EP0912607A2

EP0912607A2 - Vaccines comprising synthetic genes

Info

Publication number: EP0912607A2
Application number: EP97931230A
Authority: EP
Inventors: John W. Shiver; Mary Ellen Davies; Daniel C. Freed; Margaret A. Liu; Helen C. Perry
Original assignee: Merck and Co Inc
Current assignee: Merck and Co Inc
Priority date: 1996-06-21
Filing date: 1997-06-17
Publication date: 1999-05-06
Also published as: WO1997048370A3; CA2258568A1; WO1997048370A2; JP2000516445A; AU728422B2; AU3491897A

Abstract

Synthetic polynucleotides comprising a DNA sequence encoding a peptide or protein are provided. The DNA sequence of the synthetic polynucleotides comprise codons optimized for expression in a nonhomologous host. The invention is exemplified by synthetic DNA molecules encoding HIV env as well as modifications of HIV env. The codons of the synthetic molecules include the projected host cell's preferred codons. The synthetic molecules provide preferred forms of foreign genetic material. The synthetic molecules may be used as a polynucleotide vaccine which provides immunoprophylaxis against HIV infection through neutralizing antibody and cell-mediated immunity. This invention provides polynucleotides which, when directly introduced into a vertebrate in vivo, including mammals such as primates and humans, induces the expression of encoded proteins within the animal.

Description

97/48370 PC17US97/10517

TITLE OF THE INVENTION

VACCINES COMPRISING SYNTHETIC GENES

BACKGROUND OF THE INVENTION 1. HIV Infection:

Human Immunodeficiency Virus- 1 (HIV-1) is the etiological agent of acquired human immune deficiency syndrome (AIDS) and related disorders. HIV-1 is an RNA virus of the Retroviridae family and exhibits the 5'LTR-gag-pol-env-LTR3' organization of all retroviruses. In addition, HIV-1 comprises a handful of genes with regulatory or unknown functions, including the tat and rev genes. The env gene encodes the viral envelope glycoprotein that is translated as a 160-kilodalton (kDa) precursor (gpl60) and then cleaved by a cellular protease to yield the external 120-kDa envelope glycoprotein (gpl20) and the transmembrane 41 -kDa envelope glycoprotein (gp41). Gpl20 and gp41 remain associated and are displayed on the viral particles and the surface of HiV-infected cells. Gpl20 binds to the CD4 receptor present on the surface of helper T- lymphocytes, macrophages and other target cells. After gpl20 binds to CD4, gp41 mediates the fusion event responsible for virus entry.

Infection begins when gpl20 on the viral particle binds to the CD4 receptor on the surface of T4 lymphocytes or other target cells. The bound virus merges with the target cell and reverse transcribes its RNA genome into the double-stranded DNA of the cell. The viral DNA is incoφorated into the genetic material in the cell's nucleus, where the viral DNA directs the production of new viral RNA, viral proteins, and new virus particles. The new particles bud from the target cell membrane and infect other cells.

Destruction of T4 lymphocytes, which are critical to immune defense, is a major cause of the progressive immune dysfunction that is the hallmark of HIV infection. The loss of target cells seriously impairs the body's ability to fight most invaders, but it has a particularly severe impact on the defenses against viruses, fungi, parasites and certain bacteria, including mycobacteria. HIV-1 kills the cells it infects by replicating, budding from them and damaging the cell membrane. HIV-1 may kill target cells indirectly by means of the viral gpl20 that is displayed on an infected cell's surface. Since the CD4 receptor on T cells has a strong affinity for gpl20, healthy cells expressing CD4 receptor can bind to gpl20 and fuse with infected cells to form a syncytium. A syncytium cannot survive.

HIV-1 can also elicit normal cellular immune defenses against infected cells. With or without the help of antibodies, cytotoxic defensive cells can destroy an infected cell that displays viral proteins on its surface. Finally, free gpl20 may circulate in the blood of individuals infected with HIV-1. The free protein may bind to the CD4 receptor of uninfected cells, making them appear to be infected and evoking an immune response. Infection with HIV-1 is almost always fatal, and at present there are no cures for HIV-1 infection. Effective vaccines for prevention of HIV-1 infection are not yet available. Because of the danger of reversion or infection, live attenuated virus probably cannot be used as a vaccine. Most subunit vaccine approaches have not been successful at preventing HIV infection. Treatments for HIV-1 infection, while prolonging the lives of some infected persons, have serious side effects. There is thus a great need for effective treatments and vaccines to combat this lethal infection.

2. Vaccines

Vaccination is an effective form of disease prevention and has proven successful against several types of viral infection. Determining ways to present HIV- 1 antigens to the human immune system in order to evoke protective humoral and cellular immunity, is a difficult task. To date, attempts to generate an effective HIV vaccine have not been successful. In AIDS patients, free virus is present in low levels only. Transmission of HIV-1 is enhanced by cell-to-cell interaction via fusion and syncytia formation. Hence, antibodies generated against free virus or viral subunits are generally ineffective in eliminating virus-infected cells.

Vaccines exploit the body's ability to "remember" an antigen. After first encounters with a given antigen the immune system generates cells that retain an immunological memory of the antigen for an individual's lifetime. Subsequent exposure to the antigen stimulates the immune response and results in elimination or inactivation of the pathogen.

The immune system deals with pathogens in two ways: by humoral and by cell-mediated responses. In the humoral response lymphocytes generate specific antibodies that bind to the antigen thus inactivating the pathogen. The cell-mediated response involves cytotoxic and helper T lymphocytes that specifically attack and destroy infected cells. Vaccine development with HIV-1 virus presents problems because HIV-1 infects some of the same cells the vaccine needs to activate in the immune system (i.e., T4 lymphocytes). It would be advantageous to develop a vaccine which inactivates HIV before impairment of the immune system occurs. A particularly suitable type of HIV vaccine would generate an anti-HIV immune response which recognizes HIV variants and which works in HIV-positive individuals who are at the beginning of their infection.

A major challenge to the development of vaccines against viruses, particularly those with a high rate of mutation such as the human immunodeficiency virus, against which elicitation of neutralizing and protective immune responses is desirable, is the diversity of the viral envelope proteins among different viral isolates or strains. Because cytotoxic T-lymphocytes (CTLs) in both mice and humans are capable of recognizing epitopes derived from conserved internal viral proteins, and are thought to be important in the immune response against viruses, efforts have been directed towards the development of CTL vaccines capable of providing heterologous protection against different viral strains. It is known that CD8⁺ CTLs kill virally-infected cells when their T cell receptors recognize viral peptides associated with MHC class I molecules. The viral peptides are derived from endogenously synthesized viral proteins, regardless of the protein's location or function within the virus. Thus, by recognition of epitopes from conserved viral proteins, CTLs may provide cross-strain protection. Peptides capable of associating with MHC class I for CTL recognition originate from proteins that are present in or pass through the cytoplasm or endoplasmic reticulum. In general, exogenous proteins, which enter the endosomal processing pathway (as in the case of antigens presented by MHC class II molecules), are not effective at generating CD8+ CTL responses.

Most efforts to generate CTL responses have used replicating vectors to produce the protein antigen within the cell or they have focused upon the introduction of peptides into the cytosol. These approaches have limitations that may reduce their utility as vaccines. Retroviral vectors have restrictions on the size and structure of polypeptides that can be expressed as fusion proteins while maintaining the ability of the recombinant virus to replicate, and the effectiveness of vectors such as vaccinia for subsequent immunizations may be compromised by immune responses against the vectors themselves. Also, viral vectors and modified pathogens have inherent risks that may hinder their use in humans. Furthermore, the selection of peptide epitopes to be presented is dependent upon the structure of an individual's MHC antigens and, therefore, peptide vaccines may have limited effectiveness due to the diversity of MHC haplotypes in outbred populations.

3. DNA Vaccines Benvenisty, N., and Reshef, L. [PNAS 83, 9551 -9555,

(1986)] showed that CaPθ4-precipitated DNA introduced into mice intraperitoneally (i.p.), intravenously (i.v.) or intramuscularly (i.m.) could be expressed. The i.m. injection of DNA expression vectors without CaCl2 treatment in mice resulted in the uptake of DNA by the muscle cells and expression of the protein encoded by the DNA . The plasmids were maintained episomally and did not replicate. Subsequently, persistent expression has been observed after i.m. injection in skeletal muscle of rats, fish and primates, and cardiac muscle of rats. The technique of using nucleic acids as therapeutic agents was reported in WO90/11092 (4 October 1990), in which naked polynucleotides were used to vaccinate vertebrates.

It is not necessary for the success of the method that immunization be intramuscular. The introduction of gold microprojectiles coated with DNA encoding bovine growth hormone (BGH) into the skin of mice resulted in production of anti-BGH antibodies in the mice. A jet injector has been used to transfect skin, muscle, fat, and mammary tissues of living animals. Various methods for introducing nucleic have been reviewed. Intravenous injection of a DNAxationic liposome complex in mice was shown by Zhu et al.,

[Science 261 :209-21 1 (9 July 1993) to result in systemic expression of a cloned transgene. Ulmer et al., [Science 259:1745-1749, (1993)] reported on the heterologous protection against influenza virus infection by intramuscular injection of DNA encoding influenza virus proteins. The need for specific therapeutic and prophylactic agents capable of eliciting desired immune responses against pathogens and tumor antigens is met by the instant invention. Of particular importance in this therapeutic approach is the ability to induce T-cell immune responses which can prevent infections or disease caused even by virus strains which are heterologous to the strain from which the antigen gene was obtained. This is of particular concern when dealing with HIV as this virus has been recognized to mutate rapidly and many virulent isolates have been identified [see, for example, LaRosa et al., Science 249:932-935 (1990), identifying 245 separate HIV isolates]. In response to this recognized diversity, researchers have attempted to generate CTLs based on peptide immunization. Thus, Takahashi et al., [Science 255:333-336 (1992)] reported on the induction of broadly cross-reactive cytotoxic T cells recognizing an HIV envelope (gpl60) determinant. However, those workers recognized the difficulty in achieving a truly cross-reactive CTL response and suggested that there is a dichotomy between the priming or restimulation of T cells, which is very stringent, and the elicitation of effector function, including cytotoxicity, from already stimulated CTLs. Wang et al. reported on elicitation of immune responses in mice against HIV by intramuscular inoculation with a cloned, genomic (unspliced) HIV gene. However, the level of immune responses achieved in these studies was very low. In addition, the Wang et al., DNA construct utilized an essentially genomic piece of HIV encoding contiguous Tat/rev-gp 160-Tat/rev coding sequences. As is described in detail below, this is a suboptimal system for obtaining high-level expression of the gpl60. It also is potentially dangerous because expression of Tat contributes to the progression of Kaposi's Sarcoma.

WO 93/17706 describes a method for vaccinating an animal against a virus, wherein carrier particles were coated with a gene construct and the coated particles are accelerated into cells of an animal. In regard to HIV, essentially the entire genome, minus the long terminal repeats, was proposed to be used. That method represents substantial risks for recipients. It is generally believed that constructs of HIV should contain less than about 50% of the HIV genome to ensure safety of the vaccine; this ensures that enzymatic moieties and viral regulatory proteins, many of which have unknown or poorly understood functions have been eliminated. Thus, a number of problems remain if a useful human HIV vaccine is to emerge from the gene-delivery technology. The instant invention contemplates any of the known methods for introducing polynucleotides into living tissue to induce expression of proteins. However, this invention provides a novel immunogen for introducing HIV and other proteins into the antigen processing pathway to efficiently generate HIV-specific CTLs and antibodies. The pharmaceutical is effective as a vaccine to induce both cellular and humoral anti-HIV and HIV neutralizing immune responses. In the instant invention, the problems noted above are addressed and solved by the provision of polynucleotide immunogens which, when introduced into an animal, direct the efficient expression of HIV proteins and epitopes without the attendant risks associated with those methods. The immune responses thus generated are effective at recognizing HIV, at inhibiting replication of HIV, at identifying and killing cells infected with HIV, and are cross-reactive against many HIV strains.

4. Codon Usage and Codon Context

The codon pairings of organisms are highly nonrandom, and differ from organism to organism. This information is used to construct and express altered or synthetic genes having desired levels of translational efficiency, to determine which regions in a genome are protein coding regions, to introduce translational pause sites into heterologous genes, and to ascertain relationship or ancestral origin of nucleotide sequences. The expression of foreign heterologous genes in transformed organisms is now commonplace. A large number of mammalian genes, including, for example, murine and human genes, have been successfully inserted into single celled organisms. Standard techniques in this regard include introduction of the foreign gene to be expressed into a vector such as a plasmid or a phage and utilizing that vector to insert the gene into an organism. The native promoters for such genes are commonly replaced with strong promoters compatible with the host into which the gene is inserted. Protein sequencing machinery permits elucidation of the amino acid sequences of even minute quantities of native protein. From these amino acid sequences, DNA sequences coding for those proteins can be inferred. DNA synthesis is also a rapidly developing art, and synthetic genes corresponding to those inferred DNA sequences can be readily constructed. Despite the burgeoning knowledge of expression systems and recombinant DNA, significant obstacles remain when one attempts to express a foreign or synthetic gene in an organism. Many native, active proteins, for example, are glycosylated in a manner different from that which occurs when they are expressed in a foreign host. For this reason, eukaryotic hosts such as yeast may be preferred to bacterial hosts for expressing many mammalian genes. The glycosylation problem is the subject of continuing research.

Another problem is more poorly understood. Often translation of a synthetic gene, even when coupled with a strong promoter, proceeds much less efficiently than would be expected. The same is frequently true of exogenous genes foreign to the expression organism. Even when the gene is transcribed in a sufficiently efficient manner that recoverable quantities of the translation product are produced, the protein is often inactive or otherwise different in properties from the native protein.

It is recognized that the latter problem is commonly due to differences in protein folding in various organisms. The solution to this problem has been elusive, and the mechanisms controlling protein folding are poorly understood.

The problems related to translational efficiency are believed to be related to codon context effects. The protein coding regions of genes in all organisms are subject to a wide variety of functional constraints, some of which depend on the requirement for encoding a properly functioning protein, as well as appropriate translational start and stop signals. However, several features of protein coding regions have been discerned which are not readily understood in terms of these constraints. Two important classes of such features are those involving codon usage and codon context. It is known that codon utilization is highly biased and varies considerably between different organisms. Codon usage patterns have been shown to be related to the relative abundance of tRNA isoacceptors. Genes encoding proteins of high versus low abundance show differences in their codon preferences. The possibility that biases in codon usage alter peptide elongation rates has been widely discussed. While differences in codon use are associated with differences in translation rates, direct effects of codon choice on translation have been difficult to demonstrate. Other proposed constraints on codon usage patterns include maximizing the fidelity of translation and optimizing the kinetic efficiency of protein synthesis.

Apart from the non-random use of codons, considerable evidence has accumulated that codon/anticodon recognition is influenced by sequences outside the codon itself, a phenomenon termed "codon context." There exists a strong influence of nearby nucleotides on the efficiency of suppression of nonsense codons as well as missense codons. Clearly, the abundance of suppressor activity in natural bacterial populations, as well as the use of "termination" codons to encode selenocysteine and phosphoserine require that termination be context- dependent. Similar context effects have been shown to influence the fidelity of translation, as well as the efficiency of translation initiation.

Statistical analyses of protein coding regions of E. coli have demonstrate another manifestation of "codon context." The presence of a particular codon at one position strongly influences the frequency of occurrence of certain nucleotides in neighboring codons, and these context constraints differ markedly for genes expressed at high versus low levels. Although the context effect has been recognized, the predictive value of the statistical rules relating to preferred nucleotides adjacent to codons is relatively low. This has limited the utility of such nucleotide preference data for selecting codons to effect desired levels of translational efficiency.

The advent of automated nucleotide sequencing equipment has made available large quantities of sequence data for a wide variety of organisms. Understanding those data presents substantial difficulties. For example, it is important to identify the coding regions of the genome in order to relate the genetic sequence data to protein sequences. In addition, the ancestry of the genome of certain organisms is of substantial interest. It is known that genomes of some organisms are of mixed ancestry. Some sequences that are viral in origin are now stably incoφorated into the genome of eukaryotic organisms. The viral sequences themselves may have originated in another substantially unrelated species. An understanding of the ancestry of a gene can be important in drawing proper analogies between related genes and their translation products in other organisms.

There is a need for a better understanding of codon context effects on translation, and for a method for determining the appropriate codons for any desired translational effect. There is also a need for a method for identifying coding regions of the genome from nucleotide sequence data. There is also a need for a method for controlling protein folding and for insuring that a foreign gene will fold appropriately when expressed in a host. Genes altered or constructed in accordance with desired translational efficiencies would be of significant worth. Another aspect of the practice of recombinant DNA techniques for the expression by microorganisms of proteins of industrial and pharmaceutical interest is the phenomenon of "codon preference". While it was earlier noted that the existing machinery for gene expression is genetically transformed host cells will "operate" to construct a given desired product, levels of expression attained in a microorganism can be subject to wide variation, depending in part on specific alternative forms of the amino acid-specifying genetic code present in an inserted exogenous gene. A "triplet" codon of four possible nucleotide bases can exist in 64 variant forms. That these forms provide the message for only 20 different amino acids (as well as transcription initiation and termination) means that some amino acids can be coded for by more than one codon. Indeed, some amino acids have as many as six "redundant", alternative codons while some others have a single, required codon. For reasons not completely understood, alternative codons are not at all uniformly present in the endogenous DNA of differing types of cells and there appears to exist a variable natural hierarchy or "preference" for certain codons in certain types of cells. As one example, the amino acid leucine is specified by any of six DNA codons including CTA, CTC, CTG, CTT, TTA, and TTG (which correspond, respectively, to the mRNA codons, CUA, CUC, CUG, CUU, UUA and UUG). Exhaustive analysis of genome codon frequencies for microorganisms has revealed endogenous DNA of E. coli most commonly contains the CTG leucine-specifying codon, while the DNA of yeasts and slime molds most commonly includes a TTA leucine-specifying codon. In view of this hierarchy, it is generally held that the likelihood of obtaining high levels of expression of a leucine- rich polypeptide by an E. coli host will depend to some extent on the frequency of codon use. For example, a gene rich in TTA codons will in all probability be poorly expressed in E. coli. whereas a CTG rich gene will probably highly express the polypeptide. Similarly, when yeast cells are the projected transformation host cells for expression of a leucine-rich polypeptide, a preferred codon for use in an inserted DNA would be TTA.

The implications of codon preference phenomena on recombinant DNA techniques are manifest, and the phenomenon may serve to explain many prior failures to achieve high expression levels of exogenous genes in successfully transformed host organisms-a less "preferred" codon may be repeatedly present in the inserted gene and the host cell machinery for expression may not operate as efficiently. This phenomenon suggests that synthetic genes which have been designed to include a projected host cell's preferred codons provide a preferred form of foreign genetic material for practice of recombinant DNA techniques.

5. Protein Trafficking

The diversity of function that typifies eukaryote cells depends upon the structural differentiation of their membrane boundaries. To generate and maintain these structures, proteins must be transported from their site of synthesis in the endoplasmic reticulum to predetermined destinations throughout the cell. This requires that the trafficking proteins display sorting signals that are recognized by the molecular machinery responsible for route selection located at the access points to the main trafficking pathways. Sorting decisions for most proteins need to be made only once as they traverse their bio synthetic pathways since their final destination, the cellular location at which they perform their function, becomes their permanent residence.

Maintenance of intracellular integrity depends in part on the selective sorting and accurate transport of proteins to their correct destinations. Over the past few years the dissection of the molecular machinery for targeting and localization of proteins has been studied vigorously. Defined sequence motifs have been identified on proteins which can act as 'address labels'. A number of sorting signals have been found associated with the cytoplasmic domains of membrane proteins.

SUMMARY OF THE INVENTION

Synthetic polynucleotides comprising a DNA sequence encoding a peptide or protein are provided. The DNA sequence of the synthetic polynucleotides comprise codons optimized for expression in a nonhomologous host. The invention is exemplified by synthetic DNA molecules encoding HIV env as well as modifications of HIV env. The codons of the synthetic molecules include the projected host cell's preferred codons. The synthetic molecules provide preferred forms of foreign genetic material. The synthetic molecules may be used as a poly nucleotide vaccine which provides effective immunoprophylaxis against HIV infection through neutralizing antibody and cell-mediated immunity. This invention provides polynucleotides which, when directly introduced into a vertebrate in vivo, including mammals such as primates and humans, induces the expression of encoded proteins within the animal.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 shows HIV env cassette-based expression strategies. Figure 2 shows DNA vaccine mediated anti-gpl20 responses.

Figure 3 shows anti-gpl20 ELISA titers of murine DNA vaccinee sera. Figure 4 shows the relative expression of gpl20 after HIV env PNV cell culture transfection.

Figure 5 shows the mean anti-gpl20 ELISA responses following tPA-gpl43/optA vs. optB DNA vaccination. Figure 6 shows the neutralization of HIV by murine DNA vaccinee sera.

Figure 7 shows HIV neutralization by sera from murine HIV env DNA vaccinees.

Figure 8 is an immunoblot analysis of optimized HIV env DNA constructs.

Figure 9 shows anti-gpl20 ELISA responses in rhesus monkeys following final vaccination with gpl40 DNA and o-gpl60 protein.

Figure 10 shows SHIV neutralizing antibody responses of rhesus monkeys following final vaccination.

DETAILED DESCRIPTION OF THE INVENTION

Synthetic polynucleotides comprising a DNA sequence encoding a peptide or protein are provided. The DNA sequence of the synthetic polynucleotides comprise codons optimized for expression in a nonhomologous host. The invention is exemplified by synthetic DNA molecules encoding HIV env as well as modifications of HIV env are provided. The codons of the synthetic molecules include the projected host cell's preferred codons. The synthetic molecules provide preferred forms of foreign genetic material. The synthetic molecules may be used as a polynucleotide vaccine which provides immunoprophylaxis against HIV infection through neutralizing antibody and cell-mediated immunity. This invention provides polynucleotides which, when directly introduced into a vertebrate in vivo, including mammals such as primates and humans, induces the expression of encoded proteins within the animal.

Therefore, synthetic DNA molecules encoding HIV env and synthetic DNA molecules encoding modified forms of HIV env are provided. The codons of the synthetic molecules are designed so as to use the codons preferred by the projected host cell. As noted above, the synthetic molecules of this portion of the invention may be used as a polynucleotide vaccine which provides effective immunoprophylaxis against HIV infection through neutralizing antibody and cell-mediated immunity. The synthetic molecules may be used as an immunogenic composition. This portion of the invention also provides polynucleotides which, when directly introduced into a vertebrate in vivo, including mammals such as primates and humans, induces the expression of encoded proteins within the animal.

As used herein, a polynucleotide is a nucleic acid which contains essential regulatory elements such that upon introduction into a living, vertebrate cell, it is able to direct the cellular machinery to produce translation products encoded by the genes comprising the polynucleotide. In one embodiment of the invention, the polynucleotide is a polydeoxyribonucleic acid comprising at least one HIV gene operatively linked to a transcriptional promoter. In another embodiment of the invention, the polynucleotide vaccine (PNV) comprises polyribonucleic acid encoding at least one HIV gene which is amenable to translation by the eukaryotic cellular machinery (ribosomes, tRNAs, and other translation factors). Where the protein encoded by the polynucleotide is one which does not normally occur in that animal except in pathological conditions, (i.e., a heterologous protein) such as proteins associated with human immunodeficiency vims, (HIV), the etiologic agent of acquired immune deficiency syndrome, (AIDS), the animals' immune system is activated to launch a protective immune response. Because these exogenous proteins are produced by the animals' tissues, the expressed proteins are processed by the major histocompatibility system, MHC, in a fashion analogous to when an actual infection with the related organism (HIV) occurs. The result, as shown in this disclosure, is induction of immune responses against the cognate pathogen.

Accordingly, the instant inventors have prepared nucleic acids which, when introduced into the biological system induce the expression of HIV proteins and epitopes. The induced antibody response is both specific for the expressed HIV protein, and neutralizes HIV. In addition, cytotoxic T-lymphocytes which specifically recognize and destroy HIV infected cells are induced.

The instant invention provides a method for using a polynucleotide which, upon introduction into mammalian tissue, induces the expression in a single cell, in vivo, of discrete gene products. The instant invention provides a different solution which does not require multiple manipulations of rev dependent HIV genes to obtain rev- independent genes. The rev-independent expression system described herein is useful in its own right and is a system for demonstrating the expression in a single cell m vivo of a single desired gene-product.

Because many of the applications of the instant invention apply to anti-viral vaccination, the polynucleotides are frequently referred to as a polynucleotide vaccine, or PNV. This is not to say that additional utilities of these polynucleotides, in immune stimulation and in anti-tumor therapeutics, are considered to be outside the scope of the invention.

In one embodiment of this invention, a gene encoding an HIV gene product is incoφorated in an expression vector. The vector contains a transcriptional promoter recognized by an eukaryotic RNA polymerase, and a transcriptional terminator at the end of the HIV gene coding sequence. In a preferred embodiment, the promoter is the cytomegalovirus promoter with the intron A sequence (CMV-intA), although those skilled in the art will recognize that any of a number of other known promoters such as the strong immunoglobulin, or other eukaryotic gene promoters may be used. A preferred transcriptional terminator is the bovine growth hormone terminator. The combination of CMVintA-BGH terminator is particularly preferred.

To assist in preparation of the polynucleotides in prokaryotic cells, an antibiotic resistance marker is also preferably included in the expression vector under transcriptional control of a prokaryotic promoter so that expression of the antibiotic does not occur in eukaryotic cells. Ampicillin resistance genes, neomycin resistance genes and other pharmaceutically acceptable antibiotic resistance markers may be used. To aid in the high level production of the polynucleotide by fermentation in prokaryotic organisms, it is advantageous for the vector to contain a prokaryotic origin of replication and be of high copy number. A number of commercially available prokaryotic cloning vectors provide these benefits. It is desirable to remove non-essential DNA sequences. It is also desirable that the vectors not be able to replicate in eukaryotic cells. This minimizes the risk of integration of polynucleotide vaccine sequences into the recipients' genome. Tissue-specific promoters or enhancers may be used whenever it is desirable to limit expression of the polynucleotide to a particular tissue type.

In one embodiment, the expression vector pnRSV is used, wherein the Rous Sarcoma Virus (RSV) long terminal repeat (LTR) is used as the promoter. In another embodiment, VI , a mutated pBR322 vector into which the CMV promoter and the BGH transcriptional terminator were cloned is used. In another embodiment, the elements of V 1 and pUC 19 have been combined to produce an expression vector named V1J. Into VI J or another desirable expression vector is cloned an HIV gene, such as gpl20, gp41 , gpl60, gag, pol, env, or any other HIV gene which can induce anti-HIV immune responses. In another embodiment, the ampicillin resistance gene is removed from VI J and replaced with a neomycin resistance gene, to generate VlJ-neo into different HIV genes have been cloned for use according to this invention. In another embodiment, the vector is VlJns, which is the same as VUneo except that a unique Sfil restriction site has been engineered into the single Kpnl site at position 2114 of VlJ-neo. The incidence of Sfil sites in human genomic DNA is very low (approximately 1 site per 100,000 bases). Thus, this vector allows careful monitoring for expression vector integration into host DNA, simply by Sfil digestion of extracted genomic DNA. In a further refinement, the vector is VI R. In this vector, as much non-essential DNA as possible was "trimmed" from the vector to produce a highly compact vector. This vector is a derivative of VlJns. This vector allows larger inserts to be used, with less concern that undesirable sequences are encoded and optimizes uptake by cells. One embodiment of this invention incoφorates genes encoding HIV gρl60, gpl20, gag and other gene products from laboratory adapted strains of HIV such as SF2, IIIB or MN. Those skilled in the art will recognize that the use of genes from HIV-2 strains having analogous function to the genes from HIV-1 would be expected to generate immune responses analogous to those described herein for HIV-1 constructs. The cloning and manipulation methods for obtaining these genes are known to those skilled in the art.

It is recognized that elicitation of immune responses against laboratory adapted strains of HIV may not be adequate to provide neutralization of primary field isolates of HIV. Thus, in another embodiment of this invention, genes from virulent, primary field isolates of HIV are incoφorated in the polynucleotide immunogen. This is accomplished by preparing cDNA copies of the viral genes and then subcloning the individual genes into the polynucleotide immunogen. Sequences for many genes of many HIV strains are now publicly available on GENBANK and such primary, field isolates of HIV are available from the National Institute of Allergy and Infectious Diseases (NIAID) which has contracted with Quality Biological, Inc., [7581 Lindbergh Drive, Gaithersburg, Maryland 20879] to make these strains available. Such strains are also available from the World Health Organization (WHO) [Network for HIV Isolation and Characterization, Vaccine Development Unit, Office of Research, Global Programme on AIDS, CH-1211 Geneva 27, Switzerland]. From this work those skilled in the art will recognize that one of the utilities of the instant invention is to provide a system for in vivo as well as in vitro testing and analysis so that a correlation of HIV sequence diversity with serology of HIV neutralization, as well as other parameters can be made. Incoφoration of genes from primary isolates of HIV strains provides an immunogen which induces immune responses against clinical isolates of the virus and thus meets a need as yet unmet in the field. Furthermore, as the virulent isolates change, the immunogen may be modified to reflect new sequences as necessary. To keep the terminology consistent, the following convention is followed herein for describing polynucleotide immunogen constructs: "Vector name-HIV strain-gene-additional elements". Thus, a construct wherein the gpl60 gene of the MN strain is cloned into the expression vector VUneo, the name it is given herein is: "VUneo-MN- gpl60". The additional elements that are added to the construct are described in further detail below. As the etiologic strain of the virus changes, the precise gene which is optimal for incoφoration in the pharmaceutical may be changed. However, as is demonstrated below, because CTL responses are induced which are capable of protecting against heterologous strains, the strain variability is less critical in the immunogen and vaccines of this invention, as compared with the whole virus or subunit polypeptide based vaccines. In addition, because the pharmaceutical is easily manipulated to insert a new gene, this is an adjustment which is easily made by the standard techniques of molecular biology.

The term "promoter" as used herein refers to a recognition site on a DNA strand to which the RNA polymerase binds. The promoter forms an initiation complex with RNA polymerase to initiate and drive transcriptional activity. The complex can be modified by activating sequences termed "enhancers" or inhibiting sequences termed "silencers."

The term "leader" as used herein refers to a DNA sequence at the 5' end of a structural gene which is transcribed along with the gene. The leader usually results in the protein having an N -terminal peptide extension sometimes called a pro-sequence. For proteins destined for either secretion to the extracellular medium or a membrane, this signal sequence, which is generally hydrophobic, directs the protein into endoplasmic reticulum from which it is discharged to the appropriate destination.

The term "intron" as used herein refers to a section of DNA occurring in the middle of a gene which does not code for an amino acid in the gene product. The precursor RNA of the intron is excised and is therefore not transcribed into mRNA nor translated into protein.

The term "cassette" refers to the sequence of the present invention which contains the nucleic acid sequence which is to be expressed. The cassette is similar in concept to a cassette tape. Each cassette will have its own sequence. Thus by interchanging the cassette the vector will express a different sequence. Because of the restrictions sites at the 5' and 3' ends, the cassette can be easily inserted, removed or replaced with another cassette. The term "3' untranslated region" or "3' UTR" refers to the sequence at the 3' end of a structural gene which is usually transcribed with the gene. This 3' UTR region usually contains the poly A sequence. Although the 3' UTR is transcribed from the DNA it is excised before translation into the protein. The term "Non-Coding Region" or "NCR" refers to the region which is contiguous to the 3' UTR region of the structural gene. The NCR region contains a transcriptional termination signal.

The term "restriction site" refers to a sequence specific cleavage site of restriction endonucleases. The term "vector" refers to some means by which DNA fragments can be introduced into a host organism or host tissue. There are various types of vectors including plasmid, bacteriophages and cosmids.

The term "effective amount" means sufficient PNV is injected to produce the adequate levels of the polypeptide. One skilled in the art recognizes that this level may vary.

To provide a description of the instant invention, the following background on HIV is provided. The human immunodeficiency virus has a ribonucleic acid (RNA) genome. This RNA genome must be reverse transcribed according to methods known in the art in order to produce a cDNA copy for cloning and manipulation according to the methods taught herein. At each end of the genome is a long terminal repeat which acts as a promoter. Between these termini, the genome encodes, in various reading frames, gag-pol- env as the major gene products: gag is the group specific antigen; pol is the reverse transcriptase, or polymerase; also encoded by this region, in an alternate reading frame, is the viral protease which is responsible for post-translational processing, for example, of gpl60 into gpl20 and gp41 ; env is the envelope protein; vif is the virion infectivity factor; rev is the regulator of virion protein expression; neg is the negative regulatory factor; vpu is the virion productivity factor "u"; tat is the trans-activator of transcription; vpr is the viral protein r. The function of each of these elements has been described. In one embodiment of this invention, a gene encoding an

HIV or SrV protein is directly linked to a transcriptional promoter. The env gene encodes a large, membrane bound protein, gpl60, which is post-translationally modified to gp41 and gpl20. The gpl20 gene may be placed under the control of the cytomegalovirus promoter for expression. However, gpl20 is not membrane bound and therefore, upon expression, it may be secreted from the cell. As HIV tends to remain dormant in infected cells, it is desirable that immune responses directed at cell-bound HIV epitopes also be generated. Additionally, it is desirable that a vaccine produce membrane bound, oligomeric ENV antigen similar in structure to that produced by viral infection in order to generate the most efficacious antibody responses for viral neutralization. This goal is accomplished herein by expression in vivo of a secreted gpl40 epitope (gpl40 > gpl20 + ectodomain of gp41) or the cell-membrane associated epitope, gpl60, to prime the immune system. However, expression of gp 160 is repressed in the absence of rev due to non-export from the nucleus of non-spliced genes. For an understanding of this system, the life cycle of HIV must be described in further detail.

In the life cycle of HIV, upon infection of a host cell, HIV RNA genome is reverse-transcribed into a proviral DNA which integrates into host genomic DNA as a single transcriptional unit. The LTR provides the promoter which transcribes HIV genes from the 5' to 3' direction (gag, pol, env), to form an unspliced transcript of the entire genome. The unspliced transcript functions as the mRNA from which gag and pol are translated, while limited splicing must occur for translation of env encoded genes. For the regulatory gene product rev to be expressed, more than one splicing event must occur because in the genomic setting, rev and env overlap. In order for transcription of env to occur, rev transcription must stop, and vice versa. In addition, the presence of rev is required for export of unspliced RNA from the nucleus. For rev to function in this manner, however, a rev responsive element (RRE) must be present on the transcript [Malim et al., Nature 338:254-257 (1989)]. In the polynucleotide vaccine of this invention, the obligatory splicing of certain HIV genes is eliminated by providing fully spliced genes (i.e.: the provision of a complete open reading frame for the desired gene product without the need for switches in the reading frame or elimination of noncoding regions; those of ordinary skill in the art would recognize that when splicing a particular gene, there is some latitude in the precise sequence that results; however so long as a functional coding sequence is obtained, this is acceptable). Thus, in one embodiment, the entire coding sequence for gpl60 is spliced such that no intermittent expression of each gene product is required. The dual humoral and cellular immune responses generated according to this invention are particularly significant to inhibiting HIV infection, given the propensity of HIV to mutate within the population, as well as in infected individuals. In order to formulate an effective protective vaccine for HIV it is desirable to generate both a multivalent antibody response for example to gpl60 (env is approximately 80% conserved across various HIV-1 , clade B strains, which are the prevalent strains in US human populations), the principal neutralization target on HIV, as well as cytotoxic T cells reactive to the conserved portions of gpl60 and, internal viral proteins encoded by gag. We have made an HIV vaccine comprising gpl60 genes selected from common laboratory strains; from predominant, primary viral isolates found within the infected population; from mutated gpl60s designed to unmask cross- strain, neutralizing antibody epitopes; and from other representative HIV genes such as the gag and pol genes (-95% conserved across HIV isolates.

Virtually all HIV seropositive patients who have not advanced towards an immunodeficient state harbor anύ-gag CTLs while about 60% of these patients show cross-strain, gpl60-specific CTLs. The amount of HIV specific CTLs found in infected individuals that have progressed on to the disease state known as AIDS, however, is much lower, demonstrating the significance of our findings that we can induce cross-strain CTL responses. Immune responses induced by our env anάgag polynucleotide vaccine constructs are demonstrated in mice and primates. Monitoring antibody production to env in mice allows confirmation that a given construct is suitably immunogenic, i.e., a high proportion of vaccinated animals show an antibody response. Mice also provide the most facile animal model suitable for testing CTL induction by our constructs and are therefore used to evaluate whether a particular construct is able to generate such activity. Monkeys (African green, rhesus, chimpanzees) provide additional species including primates for antibody evaluation in larger, non-rodent animals. These species are also preferred to mice for antisera neutralization assays due to high levels of endogenous neutralizing activities against retroviruses observed in mouse sera. These data demonstrate that sufficient immunogenicity is engendered by our vaccines to achieve protection in experiments in a chimpanzee/HIVπiB challenge model based upon known protective levels of neutralizing antibodies for this system.

However, the currently emerging and increasingly accepted definition of protection in the scientific community is moving away from so-called "sterilizing immunity", which indicates complete protection from HIV infection, to prevention of disease. A number of correlates of this goal include reduced blood viral titer, as measured either by HIV reverse transcriptase activity, by infectivity of samples of serum, by ELISA assay of p24 or other HIV antigen concentration in blood, increased CD4+ T-cell concentration, and by extended survival rates [see, for example, Cohen, J., Science 262:1820-1821 , 1993, for a discussion of the evolving definition of anti-HIV vaccine efficacy 1. The immunogens of the instant invention also generate neutralizing immune responses against infectious (clinical, primary field) isolates of HIV.

Immunology

A. Antibody Responses to env.

1. gp 160 and gpl20. An ELISA assay is used to determine whether vaccine vectors expressing either secreted gpl20 or membrane-bound gpl60 are efficacious for production of env-specific antibodies. Initial in vitro characterization of env expression by our vaccination vectors is provided by immunoblot analysis of gpl60 transfected cell lysates. These data confirm and quantitate gpl60 expression using anti-gp41 and anti-gpl20 monoclonal antibodies to visualize transfectant cell gpl60 expression. In one embodiment of this invention, gp 160 is preferred to gp 120 for the following reasons: (1) an initial gpl20 vector gave inconsistent immunogenicity in mice and was very poorly or non-responsive in African green Monkeys; (2) gpl60 contributes additional neutralizing antibody as well as CTL epitopes by providing the addition of approximately 190 amino acid residues due to the inclusion of gp41; (3) gpl60 expression is more similar to viral env with respect to tetramer assembly and overall conformation, which may provide oligomer-dependent neutralization epitopes; and (4) we find that, like the success of membrane-bound, influenza HA constructs for producing neutralizing antibody responses in mice, ferrets, and nonhuman primates [see Ulmer et al., Science 259:1745-1749, 1993; Montgomery, D., et al., DNA and Cell Biol. 12:777-783, 1993] anti-gpl60 antibody generation is superior to anti- gpl20 antibody generation. Selection of which type of env , or whether a cocktail of env subfragments, is preferred is determined by the experiments outlined below.

2. Presence and Breadth of Neutralizing Activity. ELISA positive antisera from monkeys is tested and shown to neutralize both homologous and heterologous HIV strains. 3. V3 vs. non-V3 Neutralizing Antibodies. A major goal for env PNVs is to generate broadly neutralizing antibodies. It has now been shown that antibodies directed against V3 loops are very strain specific, and the serology of this response has been used to define strains. a. Non-V3 neutralizing antibodies appear to primarily recognize discontinuous, structural epitopes within gpl20 which are responsible for CD4 binding. Antibodies to this domain are polyclonal and more broadly cross-neutralizing probably due to restraints on mutations imposed by the need for the virus to bind its cellular ligand. An in vitro assay is used to test for blocking gpl20 binding to CD4 immobilized on 96 well plates by sera from immunized animals. A second in vitro assay detects direct antibody binding to synthetic peptides representing selected V3 domains immobilized on plastic. These assays are compatible for antisera from any of the animal types used in our studies and define the types of neutralizing antibodies our vaccines have generated as well as provide an in vitro correlate to virus neutralization. b. gp41 harbors at least one major neutralization determinant, corresponding to the highly conserved linear epitope recognized by the broadly neutralizing 2F5 monoclonal antibody (commercially available from Viral Testing Systems Coφ., Texas Commerce Tower, 600 Travis Street, Suite 4750, Houston, TX 77002- 3005(USA), or Waldheim Pharmazeutika GmbH, Boltzmangasse 1 1, A- 1091 Wien, Austria), as well as other potential sites including the well- conserved "fusion peptide" domain located at the N-terminus of gp41. Besides the detection of antibodies directed against gp41 by immunoblot as described above, an m vitro assay test is used for antibodies which bind to synthetic peptides representing these domains immobilized on plastic.

4. Maturation of the Antibody Response. In HIV seropositive patients, the neutralizing antibody responses progress from chiefly anti-V3 to include more broadly neutralizing antibodies comprising the structural gpl20 domain epitopes described above (#3), including gp41 epitopes. These types of antibody responses are monitored over the course of both time and subsequent vaccinations.

B. T Cell Reactivities Against env and gag. 1. Generation of CTL Responses. Viral proteins which are synthesized within cells give rise to MHC I-restricted CTL responses. Each of these proteins elicits CTL in seropositive patients. Our vaccines also are able to elicit CTL in mice. The immunogenetics of mouse strains are conducive to such studies, as demonstrated with influenza NP, [see Ulmer et al., Science 2^9: 1745-1749, 1993]. Several epitopes have been defined for the HIV proteins env, rev, nef and gag in Balb/c mice, thus facilitating in vitro CTL culture and cytotoxicity assays. It is advantageous to use syngeneic tumor lines, such as the murine mastocytoma P815, transfected with these genes to provide targets for CTL as well as for in vitro antigen specific restimulation. Methods for defining immunogens capable of eliciting MHC class I- restricted cytotoxic T lymphocytes are known [see Calin-Laurens, et al., Vaccine 1 1(91:974-978, 1993; see particularly Eriksson, et al., Vaccine ϋ(8):859-865, 1993, wherein T-cell activating epitopes on the HIV gpl20 were mapped in primates and several regions, including gpl20 amino acids 142-192, 296-343, 367-400, and 410-453 were each found to induce lymphoproliferation; furthermore, discrete regions 248-269 and 270-295 were lymphoproliferative. A peptide encompassing amino acids 152-176 was also found to induce HIV neutralizing antibodies], and these methods may be used to identify immunogenic epitopes for inclusion in the PNV of this invention. Alternatively, the entire gene encoding gpl60, gpl20, protease, or gag could be used. For additional review on this subject, see for example, Shirai et al., J. Immunol 148:1657-1667, 1992; Choppin et al.. J. Immunol 147:569-574. 1991; Choppin et al., J. Immunol 147:575-583, 1991 ; Berzofsky et al., L

Clin. Invest. 88:876-884, 1991. As used herein, T-cell effector function is associated with mature T-cell phenotype, for example, cytotoxicity, cytokine secretion for B-cell activation, and/or recruitment or stimulation of macrophages and neutrophils. 2. Measurement of TH Activities. Spleen cell cultures derived from vaccinated animals are tested for recall to specific antigens by addition of either recombinant protein or peptide epitopes. Activation of T cells by such antigens, presented by accompanying splenic antigen presenting cells, APCs, is monitored by proliferation of these cultures or by cytokine production. The pattern of cytokine production also allows classification of TH response as type 1 or type 2. Because dominant TH2 responses appear to correlate with the exclusion of cellular immunity in immunocompromised seropositive patients, it is possible to define the type of response engendered by a given PNV in patients, permitting manipulation of the resulting immune responses.

3. Delayed Type Hypersensitivitv (DTH). DTH to viral antigen after i.d. injection is indicative of cellular, primarily MHC II- restricted, immunity. Because of the commercial availability of recombinant HIV proteins and synthetic peptides for known epitopes, DTH responses are easily determined in vaccinated vertebrates using these reagents, thus providing an additional in vivo correlate for inducing cellular immunity.

Protection

Based upon the above immunologic studies, it is predictable that our vaccines are effective in vertebrates against challenge by virulent HIV. These studies are accomplished in an HIVπiB/chimpanzee challenge model after sufficient vaccination of these animals with a PNV construct, or a cocktail of PNV constructs comprised of gpl60HIB, gaglUB, nefπiB and REVmB. The IIIB strain is useful in this regard as the chimpanzee titer of lethal doses of this strain has been established. However, the same studies are envisioned using any strain of HIV and the epitopes specific to or heterologous to the given strain. A second vaccination/challenge model, in addition to chimpanzees, is the scid-hu PBL mouse. This model allows testing of the human lymphocyte immune system and our vaccine with subsequent HIV challenge in a mouse host. This system is advantageous as it is easily adapted to use with any HIV strain and it provides evidence of protection against multiple strains of primary field isolates of HIV. A third challenge model utilizes hybrid HIV/SI V viruses (SHrV), some of which have been shown to infect rhesus monkeys and lead to immunodeficiency disease resulting in death [see Li, J., et al.. J. AIDS 5:639-646. 1992]. Vaccination of rhesus with our polynucleotide vaccine constructs is protective against subsequent challenge with lethal doses of SHIV.

PNV Construct Summary HIV and other genes are ligated into an expression vector which has been optimized for polynucleotide vaccinations. Essentially all extraneous DNA is removed, leaving the essential elements of transcriptional promoter, immunogenic epitopes, transcriptional terminator, bacterial origin of replication and antibiotic resistance gene. Expression of HIV late genes such as env and gag is rev- dependent and requires that the rev response element (RRE) be present on the viral gene transcript. A secreted form of gpl20 can be generated in the absence of rev by substitution of the gpl20 leader peptide with a heterologous leader such as from tPA (tissue-type plasminogen activator), and preferably by a leader peptide such as is found in highly expressed mammalian proteins such as immunoglobulin leader peptides. We have inserted a tPA-gpl20 chimeric gene into VlJns which efficiently expresses secreted gpl20 in transfected cells (RD, a human rhabdomyosarcoma line). Monocistronic gpl60 does not produce any protein upon transfection without the addition of a rev expression vector.

Representative Construct Components Include (but are not restricted to): 1. tPA-gpl20MN; 2. gpl60HIB;

3. gaglim: for anti-gαg CTL;

4. tPA-gpl20πiB;

5. tPA-gpl40 6. tPA-gp 160 with structural mutations: VI , V2, and/or V3 loop deletions or substitutions

7. Genes encoding antigens expressed by pathogens other than HIV, such as, but not limited to, influenza virus nucleoprotein, hemagglutinin, matrix, neuraminidase, and other antigenic proteins; heφes simplex virus genes; human papillomavirus genes; tuberculosis antigens; hepatitis A, B, or C vims antigens.

The protective efficacy of polynucleotide HIV immunogens against subsequent viral challenge is demonstrated by immunization with the non-replicating plasmid DNA of this invention. This is advantageous since no infectious agent is involved, assembly of virus particles is not required, and determinant selection is permitted. Furthermore, because the sequence of gag and protease and several of the other viral gene products is conserved among various strains of HIV, protection against subsequent challenge by a virulent strain of HIV that is homologous to, as well as strains heterologous to the strain from which the cloned gene is obtained, is enabled. The i.m. injection of a DNA expression vector encoding gpl60 results in the generation of significant protective immunity against subsequent viral challenge. In particular, gp 160-specific antibodies and primary CTLs are produced. Immune responses directed against conserved proteins can be effective despite the antigenic shift and drift of the variable envelope proteins. Because each of the HIV gene products exhibit some degree of conservation, and because CTL are generated in response to intracellular expression and MHC processing, it is predictable that many virus genes give rise to responses analogous to that achieved for gpl60. Thus, many of these genes have been cloned, as shown by the cloned and sequenced junctions in the expression vector (see below) such that these constructs are immunogenic agents in available form.

The invention offers a means to induce cross -strain protective immunity without the need for self-replicating agents or adjuvants. In addition, immunization with the instant polynucleotides offers a number of other advantages. This approach to vaccination should be applicable to tumors as well as infectious agents, since the CD8+ CTL response is important for both pathophysiological processes [K. Tanaka et al, Annu. Rev. Immunol. 6, 359 (1988)]. Therefore, eliciting an immune response against a protein crucial to the transformation process may be an effective means of cancer protection or immunotherapy. The generation of high titer antibodies against expressed proteins after injection of viral protein and human growth hormone DNA suggests that this is a facile and highly effective means of making antibody-based vaccines, either separately or in combination with cytotoxic T-lymphocyte vaccines targeted towards conserved antigens.

The ease of producing and purifying DNA constructs compares favorably with traditional methods of protein purification, thus facilitating the generation of combination vaccines. Accordingly, multiple constructs, for example encoding gpl60, gpl20, gp41, or any other HIV gene may be prepared, mixed and co-administered. Because protein expression is maintained following DNA injection, the persistence of B- and T-cell memory may be enhanced, thereby engendering long-lived humoral and cell-mediated immunity.

Standard techniques of molecular biology for preparing and purifying DNA constructs enable the preparation of the DNA immunogens of this invention. While standard techniques of molecular biology are therefore sufficient for the production of the products of this invention, the specific constructs disclosed herein provide novel polynucleotide immunogens which suφrisingly produce cross-strain and primary HIV isolate neutralization, a result heretofore unattainable with standard inactivated whole virus or subunit protein vaccines. The amount of expressible DNA or transcribed RNA to be introduced into a vaccine recipient will depend on the strength of the transcriptional and translational promoters used and on the immunogenicity of the expressed gene product. In general, an immunologically or prophylactically effective dose of about 1 ng to 100 mg, and preferably about 10 μg to 300 μg is administered directly into muscle tissue. Subcutaneous injection, intradermal introduction, impression through the skin, and other modes of administration such as intraperitoneal, intravenous, or inhalation delivery are also contemplated. It is also contemplated that booster vaccinations are to be provided. Following vaccination with HIV polynucleotide immunogen, boosting with HIV protein immunogens such as gpl60, gpl20, and gag gene products is also contemplated. Parenteral administration, such as intravenous, intramuscular, subcutaneous or other means of administration of interleukin-12 protein or GM-CSF or similar proteins alone or in combination, concurrently with or subsequent to parenteral introduction of the PNV of this invention is also advantageous.

The polynucleotide may be naked, that is, unassociated with any proteins, adjuvants or other agents which impact on the recipients' immune system. In this case, it is desirable for the polynucleotide to be in a physiologically acceptable solution, such as, but not limited to, sterile saline or sterile buffered saline. Alternatively, the DNA may be associated with liposomes, such as lecithin liposomes or other liposomes known in the art, as a DNA-liposome mixture, or the DNA may be associated with an adjuvant known in the art to boost immune responses, such as a protein or other carrier. Agents which assist in the cellular uptake of DNA, such as, but not limited to, calcium ions, may also be used to advantage. These agents are generally referred to herein as transfection facilitating reagents and pharmaceutically acceptable carriers. Techniques for coating microprojectiles coated with polynucleotide are known in the art and are also useful in connection with this invention.

The following examples are offered by way of illustration and are not intended to limit the invention in any manner. EXAMPLE 1 Materials descriptions

Vectors pF411 and pF412: These vectors were subcloned from vector pSP62 which was constructed in R. Gallo's lab. pSP62 is an available reagent from Biotech Research Laboratories, Inc. pSP62 has a 12.5 kb Xbal fragment of the HXB2 genome subcloned from lambda HXB2. Sail and Xba I digestion of pSP62 yields to HXB2 fragments: 5'-XbaI/SalI, 6.5 kb and 3'- Sall/Xbal, 6 kb. These inserts were subcloned into pUC 18 at Smal and Sail sites yielding pF411 (5'- Xbal/Sall) and pF412 (3'-XbaI/SalI). pF41 1 contains gaglpol and pF412 contains tat/re v/e/zv/nef.

Repligen reagents: recombinant rev (IIIB), #RP1024-10 rec. gpl20 (IIIB), #RP1001-10 anti-rev monoclonal antibody, #RP1029-10 anti-gpl20 mAB, #1C1, #RP1010-10

AIDS Research and Reference Reagent Program: anti-gp41 mAB hybridoma, Chessie 8, #526

The strategies are designed to induce both cytotoxic T lymphocyte (CTL) and neutralizing antibody responses to HIV, principally directed at the HIV gag (~95% conserved) and env (gpl60 or gpl20; 70-80% conserved) gene products. gpl60 contains the only known neutralizing antibody epitopes on the HrV particle while the importance of anti-env and anti-gag CTL responses are highlighted by the known association of the onset of these cellular immunities with clearance of primary viremia following infection, which occurs prior to the appearance of neutralizing antibodies, as well as a role for CTL in maintaining disease-free status. Because HIV is notorious for its genetic diversity, we hope to obtain greater breadth of neutralizing antibodies by including several representative env genes derived from clinical isolates and gp41 (~90% conserved), while the highly conserved gag gene should generate broad cross-strain CTL responses. EXAMPLE 2 Heterologous Expression of HIV Late Gene Products

HIV structural genes such as env and gag require expression of the HIV regulatory gene, rev, in order to efficiently produce full-length proteins. We have found that rev-dependent expression of gag yielded low levels of protein and that rev itself may be toxic to cells. Although we achieved relatively high levels of rev- dependent expression of gpl60 in vitro this vaccine elicited low levels of antibodies to gpl60 following in vivo immunization with rev/gpl60 DNA. This may result from known cytotoxic effects of rev as well as increased difficulty in obtaining rev function in myotubules containing hundreds of nuclei (rev protein needs to be in the same nucleus as a rev- dependent transcript for gag or env protein expression to occur). However, it has been possible to obtain rev-independent expression using selected modifications of the env gene. Evaluation of these plasmids for vaccine puφoses is underway.

In general, our vaccines have utilized primarily HIV (IIIB) env and gag genes for optimization of expression within our generalized vaccination vector, VlJns, which is comprised of a CMV immediate- early (IE) promoter, BGH polyadenylation site, and a pUC backbone. Varying efficiencies, depending upon how large a gene segment is used (e.g., gpl20 vs. gpl60), of rev-independent expression may be achieved for env by replacing its native secretory leader peptide with that from the tissue-specific plasminogen activator (tPA) gene and expressing the resulting chimeric gene behind the CMVIE promoter with the CMV intron A. tPA-gpl20 is an example of a secreted gpl20 vector constructed in this fashion which functions well enough to elicit anti- gpl20 immune responses in vaccinated mice and monkeys.

Because of reports that membrane-anchored proteins may induce much more substantial (and perhaps more specific for HIV neutralization) antibody responses compared to secreted proteins as well as to gain additional immune epitopes, we prepared VUns-tPA-gpl60 and VUns-rev/gpl60. The tPA-gp!60 vector produced detectable quantities of gpl60 and gpl20, without the addition of rev, as shown by immunoblot analysis of transfected cells, although levels of expression were much lower than that obtained for rev/gpl60, a rev-dependent gpl60-expressing plasmid. This is probably because inhibitory regions (designated INS), which confer rev dependence upon the gpl60 transcript, occur at multiple sites within gpl60 including at the COOH- terminus of gp41 (see Figure 1 for schematic view of gpl43 construct strategies). A vector was prepared for a COOH-terminally truncated form of tPA-gpl60, tPA-gpl43, which was designed to increase the overall expression levels of env by elimination of these inhibitory sequences. The gpl43 vector also eliminates intracellular gp41 regions containing peptide motifs (such as leu-leu) known to cause diversion of membrane proteins to the lysosomes rather than the cell surface. Thus, gpl43 may be expected to increase both expression of the env protein (by decreasing rev-dependence) and the efficiency of transport of protein to the cell surface compared to full-length gpl60 where these proteins may be better able to elicit anti-gpl60 antibodies following DNA vaccination. tPA-gpl43 was further modified by extensive silent mutagenesis of the rev response element (RRE) sequence (350 bp) to eliminate additional inhibitory sequences for expression. This constmct, gpl43/mutRRE, was prepared in two forms: either eliminating (form A) or retaining (form B) proteolytic cleavage sites for gp 120/41. Both forms were prepared because of literature reports that vaccination of mice using uncleavable gpl60 expressed in vaccinia elicited much higher levels of antibodies to gpl60 than did cleavable forms.

A quantitative ELISA for gpl60/gpl20 expression in cell transfectants was developed to determine the relative expression capabilities for these vectors. In vitro transfection of 293 cells followed by quantification of cell-associated vs. secreted/released gpl20 yielded the following results: (1) tPA-gpl60 expressed 5-10X less gpl20 than rev/gpl60 with similar proportions retained intracellularly vs. trafficked to the cell surface; (2) tPA-gpl43 gave 3-6X greater secretion of gpl20 than rev/gpl60 with only low levels of cell-associated gpl43, confirming that the cytoplasmic tail of gpl60 causes intracellular retention of gpl60 which can be overcome by partial deletion of this sequence; and, (3) tPA-gpl43/mutRRE A and B gave ~10X greater expression levels of protein than did parental tPA-gpl43 while elimination of proteolytic processing was confirmed for form A. Figure 4 presents representative data supporting points (1 ) - (3).

Thus, our strategy to increase rev-independent expression has yielded stepwise increases in overall expression as well as redirecting membrane-anchored gpl43 to the cell surface away from lysosomes. It is important to note that it should be possible to insert gpl20 sequences derived from various viral isolates within a vector cassette containing these modifications which reside either at the NH2- terminus (tPA leader) or COOH-terminus (gp41), where few antigenic differences exist between different viral strains. In other words, this is a generic construct which can easily be modified by inserting gpl20 derived from various primary viral isolates to obtain clinically relevant vaccines.

To apply these expression strategies to viruses that are relevant for vaccine puφoses and confirm the generality of our approaches, we also prepared a tPA-gpl20 vector derived from a primary HIV isolate (containing the North American consensus V3 peptide loop; macrophage-tropic and nonsyncytia-inducing phenotypes). This vector gave high expression/secretion of gpl20 with transfected 293 cells and elicited anti-gpl20 antibodies in mice demonstrating that it was cloned in a functional form. Primary isolate gpl60 genes will also be used for expression in the same way as for gpl60 derived from laboratory strains.

EXAMPLE 3 Immune Responses to HIV-1 env Polynucleotide Vaccines:

African green (AGM) and Rhesus (RHM) monkeys which received gpl20 DNA vaccines showed low levels of neutralizing antibodies following 2-3 vaccinations, which could not be increased by additional vaccination. These results, as well as increasing awareness within the HIV vaccine field that oligomeric gpl60 is probably a more relevant target antigen for eliciting neutralizing antibodies than gpl20 monomers (Moore and Ho, J. Virol. 67: 863 (1993)), have led us to focus upon obtaining effective expression of gpl60-based vectors (see above). Mice and AGM were also vaccinated with the primary isolate derived tPA-gpl20 vaccine. These animals exhibited anti-V3 peptide (using homologous sequence) reciprocal endpoint antibody titers ranging from 500-5000, demonstrating that this vaccine design is functional for clinically relevant viral isolates. The gpl60-based vaccines, rev-gpl60 and tPA-gpl60, failed to consistently elicit antibody responses in mice and nonhuman primates or yielded low antibody titers. Our initial results with the tPA-gpl43 plasmid yielded geometric mean titers > 10^ in mice and AGM following two vaccinations. These data indicate that we have significantly improved the immunogenicity of gpl60-like vaccines by increasing expression levels. This construct, as well as the tPA- gpl43/mutRRE A and B vectors, will continue to be characterized for antibody responses, especially for virus neutralization.

Significantly, gpl20 DNA vaccination produced potent helper T cell responses in all lymphatic compartments tested (spleen, blood, inguinal, mesenteric, and iliac nodes) with THl-like cytokine secretion profiles (i.e., g-interferon and IL-2 production with little or no IL-4). These cytokines generally promote strong cellular immunity and have been associated with maintenance of a disease-free state for HIV-seropositive patients. Lymph nodes have been shown to be primary sites for HIV replication, harboring large reservoirs of virus even when virus cannot be readily detected in the blood. A vaccine which can elicit anti-HIV immune responses at a variety of lymph sites, such as we have shown with our DNA vaccine, may help prevent successful colonization of the lymphatics following initial infection. As stated previously, we consider realization of the following objectives to be essential to maximize our chances for success with this program: (1) env-based vectors capable of generating stronger neutralizing antibody responses in primates; (2) gag and env vectors which elicit strong T-lymphocyte responses as characterized by CTL and helper effector functions in primates; (3) use of env and gag genes from clinically relevant HIV-1 strains in our vaccines and characterization of the immunologic responses, especially neutralization of primary isolates, they elicit; (4) demonstration of protection in an animal challenge model such as chimpanzee/HIV (IIIB) or rhesus/SHIV using appropriate optimized vaccines; and, (5) determination of the duration of immune responses appropriate to clinical use. Significant progress has been made on the first three of these objectives and experiments are in progress to determine whether our recent vaccination constructs for gpl60 and gag will improve upon these initial results.

EXAMPLE 4 Vectors For Vaccine Production

A. VUneo EXPRESSION VECTOR. SEP. ID 1 :

It was necessary to remove the amp^r gene used for antibiotic selection of bacteria harboring VIJ because ampicillin may not be used in large-scale fermenters. The amp^1* gene from the pUC backbone of VIJ was removed by digestion with Sspl and Eaml 1051 restriction enzymes. The remaining plasmid was purified by agarose gel electrophoresis, blunt-ended with T4 DNA polymerase, and then treated with calf intestinal alkaline phosphatase. The commercially available kan^r gene, derived from transposon 903 and contained within the pUC4K plasmid, was excised using the Pstl restriction enzyme, purified by agarose gel electrophoresis, and blunt-ended with T4 DNA polymerase. This fragment was ligated with the VIJ backbone and plasmids with the kan^r gene in either orientation were derived which were designated as VUneo #'s 1 and 3. Each of these plasmids was confirmed by restriction enzyme digestion analysis, DNA sequencing of the junction regions, and was shown to produce similar quantities of plasmid as VIJ. Expression of heterologous gene products was also comparable to VIJ for these VUneo vectors. We arbitrarily selected VUneo#3, referred to as VUneo hereafter (SEQ ID: 1), which contains the kan^r gene in the same orientation as the amp^r gene in VIJ as the expression constmct.

B. VlJns Expression Vector: An Sfi I site was added to VUneo to facilitate integration studies. A commercially available 13 base pair Sfi I linker (New England BioLabs) was added at the Kpn I site within the BGH sequence of the vector. VUneo was linearized with Kpn I, gel purified, blunted by T4 DNA polymerase, and ligated to the blunt Sfi I linker. Clonal isolates were chosen by restriction mapping and verified by sequencing through the linker. The new vector was designated VlJns. Expression of heterologous genes in VlJns (with Sfi I) was comparable to expression of the same genes in VUneo (with Kpn I).

C. VUns-tPA:

In order to provide an heterologous leader peptide sequence to secreted and/or membrane proteins, VlJn was modified to include the human tissue-specific plasminogen activator (tPA) leader. Two synthetic complementary oligomers were annealed and then ligated into VlJn which had been Bgiπ digested. The sense and antisense oligomers were 5'-GATC ACC ATG GAT GCA ATG AAG AGA GGG CTC TGC TGT GTG CTG CTG CTG TGT GGA GCA GTC TTC GTT TCG CCC AGC GA-3' (SEQ.TD:2), and 5'-GAT CTC GCT GGG CGA AAC GAA GAC TGC TCC ACA CAG CAG CAG CAC ACA GCA GAG CCC TCT CTT CAT TGC ATC CAT GGT-3' (SEQ. ID:3). The Kozak sequence is underlined in the sense oligomer. These oligomers have overhanging bases compatible for ligation to Bglll-cleaved sequences. After ligation the upstream Bgiπ site is destroyed while the downstream Bgiπ is retained for subsequent ligations. Both the junction sites as well as the entire tPA leader sequence were verified by DNA sequencing. Additionally, in order to conform with our consensus optimized vector VlJns (= VUneo with an Sfil site), an Sfil restriction site was placed at the Kpnl site within the BGH terminator region of VUn-tPA by blunting the Kpnl site with T4 DNA polymerase followed by ligation with an Sfil linker (catalogue #1138, New England Biolabs). This modification was verified by restriction digestion and agarose gel electrophoresis.

EXAMPLE 5

I. HIV env Vaccine Constructs:

Vaccines Producing Secreted ewv-derived Antigen (gp!20 and gp!40): Expression of the rev -dependent env gene as gpl20 was conducted as follows: gpl20 was PCR-cloned from the MN strain of HIV with either the native leader peptide sequence (VUns-gpl20), or as a fusion with the tissue-plasminogen activator (tPA) leader peptide replacing the native leader peptide (VUns-tPA-gpl20). tPA-gpl20 expression has been shown to be rev-independent [B.S. Chapman et al., Nuc. Acids Res. 19, 3979 (1991); it should be noted that other leader sequences would provide a similar function in rendering the gpl20 gene rev independent]. This was accomplished by preparing the following gpl20 constructs utilizing the above described vectors.

EXAMPLE 6 gp!20 Vaccine Constructs:

A. VUns-tPA-HIVMN gp!20:

HIVMN gpl20 gene (Medimmune) was PCR amplified using oligomers designed to remove the first 30 amino acids of the peptide leader sequence and to facilitate cloning into VUns-tPA creating a chimeric protein consisting of the tPA leader peptide followed by the remaining gpl20 sequence following amino acid residue 30. This design allows for rev -independent gpl20 expression and secretion of soluble gpl20 from cells harboring this plasmid. The sense and antisense PCR oligomers used were 5'-CCC CGG ATC CTG ATC ACA GAA AAA TTG TGGGTC ACA GTC-3' (SEQ. ID:4), and 5'-C CCC AGG AATC CAC CTG TTA GCG CTT TTC TCT CTG CAC CAC TCT TCT C-3' (SEQ. ID:5). The translation stop codon is underlined. These oligomers contain BamHI restriction enzyme sites at either end of the translation open reading frame with a Bell site located 3' to the BamHI of the sense oligomer. The PCR product was sequentially digested with Bell followed by BamHI and ligated into VUns-tPA which had been Bglll digested followed by calf intestinal alkaline phosphatase treatment. The resulting vector was sequenced to confirm in-frame fusion between the tPA leader and gpl20 coding sequence, and gpl20 expression and secretion was verified by immunoblot analysis of transfected RB cells.

B. VUns-tPA-HrVjTTB gp!20: This vector is analogous to I. A. except that the HIV HUB strain was used for gpl20 sequence. The sense and antisense PCR oligomers used were: 5'-GGT ACA TGA TCA CA GAA AAA TTG TGG GTC ACA GTC-3' (SEQ.ID:6), and 5'-CCA CAT TGA TCA GAT ATC TTA TCT TTT TTC TCT CTG CAC CAC TCT TC-3' (SEQ.ID:7), respectively. These oligomers provide Bell sites at either end of the insert as well as an EcoRV just upstream of the Bell site at the 3'-end. The 5'-terminal Bell site allows ligation into the Bglll site of VUns-tPA to create a chimeric tPA-gpl20 gene encoding the tPA leader sequence and gpl20 without its native leader sequence. Ligation products were verified by restriction digestion and DNA sequencing.

EXAMPLE 7 gp!40 Vaccine Constructs:

These constructs was prepared by PCR similarly as tPA- gpl20 with the tPA leader in place of the native leader, but designed to produce secreted antigen by terminating the gene immediately NH2- terminal of the transmembrane peptide (projected carboxyterminal amino acid sequence = NH2- TNWLWYIK-COOH) [SEQ.ID:8].

Unlike the gpl20-producing constructs, gpl40 constructs should produce oligomeric antigen and retain known gp41 -contained antibody neutralization epitopes such as ELDKWA (SEQ.ID:53) defined by the 2F5 monoclonal antibody.

Constructs were prepared in two forms (A or B) depending upon whether the gpl60 proteolytic cleavage sites at the junction of gpl20 and gp41 were retained (B) or eliminated (A) by appropriate amino acid substitutions as described by Kieny et al., (Prot. Eng. 2: 219-255 (1988)) (wild type sequence = NH2-

...KAKRRVVQREKR...COOH (SEQ.ID:9) and the mutated sequence = NH2-...KAQNUVVQNEHQ...COOH (SEQ.ID: 10) with mutated amino acids underlined).

A. VUns-tPA-gpl40/mutRRE-A/SRV-l 3'-UTR (based on HIV- lIIIBl: This constmct was obtained by PCR using the following sense and antisense PCR oligomers: 5'-CT GAA AGA CCA GCA ACT CCT AGG GAAT TTG GGG TTG CTC TGG-3' (SEQ.ID: 11 ) :, and 5 - CGC AGG GGA GGT GGT CTA GAT ATC TTA TTA TTT TAT ATA CCA CAG CCA ATT TGT TAT G-3' (SEQ ID: 12) to obtain an Avrll/EcoRV segment from vector IVB (containing the optimized RRE- A segment). The 3'-UTR, prepared as a synthetic gene segment, that is derived from the Simian Retrovirus-1 (SRV-1 , see below) was inserted into an Srfl restriction enzyme site introduced immediately 3'- of the gpl40 open reading frame. This UTR sequence has been described previously as facilitating rev-independent expression of HIV env and gag.

B. VUns-tPA-gpl40/mutRRE-B/SRV-l 3'-UTR (based on HIV- 1IIIB): This construct is similar to IIA except that the env proteolytic cleavage sites have been retained by using constmct IVC as starting material.

C. VUns-tPA-gpl40/opt30-A (based on HIV-I TTJR): This construct was derived from IVB by Avrll and Srfl restriction enzyme digestion followed by ligation of a synthetic DNA segment corresponding to gp30 but comprised of optimal codons for translation (see gp32-opt below). The gp30-opt DNA was obtained from gp32-opt by PCR amplification using the following sense and anti- sense oligomers: 5'-GGT ACA CCT AGG CAT CTG GGG CTG CTC TGG-3^*, (SEQ ID: 13) and, 5'-CCA CAT GAT ATC G CCC GGG C TTA TTA TTT GAT GTA CCA CAG CCA GTT GGT GAT G-3', (SEQ ID: 14), respectively. This DNA segment was digested with Avrll and EcoRV restriction enzymes and ligated into VUns-tPA- gpl43/opt32-A (IVD) that had been digested with Avrll and Srfl to remove the corresponding DNA segment. The resulting products were verified by DNA sequencing of ligation junctions and immunoblot analysis.

D. VUns-tPA-gpl40/opt30-B (based on HIV-l ττre):

This construct is similar to IIC except that the env proteolytic cleavage sites have been retained.

E. VUns-tPA-gpl40/opt all-A:

The env gene of this construct is comprised completely of optimal codons. The constant regions (Cl , C5, gp32) are those described in IVB,D,H with an additional synthetic DNA segment corresponding to variable regions 1 -5 is inserted using a synthetic DNA segment comprised of optimal codons for translation (see example below based on HIV-1 MN VI -V5).

F. VUns-tPA-gpl40/opt all-B:

This constmct is similar to HE except that the env proteolytic cleavage sites have been retained.

G. VUns-tPA-gρl40/opt all-A (non-IIIB strains'):

This constmct is similar to ITE above except that env amino acid sequences from strains other than IIIB are used to determine optimum codon usage throughout the variable (V1-V5) regions.

H. VUns-tPA-gρl40/opt all-B (non-IIIB strains):

This constmct is similar to UG except that the env proteolytic cleavage sites have been retained. EXAMPLE 8 gp!60 Vaccine Constmcts:

Constructs were prepared in two forms (A or B) depending upon whether the gpl60 proteolytic cleavage sites as described above.

A. VUns-rev/env:

This vector is a variation of the one described in section D above except that the entire tat coding region in exon 1 is deleted up to the beginning of the rev open reading frame. VUns-gpl60lHB (see section A. above) was digested with Pstl and Kpnl restriction enzymes to remove the 5'-region of the gpl60 gene. PCR amplification was used to obtain a DNA segment encoding the first REV exon up to the Kpnl site in gpl60 from the HXB2 genomic clone. The sense and antisense PCR oligomers were 5'-GGT ACA CTG CAG TCA CCG TCC T ATG GCA GGA AGA AGC GGA GAC-3' (SEQ.ID: 15) and 5'-CCA CAT CA GGT ACC CCA TAA TAG ACT GTG ACC-3" (SEQ.ID:16) respectively. These oligomers provide Pstl and Kpnl restriction enzyme sites at the 5'- and 3'- termini of the DNA fragment, respectively. The resulting DNA was digested with Pstl and Kpnl, purified from an agarose electrophoretic gel, and ligated with VUns- gpl60(PstI/KpnI). The resulting plasmid was verified by restriction enzyme digestion.

B. VUns-gpl60: HlViπb gpl60 was cloned by PCR amplification from plasmid pF412 which contains the 3'-terminal half of the HIViπb genome derived from HIVπib clone HXB2. The PCR sense and antisense oligomers were 5'-GGT ACA TGA TCA ACC ATG AGA GTG AAG GAG AAA TAT CAG C-3' (SEQ. ID:17), and 5'-CCA CAT TGA TCA GAT ATC CCC ATC TTA TAG CAA AAT CCT TTC C-3' (SEQ. ID: 18), respectively. The Kozak sequence and translation stop codon are underlined. These oligomers provide Bell restriction enzyme sites outside of the translation open reading frame at both ends of the env gene. (Bell-digested sites are compatible for ligation with Bglll- digested sites with subsequent loss of sensitivity to both restriction enzymes. Bell was chosen for PCR-cloning gpl60 because this gene contains internal Bglll and as well as BamHI sites). The antisense oligomer also inserts an EcoRV site just prior to the Bell site as described above for other PCR-derived genes. The amplified gpl60 gene was agarose gel-purified, digested with Bell, and ligated to VlJns which had been digested with Bgiπ and treated with calf intestinal alkaline phosphatase. The cloned gene was about 2.6 kb in size and each junction of gp!60 with VlJns was confirmed by DNA sequencing.

C. VI Jns-tPA-gpl60 (based on HIV-ITTTR);

This vector is similar to Example 1 (C) above, except that the full-length gpl60, without the native leader sequence, was obtained by PCR. The sense oligomer was the same as used in I.C. and the antisense oligomer was 5^*-CCA CAT TGA TCA GAT ATC CCC ATC TTA TAG CAA AAT CCT TTC C-3' (SEQ.ID: 19). These oligomers provide Bell sites at either end of the insert as well as an EcoRV just upstream of the Bell site at the 3'-end. The 5'-terminal Bell site allows ligation into the Bglll site of VUns-tPA to create a chimeric tPA-gpl60 gene encoding the tPA leader sequence and gpl60 without its native leader sequence. Ligation products were verified by restriction digestion and DNA sequencing.

D. VUns-tPA-gpl60/opt Cl/opt41 -A (based on HIV-lTTTB): This constmct was based on IVH, having a complete optimized codon segment for C5 and gp41 , rather than gp32, with an additional optimized codon segment (see below) replacing Cl at the amino terminus of gpl20 following the tPA leader. The new Cl segment was joined to the remaining gpl43 segment via SOE PCR using the following oligomers for PCR to synthesize the joined C 1/143 segment: 5 -CCT GTG TGT GAG TTT AAA C TGC ACT GAT TTG AAG AAT GAT ACT AAT AC-3' (SEQ ID:20). The resulting gpl43 gene contains optimal codon usage except for V 1 - V5 regions and has a unique Pmel restriction enzyme site placed at the junction of Cl and VI for insertion of variable regions from other HIV genes.

E. VUns-tPA-gpl60/opt Cl/opt41-B (based on HIV-IJTΓR): This constmct is similar to HID except that the env proteolytic cleavage sites have been retained.

F VUns-tPA-gpl60/opt all-A (based on HIV-ITTTTR):

The env gene of this construct is comprised completely of optimal codons as described above. The constant regions (Cl , C5, gp32) are those described in IIID,E which is used as a cassette

(employed for all completely optimized gpl60s) while the variable regions, VI -V5, are derived from a synthetic DNA segment comprised of optimal codons.

G. VUns-tPA-gpl60/opt all-B:

This constmct is similar to IIIF except that the env proteolytic cleavage sites have been retained.

H. VUns-tPA-gpl60/opt all-A (non-IIIB strains):

This constmct is similar to IIIF above except that env amino acid sequences from strains other than IIIB were used to determine optimum codon useage throughout the variable (VI -V5) regions.

I. VUns-tPA-gpl60/opt all-B (non-IIIB strains):

This constmct is similar to IIIH except that the env proteolytic cleavage sites have been retained. EXAMPLE 9 gp!43 Vaccine Constmcts:

These constmcts were prepared by PCR similarly as other tPA-containing constmcts described above (tPA-gpl20, tPA-gpl40, and tPA-gpl60), with the tPA leader in place of the native leader, but designed to produce COOH-terminated, membrane-bound env (projected intracellular amino acid sequence= NH2-NRVRQGYSP- COOH). This constmct was designed with the puφose of combining the increased expression of env accompanying tPA introduction and minimizing the possibility that a transcript or peptide region corresponding to the intracellular portion of env might negatively impact expression or protein stability/transport to the cell surface. Constmcts were prepared in two forms (A or B) depending upon whether the gp 160 proteolytic cleavage sites were removed or retained as described above. The residual gp41 fragment resulting from tmncation to gpl43 is referred to as gp32.

A. VUns-tPA-gpl43:

This constmct was prepared by PCR using plasmid pF412 with the following sense and antisense PCR oligomers: 5'-GGT ACA TGA TCA CA GAA AAA TTG TGG GTC ACA GTC-3' (SEQ.ID:21):, and 5'- CCA CAT TGA TCA G CCC GGG C TTA GGG TGA ATA GCC CTG CCT CAC TCT GTT CAC-3' (SEQ.ID:22). The resulting DNA segment contains Bell restriction sites at either end for cloning into VUns-tPA/Bglll-digested with an Srfl site located immediately 3'- to the env open reading frame. Constmcts were verified by DNA sequencing of ligation junctions and immunoblot analysis of transfected cells (Figure 8).

B. V 1 Jns-tP A-gp 143/mutRRE- A :

This constmct was based on IVA by excising the DNA segment using the unique Muni restriction enzyme site and the downstream Srfl site described above. This segment corresponds to a portion of the gpl20 C5 domain and the entirety of gp32. A synthetic DNA segment corresponding to -350 bp of the rev response element (RRE A) of gpl60, comprised of optimal codons for translation, was joined to the remaining gp32 segment by splice overlap extension (SOE) PCR creating an Avrll restriction enzyme site at the junction of the two segments (but no changes in amino acid sequence). These PCR reactions were performed using the following sense and antisense PCR oligomers for generating the gp32-containing domain: 5'-CT GAA AGA CCA GCA ACT CCT AGG GAT TTG GGG TTG CTG TGG-3' (SEQ ID:23) and 5'-CCA CAT TGA TCA G CCC GGG C TTA GGG TGA ATA GCC CTG CCT CAC TCT GTT CAC-3' [SEQ ID:24] (which was used as the antisense oligomer for IVA), respectively. The mutated RRE (mutRRE-A) segment was joined to the wild type sequence of gp32 by SOE PCR using the following sense oligomer, 5'-GGT ACA CAA TTG GAG GAG CGA GTT ATA TAA ATA TAA G-3' (SEQ ID:25), and the antisense oligomer used to make the gp32 segment. The resulting joined DNA segment was digested with Muni and Srfl restriction enzymes and ligated into the parent gpl43/MunI/SrfI digested plasmid. The resulting constmct was verified by DNA sequencing of ligation and SOE PCR junctions and immunoblot analysis of transfected cells (Figure 8).

C. V 1 Jns-tPA-gp 143/mutRRE-B :

This constmct is similar to IVB except that the env proteolytic cleavage sites have been retained by using the mutRRE-B synthetic gene segment in place of mutRRE-A.

D. V 1 Jns-tPA-gp 143/opt32- A:

This constmct was derived from IVB by Avrll and Srfl restriction enzyme digestion followed by ligation of a synthetic DNA segment corresponding to gp32 but comprised of optimal codons for translation (see gp32 opt below). The resulting products were verified by DNA sequencing of ligation junctions and immunoblot analysis. E. VUns-tPA-gpl43/opt32-B:

This constmct is similar to IVD except that the env proteolytic cleavage sites have been retained by using IVC as the initial plasmid.

F. VUns-tPA-gpl43/SRV-l 3'-UTR:

This constmct is similar to IVA except that the 3'-UTR derived from the Simian Retrovims-1 (SRV-1 , see below) was inserted into the Srfl restriction enzyme site introduced immediately 3'- of the gpl43 open reading frame. This UTR sequence has been described previously as facilitating rev-independent expression of HIV env and gag-

G. VI Jns-tPA-gp 143/opt Cl/opt32A: This constmct was based on IVD, having a complete optimized codon segment for C5 and gp32 with an additional optimized codon segment (see below) replacing Cl at the amino terminus of gpl20 following the tPA leader. The new Cl segment was joined to the remaining gpl43 segment via SOE PCR using the following oligomers for PCR to synthesize the joined Cl/143 segment: 5'-CCT GTG TGT GAG TTT AAA C TGC ACT GAT TTG AAG AAT GAT ACT AAT AC-3' (SEQ ID:26). The resulting gpl43 gene contains optimal codon useage except for VI -V5 regions and has a unique Pmel restriction enzyme site placed at the junction of Cl and VI for insertion of variable regions from other HIV genes.

H. VUns-tPA-gpl43/opt Cl/opt32B:

This constmct is similar to IVH except that the env proteolytic cleavage sites have been retained. I. VI Jns-tPA-gp 143/opt all-A:

The env gene of this constmct is comprised completely of optimal codons. The constant regions (Cl , C5, gp32) are those described in 4B,D,H with an additional synthetic DNA segment corresponding to variable regions VI -V5 is inserted using a synthetic DNA segment comprised of optimal codons for translation.

J. VUns-tPA-gpl43/opt all-B:

This constmct is similar to IVJ except that the env proteolytic cleavage sites have been retained.

K. VI Jns-tPA-gp 143/opt all-A (non-IIIB strains):

This constmct is similar to IIIG above except that env amino acid sequences from strains other than IIIB were used to determine optimum codon useage throughout the variable (VI -V5) regions.

L. VI Jns-tPA-gp 143/opt all-B (non-IIIB strains):

This constmct is similar to IIIG above except that env amino acid sequences from strains other than IIIB were used to determine optimum codon useage throughout the variable (V1-V5) regions.

EXAMPLE 10 gp!43/glvB Vaccine Constmcts:

These constmcts were prepared by PCR similarly as other tPA-containing constmcts described above (tPA-gpl20, tPA-gpl40, tPA-gpl43 and tPA-gpl60), with the tPA leader in place of the native leader, but designed to produce COOH -terminated, membrane -bound env as with gpl43. However, gpl43/glyB constmcts differ from gpl43 in that of the six amino acids projected to comprise the intracellular peptide domain, the last 4 are the same those at the carboxyl terminus of human glycophorin B (glyB) protein (projected intracellular amino acid sequence= NH2-NRLJKA-COOH (SEQ.ID:27) with the underlined residues corresponding to glyB and "R" common to both env and glyB). This constmct was designed with the puφose gaining additional env expression and directed targeting to the cell surface by completely eliminating any transcript or peptide region corresponding to the intracellular portion of env that might negatively impact expression or protein stability/transport to the cell surface by replacing this region with a peptide sequence from an abundantly expressed protein (glyB) having a short cytoplasmic domain (intracellular amino acid sequence= NH2-RRLIKA-COOH). Constmcts were prepared in two forms (A or B) depending upon whether the gpl60 proteolytic cleavage sites were removed or retained as described above.

A. V 1 Jns-tPA-gp 143/opt32- A/glvB :

This constmct is the same as IVD except that the following antisense PCR oligomer was used to replace the intracellular peptide domain of gpl43 with that of glycophorin B as described above: 5'- CCA CAT GAT ATC G CCC GGG C TTA TTA GGC CTT GAT CAG CCG GTT CAC AAT GGA CAG CAC AGC-3' (SEQ ID:28).

B. VUns-tPA-gpl43/opt32-B/glvB: This constmct is similar to VA except that the env proteolytic cleavage sites have been retained.

C. VUns-tPA-gpl43/opt Cl/opt32-A/glvB:

This constmct is the same as VA except that the first constant region (Cl) of gpl20 is replaced by optimal codons for translation as with IVH.

D. V 1 Jns-tPA-gp 143/opt C 1 /opt32-B/gl vB :

This constmct is similar to VC except that the env proteolytic cleavage sites have been retained.

E. VI Jns-tPA-gp 143/opt all-A/glvB:

The env gene of this constmct is comprised completely of optimal codons as described above. F. VUns-tPA-_gpl43/opt all-B/glvB:

This constmct is similar to VE except that the env proteolytic cleavage sites have been retained.

G. VUns-tPA-gpl43/opt all-A/glvB (non-HIB strains):

H. VUns-tPA-gpl43/opt all-B/glvB (non-IIIB strains):

This constmct is similar to VG except that the env proteolytic cleavage sites have been retained.

HIV env Vaccine Constmcts with Variable Loop Deletions:

These constmcts may include all env forms listed above (gpl20, gpl40, gpl43, gpl60, gpl43/glyB) but have had variable loops within the gpl20 region deleted during preparation (e.g., VI , V2, and/or V3). The puφose of these modifications is to eliminate peptide segments which may occlude exposure of conserved neutralization epitopes such as the CD4 binding site. For example, the following oligomer was used in a PCR reaction to create a V1/V2 deletion resulting in adjoining THE Cl and C2 segments: 5'-CTG ACC CCC CTG TGT GTG GGG GCT GGC AGT TGT AAC ACC TCA GTC ATT ACA CAG-3' (SEQ ID:29).

EXAMPLE 1 1 Design of Synthetic Gene Segments for Increased env Gene Expression: Gene segments were converted to sequences having identical translated sequences (except where noted) but with altemative codon usage as defined by R. Lathe in a research article from J. Molec. Biol. Vol. 183, pp. 1-12 (1985) entitled "Synthetic Oligonucleotide Probes Deduced from Amino Acid Sequence Data: Theoretical and Practical Considerations". The methodology described below to increase rev-independent expression of HIV env gene segments was based on our hypothesis that the known inability to express this gene efficiently in mammalian cells is a consequence of the overall transcript composition. Thus, using altemative codons encoding the same protein sequence may remove the constraints on env expression in the absence of rev. Inspection of the codon usage within env revealed that a high percentage of codons were among those infrequently used by highly expressed human genes. The specific codon replacement method employed may be described as follows employing data from Lathe et al.:

1. Identify placement of codons for proper open reading frame.

2. Compare wild type codon for observed frequency of use by human genes (refer to Table 3 in Lathe et al.). 3. If codon is not the most commonly employed, replace it with an optimal codon for high expression based on data in Table 5.

4. Inspect the third nucleotide of the new codon and the first nucleotide of the adjacent codon immediately 3'- of the first. If a 5'-CG-3' pairing has been created by the new codon selection, replace it with the choice indicated in Table 5.

5. Repeat this procedure until the entire gene segment has been replaced.

6. Inspect new gene sequence for undesired sequences generated by these codon replacements (e.g., "ATTTA" sequences, inadvertent creation of intron splice recognition sites, unwanted restriction enzyme sites, etc.) and substitute codons that eliminate these sequences.

7. Assemble synthetic gene segments and test for improved expression. These methods were used to create the following synthetic gene segments for HIV env creating a gene comprised entirely of optimal codon usage for expression: (i) gp120-Cl (opt); (ii) VI -V5 (opt); (iii) RRE-A/B (mut or opt); and (iv) gp30 (opt) with percentages of codon replacements/nucleotide substitutions of 56/19, 73/26, 78/28, and 61/25 obtained for each segment, respectively. Each of these segments has been described in detail above with actual sequences listed below.

gp120-C1 (opt) This is a gpl20 constant region 1 (Cl) gene segment from the mature N-terminus to the beginning of V 1 designed to have optimal codon usage for expression.

AGTT

MN V1-V5 (opt)

This is a gene segment corresponding to the derived protein sequence for HIV MN V1 -V5 (1066BP) having optimal codon usage for expression.

RRE.Mut (A)

This is a DNA segment corresponding to the rev response element

(RRE) of HIV-1 comprised of optimal codon usage for expression. The "A" form also has removed the known proteolytic cleavage sites at the gpl20/gp41 junction by using the nucleotides indicated in boldface.

CAGAACGAGC

RRE.Mut (B)

This is a DNA segment corresponding to the rev response element (RRE) of HIV-1 comprised of optimal codon usage for expression. The "B" form retains the known proteolytic cleavage sites at the gpl20/gp41 junction.

CAGAGAGAGA

gp32 (opt)

This is a gp32 gene segment from the Avrll site (starting immediately at the end of the RRE) to the end of gpl43 comprised of optimal codons for expression.

ID34) SRV-1 CTE (A)

This is a synthetic gene segment corresponding to a 3'-UTR from the Simian Retrovims-l genome. This DNA is placed in the following orientation at the 3'-terminus of HIV genes to increase rev-independent expression.

SRV-1 CTE IB)

This synthetic gene segment is identical to SRV-1 CTE (A) shown above except that a single nucleotide mutation was used (indicated by boldface) to eliminate an ATTTA sequence. This sequence has been associated with increased mRNA turnover.

EXAMPLE 1 1 In Vitro gp!20 Vaccine Expression:

In vitro expression was tested in transfected human rhabdomyosarcoma (RD) cells for these constmcts. Quantitation of secreted tPA-gpl20 from transfected RD cells showed that VUns-tPA- gp 120 vector produced secreted gp 120.

In Vivo gp!20 Vaccination: VI Jns-tPA-gp 120MN PNV-induced Class II MHC- restricted T lymphocyte gp!20 specific antigen reactivities. Balb/c mice which had been vaccinated two times with 200 μg VI Jns-tPA-gp 120MN were sacrificed and their spleens extracted for in vitro determinations of helper T lymphocyte reactivities to recombinant gpl20. T cell proliferation assays were performed with PBMC (peripheral blood mononuclear cells) using recombinant gpl20lHB (Repligen, catalogue #RP1016-20) at 5 μg/ml with 4 x 10⁵ cells/ml. Basal levels of ³H- thymidine uptake by these cells were obtained by culturing the cells in media alone, while maximum proliferation was induced using ConA stimulation at 2 μg/ml. ConA-induced reactivities peak at -3 days and were harvested at that time point with media control samples while antigen-treated samples were harvested at 5 days with an additional media control. Vaccinated mice responses were compared with naive, age-matched syngeneic mice. ConA positive controls gave very high proliferation for both naive and immunized mice as expected. Very strong helper T cell memory responses were obtained by gpl20 treatment in vaccinated mice while the naive mice did not respond (the threshold for specific reactivity is an stimulation index (SI) of >3-4; SI is calculated as the ratio of sample cpm/media cpm). Si's of 65 and 14 were obtained for the vaccinated mice which compares with anti-gpl20 ELISA titers of 5643 and 11,900, respectively, for these mice. Interestingly, for these two mice the higher responder for antibody gave significantly lower T cell reactivity than the mouse having the lower antibody titer. This experiment demonstrates that the secreted gp 120 vector efficiently activates helper T cells in vivo as well as generates strong antibody responses. In addition, each of these immune responses was determined using antigen which was heterologous compared to that encoded by the inoculation PNV (IIIB vs. MN):

EXAMPLE 12 gp 160 Vaccines

In addition to secreted gpl20 constmcts, we have prepared expression constmcts for full-length, membrane-bound gpl60. The rationales for a gpl60 constmct, in addition to gpl20, are (1) more epitopes are available both for both CTL stimulation as well as neutralizing antibody production including gp41, against which a potent HIV neutralizing monoclonal antibody (2F5, see above) is directed; (2) a more native protein stmcture may be obtained relative to virus- produced gpl60; and, (3) the success of membrane-bound influenza HA constmcts for immunogenicity [Ulmer et al., Science 259: 1745-1749. 1993; Montgomery, D., et al.. DNA and Cell Biol.. 12:777-783. 1993]. gpl60 retains substantial rev dependence even with a heterologous leader peptide sequence so that further constmcts were made to increase expression in the absence of rev.

EXAMPLE 13

Assay For HIV Cytotoxic T-Lvmphocytes:

The methods described in this section illustrate the assay as used for vaccinated mice. An essentially similar assay can be used with primates except that autologous B cell lines must be established for use as target cells for each animal. This can be accomplished for humans using the Epstein-Barr vims and for rhesus monkey using the heφes B virus.

Peripheral blood mononuclear cells (PBMC) are derived from either freshly drawn blood or spleen using Ficoll-Hypaque centrifugation to separate erythrocytes from white blood cells. For mice, lymph nodes may be used as well. Effecter CTLs may be prepared from the PBMC either by in vitro culture in IL-2 (20 U/ml) and concanavalin A (2μg/ml) for 6-12 days or by using specific antigen using an equal number of irradiated antigen presenting cells. Specific antigen can consist of either synthetic peptides (9-15 amino acids usually) that are known epitopes for CTL recognition for the MHC haplotype of the animals used, or vaccinia vims constmcts engineered to express appropriate antigen. Target cells may be either syngeneic or MHC haplotype-matched cell lines which have been treated to present appropriate antigen as described for in vitro stimulation of the CTLs. For Balb/c mice the PI 8 peptide

(ArglleHisIleGlyProGlyArgAlaPheTyrThrThrLysAsn [SEQ.ID:37], for HIV MN strain) can be used at 10 μM concentration to restimulate CTL in vitro using irradiated syngeneic splenocytes and can be used to sensitize target cells during the cytotoxicity assay at 1-10 μM by incubation at 37°C for about two hours prior to the assay. For these H- lA MHC haplotype mice, the murine mastocytoma cell line, P815, provides good target cells. Antigen-sensitized target cells are loaded with Na^ 1 Crθ4, which is released from the interior of the target cells upon killing by CTL, by incubation of targets for 1-2 hours at 37°C (0.2 mCi for -5 x 106 cells) followed by several washings of the target cells. CTL populations are mixed with target cells at varying ratios of effectors to targets such as 100:1 , 50:1, 25:1, etc., pelleted together, and incubated 4-6 hours at 37°C before harvest of the supematants which are then assayed for release of radioactivity using a gamma counter. Cytotoxicity is calculated as a percentage of total releasable counts from the target cells (obtained using 0.2% Triton X-100 treatment) from which spontaneous release from target cells has been subtracted.

EXAMPLE 14 Assay For HIV Specific Antibodies:

ELISA were designed to detect antibodies generated against HIV using either specific recombinant protein or synthetic peptides as substrate antigens. 96 well microtiter plates were coated at 4°C overnight with recombinant antigen at 2 μg/ml in PBS (phosphate buffered saline) solution using 50 μl/well on a rocking platform. Antigens consisted of either recombinant protein (gpl20, rev: Repligen Coφ.; gpl60, gp41 : American Bio-Technologies, Inc.) or synthetic peptide (V3 peptide corresponding to vims isolate sequences from IIIB, etc.: American Bio-Technologies, Inc.; gp41 epitope for monoclonal antibody 2F5). Plates were rinsed four times using wash buffer (PBS/0.05% Tween 20) followed by addition of 200μl/well of blocking buffer (1 % Carnation milk solution in PBS/0.05% Tween-20) for 1 hr at room temperature with rocking. Pre-sera and immune sera were diluted in blocking buffer at the desired range of dilutions and 100 μl added per well. Plates were incubated for 1 hr at room temperature with rocking and then washed four times with wash buffer. Secondary antibodies conjugated with horse radish peroxidase, (anti-rhesus Ig, Southern Biotechnology Associates; anti- mouse and anti-rabbit Igs,

Jackson Immuno Research) diluted 1 :2000 in blocking buffer, were then added to each sample at 100 μl/well and incubated 1 hr at room temperature with rocking. Plates were washed 4 times with wash buffer and then developed by addition of 100 μl/well of an o-phenylenediamine (o-PD, Calbiochem) solution at 1 mg/ml in 100 mM citrate buffer at pH 4.5. Plates were read for absorbance at 450 nm both kinetically (first ten minutes of reaction) and at 10 and 30 minute endpoints (Thermo- max microplate reader, Molecular Devices).

EXAMPLE 15 Assay For HIV Neutralizing Antibodies:

In vitro neutralization of HIV isolates assays using sera derived from vaccinated animals was performed as follows. Test sera and pre-immune sera were heat inactivated at 56°c for 60 min before use. A titrated amount of HIV-1 was added in 1 :2 serial dilutions of test sera and incubated 60 min at room temperature before addition to 10^ MT-4 human lymphoid cells in 96 well microtiter plates. The vims/cell mixtures were incubated for 7 days at 37°C and assayed for virus- mediated killing of cells by staining cultures with tetrazolium dye.

Neutralization of vims is observed by prevention of vims-mediated cell death.

EXAMPLE 16 Isolation Of Genes From Clinical HIV Isolates:

HIV viral genes were cloned from infected PBMC's which had been activated by ConA treatment. The preferred method for obtaining the viral genes was by PCR amplification from infected cellular genome using specific oligomers flanking the desired genes. A second method for obtaining viral genes was by purification of viral RNA from the supematants of infected cells and preparing cDNA from this material with subsequent PCR. This method was very analogous to that described above for cloning of the murine B7 gene except for the PCR oligomers used and random hexamers used to make cDNA rather than specific priming oligomers.

Genomic DNA was purified from infected cell pellets by lysis in STE solution (10 mM NaCl, 10 mM EDTA, 10 mM Tris-HCl, pH 8.0) to which Proteinase K and SDS were added to 0.1 mg/ml and 0.5% final concentrations, respectively. This mixture was incubated overnight at 56°C and extracted with 0.5 volumes of phenol :chloroform:isoamyl alcohol (25:24:1). The aqueous phase was then precipitated by addition of sodium acetate to 0.3 M final concentration and two volumes of cold ethanol. After pelleting the DNA from solution the DNA was resuspended in 0.1X TE solution (IX TE = 10 mM Tris-HCl, pH 8.0, 1 mM EDTA). At this point SDS was added to 0.1 % with 2 U of RNAse A with incubation for 30 minutes at 37°C. This solution was extracted with phenol/chloroform/isoamyl alcohol and then precipitated with ethanol as before. DNA was suspended in 0.1 X TE and quantitated by measuring its ultraviolet absorbance at 260 nm. Samples were stored at -20°C until used for PCR.

PCR was performed using the Perkin-Elmer Cetus kit and procedure using the following sense and antisense oligomers for gpl60: 5'-GA AAG AGC AGA AGA CAG TGG CAA TGA -3' (SEQ.ID:38) and 5'-GGG CTT TGC TAA ATG GGT GGC AAG TGG CCC GGG C ATG TGG-3' (SEQ.LD:39), respectively. These oligomers add an Srfl site at the 3'-terminus of the resulting DNA fragment. PCR-derived segments are cloned into either the VlJns or VI R vaccination vectors and V3 regions as well as ligation junction sites confirmed by DNA sequencing.

EXAMPLE 17 T Cell Proliferation Assays: PBMCs are obtained and tested for recall responses to specific antigen as determined by proliferation within the PBMC population. Proliferation is monitored using -^H-thymidine which is added to the cell cultures for the last 18-24 hours of incubation before harvest. Cell harvesters retain isotope-containing DNA on filters if proliferation has occurred while quiescent cells do not incoφorate the isotope which is not retained on the filter in free form. For either rodent or primate species 4 X 10^ cells are plated in 96 well microtiter plates in a total of 200 μl of complete media (RPMI/10% fetal calf semm). Background proliferation responses are determined using PBMCs and media alone while nonspecific responses are generated by using lectins such as phytohaemagglutin (PHA) or concanavalin A (ConA) at 1- 5 μg/ml concentrations to serve as a positive control. Specific antigen consists of either known peptide epitopes, purified protein, or inactivated vims. Antigen concentrations range from 1 - 10 μM for peptides and 1-10 μg/ml for protein. Lectin-induced proliferation peaks at 3-5 days of cell culture incubation while antigen- specific responses peak at 5-7 days. Specific proliferation occurs when radiation counts are obtained which are at least three-fold over the media background and is often given as a ratio to background, or

Stimulation Index (SI). HIV gpl60 is known to contain several peptides known to cause T cell proliferation of gpl60/gpl20 immunized or HIV- infected individuals. The most commonly used of these are: Tl (LysGlnllelleAsnMetTφGlnGluValGlyLysAlaMetTyrAla [SEQ.LD:40]); T2 (HisGluAspIlelleSerLeuTφAspGlnSerLeuLys

[SEQ.ID:41]; and, TH4 (AspArgVallleGluValValGlnGlyAlaTyrArgAla IleArg [SEQ.H):42]). These peptides have been demonstrated to stimulate proliferation of PBMC from antigen-sensitized mice, nonhuman primates, and humans.

EXAMPLE 18 Vector V1R Preparation:

In an effort to continue to optimize our basic vaccination vector, we prepared a derivative of VlJns which was designated as V1R. The puφose for this vector constmction was to obtain a minimum-sized vaccine vector, i.e., without unnecessary DNA sequences, which still retained the overall optimized heterologous gene expression characteristics and high plasmid yields that VIJ and VlJns afford. We determined from the literature as well as by experiment that (1) regions within the pUC backbone comprising the E. coli origin of replication could be removed without affecting plasmid yield from bacteria; (2) the 3'-region of the kan^γ gene following the kanamycin open reading frame could be removed if a bacterial terminator was inserted in its stead; and, (3) -300 bp from the 3'- half of the BGH terminator could be removed without affecting its regulatory function (following the original Kpnl restriction enzyme site within the BGH element).

V1R was constmcted by using PCR to synthesize three segments of DNA from VlJns representing the CMVintA promoter/BGH terminator, origin of replication, and kanamycin resistance elements, respectively. Restriction enzymes unique for each segment were added to each segment end using the PCR oligomers: Sspl and Xhol for CMVintA/BGH; EcoRV and BamHI for the kan ^r gene; and, Bell and Sail for the ori ^r. These enzyme sites were chosen because they allow directional ligation of each of the PCR-derived DNA segments with subsequent loss of each site: EcoRV and Sspl leave blunt- ended DNAs which are compatible for ligation while BamHI and Bell leave complementary overhangs as do Sail and Xhol. After obtaining these segments by PCR each segment was digested with the appropriate restriction enzymes indicated above and then ligated together in a single reaction mixture containing all three DNA segments. The 5'-end of the ori ^r was designed to include the T2 rho independent terminator sequence that is normally found in this region so that it could provide termination information for the kanamycin resistance gene. The ligated product was confirmed by restriction enzyme digestion (>8 enzymes) as well as by DNA sequencing of the ligation junctions. DNA plasmid yields and heterologous expression using viral genes within VI R appear similar to VlJns. The net reduction in vector size achieved was 1346 bp (VlJns = 4.86 kb; V1R = 3.52 kb), [SEQ.ID:43 of this specification; also see Figure 1 1 and SEQ ID: 100 of W095/24485; PCT International Application No. PCT/US95/02633].

PCR oligomer sequences used to synthesize VI R (restriction enzyme sites are underlined and identified in brackets following sequence):

(1) 5'-GGT ACA AAT ATT GG CTA TTG GCC ATT GCA TAC G-3^*

[Sspl], (SEQ.ID:44):, (2) 5 -CCA CAT CTC GAG GAA CCG GGT CAA TTC TTC AGC ACC-3' [Xhol], (SEQ.ID:45):

(for CMVintA/BGH segment)

(3) 5 -GGT ACA GAT ATC GGA AAG CCA CGT TGT GTC TCA AAA TC-3'[EcoRV], (SEQ.ID:46):

(4) 5 -CCA CAT GGA TCC G TAA TGC TCT GCC AGT GTT ACA ACC-3' [BamHI], (SEQ.ID:47):

(for kanamycin resistance gene segment)

(5) 5-GGTACATGA TCACGTAGAAAAGATCAA AGGATC TTC TTG-3'[BclI], (SEQ.ID.48):,

(6)5'-CCACATGTCGACCCGTAAAAAGG CCG CGTTGC TGG-3' [Sail], (SEQ.ID:49): (for E. coli origin of replication)

Ligation junctions were sequenced for VI R using the following oligomers:

5'-GAG CCA ATA TAA ATG TAC-3' (SEQ.LD:50): [CM Vint A/kan^r junction]

5'-CAA TAG CAG GCA TGC-3' (SEQ.ID:51 ): [BGH/ori junction]

5'-G CAA GCA GCA GAT TAC-3' (SEQ.ID:52): [ori/kanr junction]

EXAMPLE 19 Heterologous Expression of HIV Late Gene Products

HIV structural genes such as env and gag require expression of the HIV regulatory gene, rev, in order to efficiently produce full-length proteins. We have found that rev-dependent expression of gag yielded low levels of protein and that rev itself may be toxic to cells. Although we achieved relatively high levels of rev- dependent expression of gpl60 in vitro this vaccine elicited low levels of antibodies to gpl60 following in vivo immunization with rev/gpl60 DNA. This may result from known cytotoxic effects of rev as well as increased difficulty in obtaining rev function in myotubules containing hundreds of nuclei (rev protein needs to be in the same nucleus as a rev- dependent transcript in order for gag or env protein expression to occur). However, it has been possible to obtain rev-independent expression using selected modifications of the env gene.

1. rev-independent expression of env:

In general, our vaccines have utilized primarily HIV (IIIB) env and gag genes for optimization of expression within our generalized vaccination vector, VlJns, which is comprised of a CMV immediate- early (IE) promoter, a BGH-derived polyadenylation and transcriptional termination sequence, and a pUC backbone. Varying efficiencies, depending upon how large a gene segment is used (e.g., gpl20 vs. gpl60), of rev-independent expression may be achieved for env by replacing its native secretory leader peptide with that from the tissue- specific plasminogen activator (tPA) gene and expressing the resulting chimeric gene behind the CMVIE promoter with the CMV intron A. tPA-gpl20 is an example of a secreted gpl20 vector constructed in this fashion which functions well enough to elicit anti-gpl20 immune responses in vaccinated mice and monkeys.

Because of reports that membrane-anchored proteins may induce much more substantial (and perhaps more specific for HIV neutralization) antibody responses compared to secreted proteins as well as to gain additional epitopes, we prepared VUns-tPA-gpl60 and VUns- rev/gpl60. The tPA-gpl60 vector produced detectable quantities of gpl60 and gpl20, without the addition of rev, as shown by immunoblot analysis of transfected cells, although levels of expression were much lower than that obtained for rev/gpl60, a rev-dependent gpl60- expressing plasmid. This is probably because inhibitory regions, which confer rev dependence upon the gpl60 transcript, occur at multiple sites within gpl60 including at the COOH-terminus of gp41. A vector was prepared for a COOH-terminally tmncated form of tPA-gp 160 (tPA- gpl43) which was designed to increase the overall expression levels of env by elimination of these inhibitory sequences. The gpl43 vector also eliminates intracellular gp41 regions containing peptide motifs (such as Leu-Leu) known to cause diversion of membrane proteins to the lysosomes rather than the cell surface. Thus, gp 143 may be expected to have increased levels of expression of the env protein (by decreasing rev-dependence) and greater efficiency of transport of protein to the cell surface compared to full-length gpl60 where these proteins may be better able to elicit anti-gpl60 antibodies following DNA vaccination. tPA-gpl43 was further modified by extensive silent mutagenesis of the rev response element (RRE) sequence (350 bp) to eliminate additional inhibitory sequences for expression. This constmct, gpl43/mutRRE, was prepared in two forms: either eliminating (form A) or retaining (form B) proteolytic cleavage sites for gpl20/41. Both forms were prepared because of literature reports that vaccination of mice using uncleavable gpl60 expressed in vaccinia elicited much higher levels of antibodies to gpl60 than did cleavable forms.

A quantitative ELISA for gpl60/gpl20 expression in cell transfectants was developed to determine the relative expression capabilities for these vectors. In vitro transfection of 293 cells followed by quantification of cell-associated vs. secreted/released gpl20 yielded the following results: (1 ) tPA-gpl60 expressed 5-1 OX less gpl20 than rev/gpl60 with similar proportions retained intracellularly vs. released from the cell surface; (2) tPA-gpl43 gave 3-6X greater secretion of gpl20 than rev/gpl60 with only low levels of cell-associated gpl43, confirming that the cytoplasmic tail of gpl60 causes intracellular retention of gpl60 which can be overcome by partial deletion of this sequence; and, (3) tPA-gpl43/mutRRE A and B gave -10X greater expression levels of protein than did parental tPA-gpl43 while elimination of proteolytic processing was confirmed for form A.

Thus, our strategy to increase rev-independent expression has yielded stepwise increases in overall expression levels as well as redirecting membrane-anchored gpl43 to the cell surface away from lysosomes. It is important to note that this is a generic constmct into which it should be possible to insert gpl20 sequences derived from various primary viral isolates within a vector cassette containing these modifications which reside either at the NH2-terminus (tPA leader) or COOH-terminus (gρ41), where few antigenic differences exist between different viral strains.

Figures 2-7 present data supporting the use of various constmcts, including but not limited to a gp 143 -based constmct, and preferably a tPA-gpl43 based constmct, as a DNA vaccine against HIV infection. Figure 2 shows that tPA-143 (opt41) elicits an anti-gpl20 antibody response in the in the range of GMT=10 . Figure 3 measures and compares anti-gpl20 antibody titers for several DNA vaccines, including gpl43-based constmcts. Figure 4 shows the relative expression of tPA-gpl43 and tPA-143/mutRRE in comparison to the tPA-gpl60 constmct. Figure 5 measures generation of anti-gpl20 antibodies for both the optA and optB forms of tPA-gpl43 constmcts. Figure 6 shows the ability of several DNA vaccines, including tPA- gpl43-optA and tPA-gpl43-optB, to promote generation of neutralizing antibodies against HIV strains subsequent to murine DNA vaccination. Figure 7 also shows HIV neutralization data for various DNA vaccine constmctions, including tPA-gpl43-optA, tPA-gpl43-optB, tPA-gpl43- optA-glyB and tPA-gpl43-optB-glyB.

2. Expression of gp!20 derived from a clinical isolate:

To apply these expression strategies to vimses that are relevant for vaccine puφoses and confirm the generality of our approaches, we also prepared a tPA-gpl20 vector derived from a primary HIV isolate (containing the North American concensus V3 peptide loop; macrophage-tropic and nonsyncytia-inducing phenotypes). This vector gave high expression/secretion of gpl20 with transfected 293 cells and elicited anti-gpl20 antibodies in mice thus demonstrating that it was cloned in a functional form. Primary isolate gpl60 genes will also be used for expression in the same way as for gpl60 derived from laboratory strains. 3. Immune Responses to HIV-1 env Polynucleotide Vaccines

Effect of vaccination route on immune responses in mice: While efforts to improve expression of gpl60 are ongoing, we have utilized the tPA-gpl20 DNA constmct to assess immune responses and ways to augment them. Intramuscular (i.m.) and intradermal (i.d.) vaccination routes were compared for this vector at 100, 10, and 1 μg doses in mice. Vaccination by either route elicited antibody responses (GMTs = lO^-lO^) in all recipients following 2-3 vaccinations at all three dosage levels. Each route elicited similar anti-gpl20 antibody titers with clear dose-dependent responses. However, we observed greater variability of responses for i.d. vaccination, particularly at the lower doses following the initial inoculation. Moreover, helper T-cell responses, as determined by antigen-specific in vitro proliferation and cytokine secretion, were higher following i.m. vaccination than i.d. We concluded that i.d. vaccination did not offer any advantages compared to i.m. for this vaccine.

4. gp!20 DNA vaccine-mediated helper T cell immunity in mice: gpl20 DNA vaccination produced potent helper T-cell responses in all lymphatic compartments tested (spleen, blood, inguinal, mesenteric, and iliac nodes) with THl-like cytokine secretion profiles (i.e., g-interferon and IL-2 production with little or no IL-4). These cytokines generally promote strong cellular immunity and have been associated with maintenance of a disease-free state for HIV-seropositive patients. Lymph nodes have been shown to be primary sites for HIV replication, harboring large reservoirs of vims even when vims cannot be readily detected in the blood. A vaccine which can elicit anti-HIV immune responses at a variety of lymph sites, such as we have shown with our DNA vaccine, may help prevent successful colonization of the lymphatics following initial infection.

5. env DNA vaccine-mediated antibody responses:

African green (AGM) and Rhesus (RHM) monkeys which received gpl20 DNA vaccines showed low levels of neutralizing antibodies following 2-3 vaccinations, which could not be increased by additional vaccination. These results, as well as increasing awareness within the HIV vaccine field that oligomeric gpl60 is probably a more relevant target antigen for eliciting neutralizing antibodies than gpl20 monomers, have led us to focus upon obtaining effective expression of gpl60-based vectors (see above). Mice and AGM were also vaccinated with the primary isolate derived tPA-gpl20 vaccine. These animals exhibited anti-V3 peptide (using homologous sequence) reciprocal endpoint antibody titers ranging 500-5000, demonstrating that this vaccine design is functional for clinically relevant viral isolates. The gp 160-based vaccines , rev-gp 160 and tP A-gp 160, failed to consistently elicit antibody responses in mice and nonhuman primates or yielded low antibody titers. Our initial results with the tPA-gpl43 plasmid yielded geometric mean titers (GMT) > 10^ in mice and AGM following two vaccinations. These data indicate that we have signficantly improved the immunogenicity of gpl60-like vaccines by increasing expression levels and more efficient intracellular trafficking of env to the cell surface. This constmct, as well as the tPA- gpl43/mutRRE A and B vectors, will continue to be characterized for antibody responses, especially for vims neutralization.

6. env DNA vaccine-mediated CTL responses in monkevs:

We continued to characterize CTL responses of RHM that had been vaccinated with gpl20 and gpl60/IRES/rev DNA. All four monkeys that received this vaccine showed significant MHC Class I- restricted CTL activities (20-35% specific killing at an effector/target = 20) following two vaccinations. Following a fourth vaccination these activities increased to 50-60% killing under similar test conditions, indicating that additional vaccination boosted responses significantly. The CTL activities have persisted for at least seven months subsequent to the final vaccination at about 50% of their peak levels indicating that long-term memory had been established. EXAMPLE 20 SIV/HIV (SfflV) Chimeras:

A major obstacle for testing the protective efficacy of candidate HTV-l vaccines has been the lack of a suitable animal challenge model for this vims. Although the simian immunodeficiency vims (SIV), which is closely related to HIV, is infectious and causes AIDS in rhesus monkeys, the only animal species which can be infected with HIV-1 viral isolates is the chimpanzee. However, the resulting viremia from this infection is low-level, transient, and no pathogenic effects (e.g., lymphopenia, immunodeficiency-related opportunistic infections, etc.) develop. Recently, hybrid vimses comprised of SIV and HIV genomes have been developed which are also infectious to rhesus monkeys and which can cause infection-related AIDS. An example of this type of vims is SHIV-4 (IIIB) (Li et al., J. of Acquired Immune Deficiency Syndrome, Vol. 5, 639-646 (1992)). This vims contains the SIV (MAC239) genome except for the regulatory genes, tat and rev, and the structural gene, env. Because the principle component of candidate HIV vaccines is based upon env this vims allows testing vaccines developed for human clinical puφoses for protective efficacy against infection in an animal model.

EXAMPLE 21 Plasmid DNA and Recombinant Protein Combination Vaccines:

Vaccines having both a plasmid DNA HIV env component and a recombinant HIV env protein component were tested for their abilities to induce antibody responses in rhesus monkeys. Figure 9 and Figure 10 show the resulting anti-gpl20 ELISA antibody and SHIV-4 (IIIB) vims neutralizing antibody titers, respectively, following vaccination of rhesus with HIV env gene-containing DNA vaccines and recombinant protein (formulated in an appropriate adjuvant). These monkeys developed high titers of env-specific antibodies and neutralizing antibodies. Control monkeys, vaccinated with "blank" DNA that did not contain a gene and ovalbumin did not develop any detectable env-specific responses while monkeys vaccinated only with the protein component of this vaccine showed low levels of antigen- specific antibodies detected by ELISA and no neutralizing antibodies. When these monkeys were challenged with SHIV-4 (IIIB) vims all control and protein only monkeys became infected while those receiving both env DNA and protein did not develop a detectable SHIV viremia. These monkeys are currently being tested periodically for possible delayed onset of infection.

SEQUENCE LISTING

(1) GENERAL INFORMATION:

(l) APPLICANTS: MERCK & CO. , INC.

(ii) TITLE OF INVENTION: VACCINES COMPRISING SYNTHETIC GENES

(iii) NUMBER OF SEQUENCES: 53

(iv) CORRESPONDENCE ADDRESS:

(A) ADDRESSEE: J. MARK HAND - MERCK & CO. , INC.

(B) STREET: 126 E. LINCOLN AVE., P.O. BOX 2000

(C) CITY: RAHWAY

(D) STATE: NEW JERSEY

(E) COUNTRY: US

(F) ZIP: 07065-0907

(v) COMPUTER READABLE FORM:

(A) MEDIUM TYPE: Floppy disk

(B) COMPUTER: IBM PC compatible

(C) OPERATING SYSTEM: PC-DOS/MS-DOS

(D) SOFTWARE: Patentin Release #1.0, Version #1.30

(vi) CURRENT APPLICATION DATA:

(A) APPLICATION NUMBER:

(B) FILING DATE:

(C) CLASSIFICATION:

(vill) ATTORNEY/AGENT INFORMATION:

(A) NAME: HAND, J. MARK

(B) REGISTRATION NUMBER: 36,545

(C) REFERENCE/DOCKET NUMBER: 19729Y PCT

(IX) TELECOMMUNICATION INFORMATION:

(A) TELEPHONE: 908-594-3905

(B) TELEFAX: 908-594-4720

(2) INFORMATION FOR SEQ ID NO:1 :

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 4864 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: double

(D) TOPOLOGY: both (ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:l:

TCGCGCGTTT CGGTGATGAC GGTGAAAACC TCTGACACAT GCAGCTCCCG GAGACGGTCA 60

CAGCTTGTCT GTAAGCGGAT GCCGGGAGCA GACAAGCCCG TCAGGGCGCG TCAGCGGGTG 120

TTGGCGGGTG TCGGGGCTGG CTTAACTATG CGGCATCAGA GCAGATTGTA CTGAGAGTGC 180

ACCATATGCG GTGTGAAATA CCGCACAGAT GCGTAAGGAG AAAATACCGC ATCAGATTGG 240

CTATTGGCCA TTGCATACGT TGTATCCATA TCATAATATG TACATTTATA TTGGCTCATG 300

TCCAACATTA CCGCCATGTT GACATTGATT ATTGACTAGT TATTAATAGT AATCAATTAC 360

GGGGTCATTA GTTCATAGCC CATATATGGA GTTCCGCGTT ACATAACTTA CGGTAAATGG 420

CCCGCCTGGC TGACCGCCCA ACGACCCCCG CCCATTGACG TCAATAATGA CGTATGTTCC 480

CATAGTAACG CCAATAGGGA CTTTCCATTG ACGTCAATGG GTGGAGTATT TACGGTAAAC 540

TGCCCACTTG GCAGTACATC AAGTGTATCA TATGCCAAGT ACGCCCCCTA TTGACGTCAA 600

TGACGGTAAA TGGCCCGCCT GGCATTATGC CCAGTACATG ACCTTATGGG ACTTTCCTAC 660

TTGGCAGTAC ATCTACGTAT TAGTCATCGC TATTACCATG GTGATGCGGT TTTGGCAGTA 720

CATCAATGGG CGTGGATAGC GGTTTGACTC ACGGGGATTT CCAAGTCTCC ACCCCATTGA 780

CGTCAATGGG AGTTTGTTTT GGCACCAAAA TCAACGGGAC TTTCCAAAAT GTCGTAACAA 840

CTCCGCCCCA TTGACGCAAA TGGGCGGTAG GCGTGTACGG TGGGAGGTCT ATATAAGCAG 900

AGCTCGTTTA GTGAACCGTC AGATCGCCTG GAGACGCCAT CCACGCTGTT TTGACCTCCA 960

TAGAAGACAC CGGGACCGAT CCAGCCTCCG CGGCCGGGAA CGGTGCATTG GAACGCGGAT 1020

TCCCCGTGCC AAGAGTGACG TAAGTACCGC CTATAGAGTC TATAGGCCCA CCCCCTTGGC 1080

TTCTTATGCA TGCTATACTG TTTTTGGCTT GGGGTCTATA CACCCCCGCT TCCTCATGTT 1140

ATAGGTGATG GTATAGCTTA GCCTATAGGT GTGGGTTATT GACCATTATT GACCACTCCC 1200

CTATTGGTGA CGATACTTTC CATTACTAAT CCATAACATG GCTCTTTGCC ACAACTCTCT 1260

TTATTGGCTA TATGCCAATA CACTGTCCTT CAGAGACTGA CACGGACTCT GTATTTTTAC 1320

AGGATGGGGT CTCATTTATT ATTTACAAAT TCACATATAC AACACCACCG TCCCCAGTGC 1380

CCGCAGTTTT TATTAAACAT AACGTGGGAT CTCCACGCGA ATCTCGGGTA CGTGTTCCGG 1440 ACATGGGCTC TTCTCCGGTA GCGGCGGAGC TTCTACATCC GAGCCCTGCT CCCATGCCTC 1500

CAGCGACTCA TGGTCGCTCG GCAGCTCCTT GCTCCTAACA GTGGAGGCCA GACTTAGGCA 1560

CAGCACGATG CCCACCACCA CCAGTGTGCC GCACAAGGCC GTGGCGGTAG GGTATGTGTC 1620

TGAAAATGAG CTCGGGGAGC GGGCTTGCAC CGCTGACGCA TTTGGAAGAC TTAAGGCAGC 1680

GGCAGAAGAA GATGCAGGCA GCTGAGTTGT TGTGTTCTGA TAAGAGTCAG AGGTAACTCC 1740

CGTTGCGGTG CTGTTAACGG TGGAGGGCAG TGTAGTCTGA GCAGTACTCG TTGCTGCCGC 1800

GCGCGCCACC AGACATAATA GCTGACAGAC TAACAGACTG TTCCTTTCCA TGGGTCTTTT 1860

CTGCAGTCAC CGTCCTTAGA TCTGCTGTGC CTTCTAGTTG CCAGCCATCT GTTGTTTGCC 1920

CCTCCCCCGT GCCTTCCTTG ACCCTGGAAG GTGCCACTCC CACTGTCCTT TCCTAATAAA 1980

ATGAGGAAAT TGCATCGCAT TGTCTGAGTA GGTGTCATTC TATTCTGGGG GGTGGGGTGG 2040

GGCAGCACAG CAAGGGGGAG GATTGGGAAG ACAATAGCAG GCATGCTGGG GATGCGGTGG 2100

GCTCTATGGG TACCCAGGTG CTGAAGAATT GACCCGGTTC CTCCTGGGCC AGAAAGAAGC 2160

AGGCACATCC CCTTCTCTGT GACACACCCT GTCCACGCCC CTGGTTCTTA GTTCCAGCCC 2220

CACTCATAGG ACACTCATAG CTCAGGAGGG CTCCGCCTTC AATCCCACCC GCTAAAGTAC 2280

TTGGAGCGGT CTCTCCCTCC CTCATCAGCC CACCAAACCA AACCTAGCCT CCAAGAGTGG 2340

GAAGAAATTA AAGCAAGATA GGCTATTAAG TGCAGAGGGA GAGAAAATGC CTCCAACATG 2400

TGAGGAAGTA ATGAGAGAAA TCATAGAATT TCTTCCGCTT CCTCGCTCAC TGACTCGCTG 2460

CGCTCGGTCG TTCGGCTGCG GCGAGCGGTA TCAGCTCACT CAAAGGCGGT AATACGGTTA 2520

TCCACAGAAT CAGGGGATAA CGCAGGAAAG AACATGTGAG CAAAAGGCCA GCAAAAGGCC 2580

AGGAACCGTA AAAAGGCCGC GTTGCTGGCG TTTTTCCATA GGCTCCGCCC CCCTGACGAG 2640

CATCACAAAA ATCGACGCTC AAGTCAGAGG TGGCGAAACC CGACAGGACT ATAAAGATAC 2700

CAGGCGTTTC CCCCTGGAAG CTCCCTCGTG CGCTCTCCTG TTCCGACCCT GCCGCTTACC 2760

GGATACCTGT CCGCCTTTCT CCCTTCGGGA AGCGTGGCGC TTTCTCAATG CTCACGCTGT 2820

AGGTATCTCA GTTCGGTGTA GGTCGTTCGC TCCAAGCTGG GCTGTGTGCA CGAACCCCCC 2880

GTTCAGCCCG ACCGCTGCGC CTTATCCGGT AACTATCGTC TTGAGTCCAA CCCGGTAAGA 2940

CACGACTTAT CGCCACTGGC AGCAGCCACT GGTAACAGGA TTAGCAGAGC GAGGTATGTA 3000 GGCGGTGCTA CAGAGTTCTT GAAGTGGTGG CCTAACTACG GCTACACTAG AAGGACAGTA 3060

TTTGGTATCT GCGCTCTGCT GAAGCCAGTT ACCTTCGGAA AAAGAGTTGG TAGCTCTTGA 3120

TCCGGCAAAC AAACCACCGC TGGTAGCGGT GGTTTTTTTG TTTGCAAGCA GCAGATTACG 3180

CGCAGAAAAA AAGGATCTCA AGAAGATCCT TTGATCTTTT CTACGGGGTC TGACGCTCAG 3240

TGGAACGAAA ACTCACGTTA AGGGATTTTG GTCATGAGAT TATCAAAAAG GATCTTCACC 3300

TAGATCCTTT TAAATTAAAA ATGAAGTTTT AAATCAATCT AAAGTATATA TGAGTAAACT 3360

TGGTCTGACA GTTACCAATG CTTAATCAGT GAGGCACCTA TCTCAGCGAT CTGTCTATTT 3420

CGTTCATCCA TAGTTGCCTG ACTCCGGGGG GGGGGGGCGC TGAGGTCTGC CTCGTGAAGA 3480

AGGTGTTGCT GACTCATACC AGGCCTGAAT CGCCCCATCA TCCAGCCAGA AAGTGAGGGA 3540

GCCACGGTTG ATGAGAGCTT TGTTGTAGGT GGACCAGTTG GTGATTTTGA ACTTTTGCTT 3600

TGCCACGGAA CGGTCTGCGT TGTCGGGAAG ATGCGTGATC TGATCCTTCA ACTCAGCAAA 3660

AGTTCGATTT ATTCAACAAA GCCGCCGTCC CGTCAAGTCA GCGTAATGCT CTGCCAGTGT 3720

TACAACCAAT TAACCAATTC TGATTAGAAA AACTCATCGA GCATCAAATG AAACTGCAAT 3780

TTATTCATAT CAGGATTATC AATACCATAT TTTTGAAAAA GCCGTTTCTG TAATGAAGGA 3840

GAAAACTCAC CGAGGCAGTT CCATAGGATG GCAAGATCCT GGTATCGGTC TGCGATTCCG 3900

ACTCGTCCAA CATCAATACA ACCTATTAAT TTCCCCTCGT CAAAAATAAG GTTATCAAGT 3960

GAGAAATCAC CATGAGTGAC GACTGAATCC GGTGAGAATG GCAAAAGCTT ATGCATTTCT 4020

TTCCAGACTT GTTCAACAGG CCAGCCATTA CGCTCGTCAT CAAAATCACT CGCATCAACC 4080

AAACCGTTAT TCATTCGTGA TTGCGCCTGA GCGAGACGAA ATACGCGATC GCTGTTAAAA 4140

GGACAATTAC AAACAGGAAT CGAATGCAAC CGGCGCAGGA ACACTGCCAG CGCATCAACA 4200

ATATTTTCAC CTGAATCAGG ATATTCTTCT AATACCTGGA ATGCTGTTTT CCCGGGGATC 4260

GCAGTGGTGA GTAACCATGC ATCATCAGGA GTACGGATAA AATGCTTGAT GGTCGGAAGA 4320

GGCATAAATT CCGTCAGCCA GTTTAGTCTG ACCATCTCAT CTGTAACATC ATTGGCAACG 4380

CTACCTTTGC CATGTTTCAG AAACAACTCT GGCGCATCGG GCTTCCCATA CAATCGATAG 4440

ATTGTCGCAC CTGATTGCCC GACATTATCG CGAGCCCATT TATACCCATA TAAATCAGCA 4500

TCCATGTTGG AATTTAATCG CGGCCTCGAG CAAGACGTTT CCCGTTGAAT ATGGCTCATA 4560 ACACCCCTTG TATTACTGTT TATGTAAGCA GACAGTTTTA TTGTTCATGA TGATATATTT 4620

TTATCTTGTG CAATGTAACA TCAGAGATTT TGAGACACAA CGTGGCTTTC CCCCCCCCCC 4680

CATTATTGAA GCATTTATCA GGGTTATTGT CTCATGAGCG GATACATATT TGAATGTATT 4740

TAGAAAAATA AACAAATAGG GGTTCCGCGC ACATTTCCCC GAAAAGTGCC ACCTGACGTC 4800

TAAGAAACCA TTATTATCAT GACATTAACC TATAAAAATA GGCGTATCAC GAGGCCCTTT 4860

CGTC 4864

(2) INFORMATION FOR SEQ ID NO:2:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 78 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:2 :

GATCACCATG GATGCAATGA AGAGAGGGCT CTGCTGTGTG CTGCTGCTGT GTGGAGCAGT 60

CTTCGTTTCG CCCAGCGA 78

(2) INFORMATION FOR SEQ ID NO:3 :

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 78 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(XI) SEQUENCE DESCRIPTION: SEQ ID NO:3 :

GATCTCGCTG GGCGAAACGA AGACTGCTCC ACACAGCAGC AGCACACAGC AGAGCCCTCT 60

CTTCATTGCA TCCATGGT 78

(2) INFORMATION FOR SEQ ID NO:4:

(l) SEQUENCE CHARACTERISTICS: (A) LENGTH: 39 base pairs (B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:4:

CCCCGGATCC TGATCACAGA AAAATTGTGG GTCACAGTC 39

(2) INFORMATION FOR SEQ ID NO:5:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 48 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(XI) SEQUENCE DESCRIPTION: SEQ ID NO:5 :

CCCCAGGAAT CCACCTGTTA GCGCTTTTCT CTCTGCACCA CTCTTCTC 48

(2) INFORMATION FOR SEQ ID NO:6:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 35 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 6:

GGTACATGAT CACAGAAAAA TTGTGGGTCA CAGTC 35

(2) INFORMATION FOR SEQ ID NO:7 :

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 47 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear (11) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:7:

CCACATTGAT CAGATATCTT ATCTTTTTTC TCTCTGCACC ACTCTTC 47

(2) INFORMATION FOR SEQ ID NO:8 :

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 8 amino acids

(B) TYPE: ammo acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ll) MOLECULE TYPE: peptide (xi) SEQUENCE DESCRIPTION: SEQ ID NO:8 : Thr Asn Trp Leu Trp Tyr lie Lys

1 5

(2) INFORMATION FOR SEQ ID NO:9 :

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 amino acids

(B) TYPE: amino acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: peptide (xi) SEQUENCE DESCRIPTION: SEQ ID NO:9 :

Lys Ala Lys Arg Arg Val Val Gin Arg Glu Lys Arg

1 5 10

(2) INFORMATION FOR SEQ ID NO: 10:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 ammo acids

(B) TYPE: amino acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: peptide (xi) SEQUENCE DESCRIPTION: SEQ ID NO:10:

Lys Ala Gin Asn His Val Val Gin Asn Glu His Gin 1 5 10

(2) INFORMATION FOR SEQ ID NO:11:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 42 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 11:

CTGAAAGACC AGCAACTCCT AGGGAATTTG GGGTTGCTCT GG 42

(2) INFORMATION FOR SEQ ID NO:12:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 58 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:12:

CGCAGGGGAG GTGGTCTAGA TATCTTATTA TTTTATATAC CACAGCCAAT TTGTTATG 58

(2) INFORMATION FOR SEQ ID NO: 13:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 30 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:13:

GGTACACCTA GGCATCTGGG GCTGCTCTGG 30 (2) INFORMATION FOR SEQ ID NO:14:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 54 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:14:

CCACATGATA TCGCCCGGGC TTATTATTTG ATGTACCACA GCCAGTTGGT GATG 54

(2) INFORMATION FOR SEQ ID NO:15:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 43 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(XI) SEQUENCE DESCRIPTION: SEQ ID NO: 15:

GGTACACTGC AGTCACCGTC CTATGGCAGG AAGAAGCGGA GAC 43

(2) INFORMATION FOR SEQ ID NO:16:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 32 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:16:

CCACATCAGG TACCCCATAA TAGACTGTGA CC 32

(2) INFORMATION FOR SEQ ID NO: 17:

(l) SEQUENCE CHARACTERISTICS: (A) LENGTH: 40 base pairs (B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(11) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 17:

GGTACATGAT CAACCATGAG AGTGAAGGAG AAATATCAGC 40

(2) INFORMATION FOR SEQ ID NO: 18:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 43 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 18:

CCACATTGAT CAGATATCCC CATCTTATAG CAAAATCCTT TCC 43

(2) INFORMATION FOR SEQ ID NO: 19:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 43 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 19:

CCACATTGAT CAGATATCCC CATCTTATAG CAAAATCCTT TCC 43

(2) INFORMATION FOR SEQ ID NO:20:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 48 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear (11) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:20:

CCTGTGTGTG AGTTTAAACT GCACTGATTT GAAGAATGAT ACTAATAC 48

(2) INFORMATION FOR SEQ ID NO:21:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 35 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: 1mear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:21:

GGTACATGAT CACAGAAAAA TTGTGGGTCA CAGTC 35

(2) INFORMATION FOR SEQ ID NO:22:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 53 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(XI) SEQUENCE DESCRIPTION: SEQ ID NO:22:

CCACATTGAT CAGCCCGGGC TTAGGGTGAA TAGCCCTGCC TCACTCTGTT CAC 53

(2) INFORMATION FOR SEQ ID NO:23:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 41 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide" (xi) SEQUENCE DESCRIPTION: SEQ ID NO-.23: CTGAAAGACC AGCAACTCCT AGGGATTTGG GGTTGCTGTG G 41

(2) INFORMATION FOR SEQ ID NO:24:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 53 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION, /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:24:

CCACATTGAT CAGCCCGGGC TTAGGGTGAA TAGCCCTGCC TCACTCTGTT CAC 53

(2) INFORMATION FOR SEQ ID NO:25:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 37 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:25-

GGTACACAAT TGGAGGAGCG AGTTATATAA ATATAAG 37

(2) INFORMATION FOR SEQ ID NO:26:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 48 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:26:

CCTGTGTGTG AGTTTAAACT GCACTGATTT GAAGAATGAT ACTAATAC 48 (2) INFORMATION FOR SEQ ID NO:27:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 6 ammo acids

(B) TYPE: ammo acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(li) MOLECULE TYPE: peptide

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:27:

Asn Arg Leu lie Lys Ala

1 5

(2) INFORMATION FOR SEQ ID NO:28:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 62 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:28:

CCACATGATA TCGCCCGGGC TTATTAGGCC TTGATCAGCC GGTTCACAAT GGACAGCACA 60

GC 62

(2) INFORMATION FOR SEQ ID NO:29:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 54 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:29:

CTGACCCCCC TGTGTGTGGG GGCTGGCAGT TGTAACACCT CAGTCATTAC ACAG 54

(2) INFORMATION FOR SEQ ID NO:30: (l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 305 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:30:

TGATCACAGA GAAGCTGTGG GTGACAGTGT ATTATGGCGT GCCAGTCTGG AAGGAGGCCA 60

CCACCACCCT GTTCTGTGCC TCTGATGCCA AGGCCTATGA CACAGAGGTG CACAATGTGT 120

GGGCCACCCA TGCCTGTGTG CCCACAGACC CCAACCCCCA GGAGGTGGTG CTGGTGAATG 180

TGACTGAGAA CTTCAACATG TGGAAGAACA ACATGGTGGA GCAGATGCAT GAGGACATCA 240

TCAGCCTGTG GGACCAGAGC CTGAAGCCCT GTGTGAAGCT GACCCCCCTG TGTGTGAGTT 300

TAAAC 305

(2) INFORMATION FOR SEQ ID NO:31:

(1) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 1065 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:31 :

AGTTTAAACT GCACAGACCT GAGGAACACC ACCAACACCA ACAACTCCAC AGCCAACAAC 60

AACTCCAACT CCGAGGGCAC CATCAAGGGG GGGGAGATGA AGAACTGCTC CTTCAACATC 120

ACCACCTCCA TCAGGGACAA GATGCAGAAG GAGTATGCCC TGCTGTACAA GCTGGACATT 180

GTGTCCATTG ACAATGACTC CACCTCCTAC AGGCTGATCT CCTGCAACAC CTCTGTCATC 240

ACCCAGGCCT GCCCCAAAAT CTCCTTTGAG CCCATCCCCA TCCACTACTG TGCCCCTGCT 300

GGCTTTGCCA TCCTGAAGTG CAATGACAAG AAGTTCTCTG GCAAGGGCTC CTGCAAGAAT 360

GTGTCCACAG TGCAGTGCAC ACATGGCATC AGGCCTGTGG TGTCCACCCA GCTGCTGCTG 420

AATGGCTCCC TGGCTGAGGA GGAGGTGGTC ATCAGGTCTG AGAACTTCAC AGACAATGCC 480

AAGACCATCA TCGTGCACCT GAATGAGTCT GTGCAGATCA ACTGCACCAG GCCCAACTAC 540 AACAAGAGGA AGAGGATCCA CATTGGCCCT GGCAGGGCCT TCTACACCAC CAAGAACATC 600

ATTGGCACCA TCAGGCAGGC CCACTGCAAC ATCTCCAGGG CCAAGTGGAA TGACACCCTG 660

AGGCAGATTG TGTCCAAGCT GAAGGAGCAG TTCAAGAACA AGACCATTGT GTTCAACCAG 720

TCCTCTGGGG GGGACCCTGA GATTGTGATG CACTCCTTCA ACTGTGGGGG GGAGTTCTTC 780

TACTGCAACA CCTCCCCCCT GTTCAACTCC ACCTGGAATG GCAACAACAC CTGGAACAAC 840

ACCACAGGCT CCAACAACAA CATCACCCTC CAGTGCAAGA TCAAGCAGAT CATCAACATG 900

TGGCAGGAGG TGGGCAAGGC CATGTATGCC CCCCCCATTG AGGGCCAGAT CAGGTGCTCC 960

TCCAACATCA CAGGCCTGCT GCTGACCAGG GATGGGGGGA AGGACACAGA CACCAACGAC 1020

ACCGAAATCT TCAGGCCTGG GGGGGGGGAC ATGAGGGACA ATTGG 1065

(2) INFORMATION FOR SEQ ID NO:32:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 354 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: DNA (genomic) (Xl) SEQUENCE DESCRIPTION: SEQ ID NO:32:

GACAATTGGA GGAGCGAGTT ATATAAATAT AAGGTGGTGA AGATTGAGCC CCTGGGGGTG 60

GCCCCAACAA AAGCTCAGAA CCACGTGGTG CAGAACGAGC ACCAGGCCGT GGGCATTGGG 120

GCCCTGTTTC TGGGCTTTCT GGGGGCTGCT GGCTCCACAA TGGGCGCCGC TAGCATGACC 180

CTCACCGTGC AAGCTCGCCA GCTGCTGAGT GGCATCGTCC AGCAGCAGAA CAACCTGCTC 240

CGCGCCATCG AAGCCCAGCA GCACCTCCTC CAGCTGACTG TGTGGGGGAT CAAACAGCTT 300

CAGGCCCGGG TGCTGGCCGT CGAGCGCTAT CTGAAAGACC AGCAACTCCT AGGC 354

(2) INFORMATION FOR SEQ ID NO:33:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 354 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear (11) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:33:

GACAATTGGA GGAGCGAGTT ATATAAATAT AAGGTGGTGA AGATTGAGCC CCTGGGGGTG 60

GCCCCAACAA AAGCTAAGAG AAGAGTGGTG CAGAGAGAGA AGAGAGCCGT GGGCATTGGG 120

GCCCTGTTTC TGGGCTTTCT GGGGGCTGCT GGCTCCACAA TGGGCGCCGC TAGCATGACC 180

CTCACCGTGC AAGCTCGCCA GCTGCTGAGT GGCATCGTCC AGCAGCAGAA CAACCTGCTC 240

CGCGCCATCG AAGCCCAGCA GCACCTCCTC CAGCTGACTG TGTGGGGGAT CAAACAGCTT 300

CAGGCCCGGG TGCTGGCCGT CGAGCGCTAT CTGAAAGACC AGCAACTCCT AGGC 354

(2) INFORMATION FOR SEQ ID NO:34:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 387 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:34:

CCTAGGCATC TGGGGCTGCT CTGGCAAGCT GATCTGCACC ACAGCTGTGC CCTGGAATGC 60

CTCCTGGTCC AACAAGAGCC TGGAGCAAAT CTGGAACAAC ATGACCTGGA TGGAGTGGGA 120

CAGAGAGATC AACAACTACA CCTCCCTGAT CCACTCCCTG ATTGAGGAGT CCCAGAACCA 180

GCAGGAGAAG AATGAGCAGG AGCTGCTGGA GCTGGACAAG TGGGCCTCCC TGTGGAACTG 240

GTTCAACATC ACCAACTGGC TGTGGTACAT CAAAATCTTC ATCATGATTG TGGGGGGCCT 300

GGTGGGGCTG CGGATTGTCT TTGCTGTGCT GTCCATTGTG AACCGGGTGA GACAGGGCTA 360

CTCCCCCTAA TAAGCCCGGG CGATATC 387

(2) INFORMATION FOR SEQ ID NO:35:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 269 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear (11) MOLECULE TYPE: DNA (genomic) (Xl) SEQUENCE DESCRIPTION: SEQ ID NO:35:

GCCCGGGCGA TATCTAGACC ACCTCCCCTG CGAGCTAAGC TGGACAGCCA ATGACGGGTA 60

AGAGAGTGAC ATTTTTCACT AACCTAAGAC AGGAGGGCCG TCAGAGCTAC TGCCTAATCC 120

AAAGACGGGT AAAAGTGATA AAAATGTATC ACTCCAACCT AAGACAGGCG CAGCTTCCGA 180

GGGATTTGTC GTCTGTTTTA TATATATTTA AAAGGGTGAC CTGTCCGGAG CCGTGCTGCC 240

CGGATGATGT CTTGGGATAT CGCCCGGGC 269

(2) INFORMATION FOR SEQ ID NO:36:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 269 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:36:

GCCCGGGCGA TATCTAGACC ACCTCCCCTG CGAGCTAAGC TGGACAGCCA ATGACGGGTA 60

AGAGAGTGAC ATTTTTCACT AACCTAAGAC AGGAGGGCCG TCAGAGCTAC TGCCTAATCC 120

AAAGACGGGT AAAAGTGATA AAAATGTATC ACTCCAACCT AAGACAGGCG CAGCTTCCGA 180

GGGATTTGTC GTCTGTTTTA TATATATTAA AAAGGGTGAC CTGTCCGGAG CCGTGCTGCC 240 CGGATGATGT CTTGGGATAT CGCCCGGGC 269

(2) INFORMATION FOR SEQ ID NO:37:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 15 amino acids

(B) TYPE: ammo acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: lineal

(ll) MOLECULE TYPE: peptide

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:37:

Arg lie His lie Gly Pro Gly Arg Ala Phe Tyr Thr Thr Lys Asn 1 5 10 15 (2) INFORMATION FOR SEQ ID NO:38:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 26 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: both

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:38:

GAAAGAGCAG AAGACAGTGG CAATGA 26

(2) INFORMATION FOR SEQ ID NO:39:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 40 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: both

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:39:

GGGCTTTGCT AAATGGGTGG CAAGTGGCCC GGGCATGTGG 40

(2) INFORMATION FOR SEQ ID NO:40:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 16 amino acids

(B) TYPE: amino acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: peptide

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:40:

Lys Gin He He Asn Met Trp Gin Glu Val Gly Lys Ala Met Tyr Ala 1 5 10 15

(2) INFORMATION FOR SEQ ID NO:41:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 13 amino acids (B) TYPE: amino acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: peptide

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:41:

His Glu Asp He He Ser Leu Trp Asp Gin Ser Leu Lys 1 5 10

(2) INFORMATION FOR SEQ ID NO:42:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 15 amino acids

(B) TYPE: amino acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: peptide

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:42:

Asp Arg Val He Glu Val Val Gin Gly Ala Tyr Arg Ala He Arg 1 5 10 15

(2) INFORMATION FOR SEQ ID NO:43:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 3547 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: double

(D) TOPOLOGY: both

(ii) MOLECULE TYPE: cDNA

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 43:

GATATTGGCT ATTGGCCATT GCATACGTTG TATCCATATC ATAATATGTA CATTTATATT 60

GGCTCATGTC CAACATTACC GCCATGTTGA CATTGATTAT TGACTAGTTA TTAATAGTAA 120

TCAATTACGG GGTCATTAGT TCATAGCCCA TATATGGAGT TCCGCGTTAC ATAACTTACG 180

GTAAATGGCC CGCCTGGCTG ACCGCCCAAC GACCCCCGCC CATTGACGTC AATAATGACG 240

TATGTTCCCA TAGTAACGCC AATAGGGACT TTCCATTGAC GTCAATGGGT GGAGTATTTA 300

CGGTAAACTG CCCACTTGGC AGTACATCAA GTGTATCATA TGCCAAGTAC GCCCCCTATT 360

GACGTCAATG ACGGTAAATG GCCCGCCTGG CATTATGCCC AGTACATGAC CTTATGGGAC 420

TTTCCTACTT GGCAGTACAT CTACGTATTA GTCATCGCTA TTACCATGGT GATGCGGTTT 480 TGGCAGTACA TCAATGGGCG TGGATAGCGG TTTGACTCAC GGGGATTTCC AAGTCTCCAC 540

CCCATTGACG TCAATGGGAG TTTGTTTTGG CACCAAAATC AACGGGACTT TCCAAAATGT 600

CGTAACAACT CCGCCCCATT GACGCAAATG GGCGGTAGGC GTGTACGGTG GGAGGTCTAT 660

ATAAGCAGAG CTCGTTTAGT GAACCGTCAG ATCGCCTGGA GACGCCATCC ACGCTGTTTT 720

GACCTCCATA GAAGACACCG GGACCGATCC AGCCTCCGCG GCCGGGAACG GTGCATTGGA 780

ACGCGGATTC CCCGTGCCAA GAGTGACGTA AGTACCGCCT ATAGAGTCTA TAGGCCCACC 840

CCCTTGGCTT CTTATGCATG CTATACTGTT TTTGGCTTGG GGTCTATACA CCCCCGCTTC 900

CTCATGTTAT AGGTGATGGT ATAGCTTAGC CTATAGGTGT GGGTTATTGA CCATTATTGA 960

CCACTCCCCT ATTGGTGACG ATACTTTCCA TTACTAATCC ATAACATGGC TCTTTGCCAC 1020

AACTCTCTTT ATTGGCTATA TGCCAATACA CTGTCCTTCA GAGACTGACA CGGACTCTGT 1080

ATTTTTACAG GATGGGGTCT CATTTATTAT TTACAAATTC ACATATACAA CACCACCGTC 1140

CCCAGTGCCC GCAGTTTTTA TTAAACATAA CGTGGGATCT CCACGCGAAT CTCGGGTACG 1200

TGTTCCGGAC ATGGGCTCTT CTCCGGTAGC GGCGGAGCTT CTACATCCGA GCCCTGCTCC 1260

CATGCCTCCA GCGACTCATG GTCGCTCGGC AGCTCCTTGC TCCTAACAGT GGAGGCCAGA 1320

CTTAGGCACA GCACGATGCC CACCACCACC AGTGTGCCGC ACAAGGCCGT GGCGGTAGGG 1380

TATGTGTCTG AAAATGAGCT CGGGGAGCGG GCTTGCACCG CTGACGCATT TGGAAGACTT 1440

AAGGCAGCGG CAGAAGAAGA TGCAGGCAGC TGAGTTGTTG TGTTCTGATA AGAGTCAGAG 1500

GTAACTCCCG TTGCGGTGCT GTTAACGGTG GAGGGCAGTG TAGTCTGAGC AGTACTCGTT 1560

GCTGCCGCGC GCGCCACCAG ACATAATAGC TGACAGACTA ACAGACTGTT CCTTTCCATG 1620

GGTCTTTTCT GCAGTCACCG TCCTTAGATC TGCTGTGCCT TCTAGTTGCC AGCCATCTGT 1680

TGTTTGCCCC TCCCCCGTGC CTTCCTTGAC CCTGGAAGGT GCCACTCCCA CTGTCCTTTC 1740

CTAATAAAAT GAGGAAATTG CATCGCATTG TCTGAGTAGG TGTCATTCTA TTCTGGGGGG 1800

TGGGGTGGGG CAGCACAGCA AGGGGGAGGA TTGGGAAGAC AATAGCAGGC ATGCTGGGGA 1860

TGCGGTGGGC TCTATGGGTA CGGCCGCAGC GGCCGTACCC AGGTGCTGAA GAATTGACCC 1920

SUBSTITUTE SHEET (RULE 25) GGTTCCTCGA CCCGTAAAAA GGCCGCGTTG CTGGCGTTTT TCCATAGGCT CCGCCCCCCT 1980

GACGAGCATC ACAAAAATCG ACGCTCAAGT CAGAGGTGGC GAAACCCGAC AGGACTATAA 2040

AGATACCAGG CGTTTCCCCC TGGAAGCTCC CTCGTGCGCT CTCCTGTTCC GACCCTGCCG 2100

CTTACCGGAT ACCTGTCCGC CTTTCTCCCT TCGGGAAGCG TGGCGCTTTC TCAATGCTCA 2160

CGCTGTAGGT ATCTCAGTTC GGTGTAGGTC GTTCGCTCCA AGCTGGGCTG TGTGCACGAA 2220

CCCCCCGTTC AGCCCGACCG CTGCGCCTTA TCCGGTAACT ATCGTCTTGA GTCCAACCCG 2280

GTAAGACACG ACTTATCGCC ACTGGCAGCA GCCACTGGTA ACAGGATTAG CAGAGCGAGG 2340

TATGTAGGCG GTGCTACAGA GTTCTTGAAG TGGTGGCCTA ACTACGGCTA CACTAGAAGG 2400

ACAGTATTTG GTATCTGCGC TCTGCTGAAG CCAGTTACCT TCGGAAAAAG AGTTGGTAGC 2460

TCTTGATCCG GCAAACAAAC CACCGCTGGT AGCGGTGGTT TTTTTGTTTG CAAGCAGCAG 2520

ATTACGCGCA GAAAAAAAGG ATCTCAAGAA GATCCTTTGA TCTTTTCTAC GTGATCCCGT 2580

AATGCTCTGC CAGTGTTACA ACCAATTAAC CAATTCTGAT TAGAAAAACT CATCGAGCAT 2640

CAAATGAAAC TGCAATTTAT TCATATCAGG ATTATCAATA CCATATTTTT GAAAAAGCCG 2700

TTTCTGTAAT GAAGGAGAAA ACTCACCGAG GCAGTTCCAT AGGATGGCAA GATCCTGGTA 2760

TCGGTCTGCG ATTCCGACTC GTCCAACATC AATACAACCT ATTAATTTCC CCTCGTCAAA 2820

AATAAGGTTA TCAAGTGAGA AATCACCATG AGTGACGACT GAATCCGGTG AGAATGGCAA 2880

AAGCTTATGC ATTTCTTTCC AGACTTGTTC AACAGGCCAG CCATTACGCT CGTCATCAAA 2940

ATCACTCGCA TCAACCAAAC CGTTATTCAT TCGTGATTGC GCCTGAGCGA GACGAAATAC 3000

GCGATCGCTG TTAAAAGGAC AATTACAAAC AGGAATCGAA TGCAACCGGC GCAGGAACAC 3060

TGCCAGCGCA TCAACAATAT TTTCACCTGA ATCAGGATAT TCTTCTAATA CCTGGAATGC 3120

TGTTTTCCCG GGGATCGCAG TGGTGAGTAA CCATGCATCA TCAGGAGTAC GGATAAAATG 3180

CTTGATGGTC GGAAGAGGCA TAAATTCCGT CAGCCAGTTT AGTCTGACCA TCTCATCTGT 3240

AACATCATTG GCAACGCTAC CTTTGCCATG TTTCAGAAAC AACTCTGGCG CATCGGGCTT 3300

CCCATACAAT CGATAGATTG TCGCACCTGA TTGCCCGACA TTATCGCGAG CCCATTTATA 3360

CCCATATAAA TCAGCATCCA TGTTGGAATT TAATCGCGGC CTCGAGCAAG ACGTTTCCCG 3420 TTGAATATGG CTCATAACAC CCCTTGTATT ACTGTTTATG TAAGCAGACA GTTTTATTGT 3480 TCATGATGAT ATATTTTTAT CTTGTGCAAT GTAACATCAG AGATTTTGAG ACACAACGTG 3540 GCTTTCC 3547

(2) INFORMATION FOR SEQ ID NO:44:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 33 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "olignucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:44:

GGTACAAATA TTGGCTATTG GCCATTGCAT ACG 33

(2) INFORMATION FOR SEQ ID NO:45:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 36 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:45:

CCACATCTCG AGGAACCGGG TCAATCCTCC AGCACC 36

(2) INFORMATION FOR SEQ ID NO:46:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 38 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc == "oligonucleotide" (xi) SEQUENCE DESCRIPTION: SEQ ID NO:46:

GGTACAGATA TCGGAAAGCC ACGTTGTGTC TCAAAATC 38

(2) INFORMATION FOR SEQ ID NO:47:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 37 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(li) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:47:

CCACATGGAT CCGTAATGCT CTGCCAGTGT TACAACC 37

(2) INFORMATION FOR SEQ ID NO:48:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 39 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(π) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:48:

GGTACATGAT CACGTAGAAA AGATCAAAGG ATCTTCTTG 39

(2) INFORMATION FOR SEQ ID NO:49:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 35 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: othei nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:49:

CCACATGTCG ACCCGTAAAA AGGCCGCGTT GCTGG 35 (2) INFORMATION FOR SEQ ID NO:50:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 18 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 50:

GAGCCAATAT AAATGTAC 18

(2) INFORMATION FOR SEQ ID NO:51:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 15 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(n) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:51:

CAATAGCAGG CATGC 15

(2) INFORMATION FOR SEQ ID NO:52:

(l) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 16 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: other nucleic acid

(A) DESCRIPTION: /desc = "oligonucleotide"

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:52:

GCAAGCAGCA GATTAC 16 (2) INFORMATION FOR SEQ ID NO:53:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 6 amino acids

(B) TYPE: amino acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: peptide

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:53

Glu Leu Asp Lys Trp Ala 1 5

Claims

WHAT IS CLAIMED IS:

1. A synthetic polynucleotide comprising a DNA sequence encoding a peptide or protein, the DNA sequence comprising codons optimized for expression in a nonhomologous host.

2. The synthetic polynucleotide of Claim 1 wherein the protein is an HIV protein.

3. The synthetic polynucleotide of Claim 1 wherein the

DNA sequence encodes HIV env protein or a fragment thereof, the DNA sequence comprising codons optimized for expression in a mammalian host.

4. The polynucleotide of Claim 3 which is selected from:

VUns-tPA-HIVMN gpl20;

VUns-tPA-HIVπiB gpl20;

V 1 Jns-tPA-gp 140/mutRRE- A/SR V- 1 3'-UTR; VUns-tPA-gpl40/mutRRE-B/SRV-l 3'-UTR;

V 1 Jns-tPA-gp 140/opt30- A;

V 1 Jns-tPA-gp 140/opt30-B ;

VI Jns-tPA-gp 140/opt all-A;

VUns-tPA-gpl40/opt all-B; V 1 Jns-tPA-gp 140/opt all-A;

VI Jns-tPA-gp 140/opt all-B;

VlJns-rev/env:;

VUns-gpl60;

VUns-tPA-gpl60; VI Jns-tPA-gp 160/opt Cl/opt41-A;

VlJns-tPA-gpl60/opt Cl/opt41-B;

VI Jns-tPA-gp 160/opt all-A;

VI Jns-tPA-gp 160/opt all-B;

VI Jns-tPA-gp 160/opt all-A; VI Jns-tPA-gp 160/opt all-B;

VUns-tPA-gpl43;

V 1 Jns-tPA-gp 143/mutRRE-A;

V 1 Jns-tPA-gp 143/mutRRE-B ; VI Jns-tPA-gp 143/opt32-A;

VUns-tPA-gpl43/opt32-B;

VUns-tPA-gpl43/SRV-l 3'-UTR;

VUns-tPA-gpl43/opt Cl/opt32A;

VI Jns-tPA-gp 143/opt Cl/opt32B; VI Jns-tPA-gp 143/opt all-A

VUns-tPA-gpl43/opt all-B

VI Jns-tPA-gp 143/opt all-A

VUns-tPA-gpl43/opt all-B

VI Jns-tPA-gp 143/opt32-A/glyB; VUns-tPA-gpl43/opt32-B/glyB;

VlJns-tPA-gpl43/opt Cl/opt32-A/glyB;

V 1 Jns-tPA-gp 143/opt C 1 /opt32-B/glyB ;

VI Jns-tPA-gp 143/opt all-A/glyB

VI Jns-tPA-gp 143/opt all-B/glyB VI Jns-tPA-gp 143/opt all-A/glyB

VI Jns-tPA-gp 143/opt all-B/glyB and combinations thereof.

5. The polynucleotide of Claim 2 which induces anti- HIV neutralizing antibody, HIV specific T-cell immune responses, or protective immune responses upon introduction into vertebrate tissue, including human tissue in vivo, wherein said polynucleotide comprises a gene encoding an HIV gag , HIV protease and combinations thereof.

6. A method for inducing immune responses in a vertebrate against HIV epitopes which comprises introducing between 1 ng and 100 mg of the polynucleotide of Claim 2 into the tissue of the vertebrate.

7. A method for using a rev independent HIV gene to induce immune responses in vivo which comprises: a) synthesizing the rev independent HIV gene; b) linking the synthesized gene to regulatory sequences such that the gene is expressible by virtue of being operatively linked to control sequences which, when introduced into a living tissue, direct the transcription initiation and subsequent translation of the gene;

8. A method for inducing immune responses against infection or disease caused by virulent strains of HIV which comprises introducing into the tissue of a vertebrate the polynucleotide of Claim 2.

9. A vaccine for inducing immune responses against HIV infection which comprises the polynucleotide of Claim 2 and a pharmaceutically acceptable carrier.

10. A method for inducing anti-HIV immune responses in a primate which comprises introducing the polynucleotide of Claim 2 into the tissue of the primate and concurrently administering interleukin 12, GM-CSF, or combinations thereof parenterally.

11. A method of inducing an antigen presenting cell to stimulate cytotoxic and helper T-cell proliferation an effector functions including lymphokine secretion specific to HIV antigens which comprises exposing cells of a vertebrate in vivo to the polynucleotide of Claim 2.

12. A method of increasing rev independent in vivo expression of DNA encoding HIV env or a fragment thereof, comprising:

(a) identifying placement of codons for proper open reading frame;

- 99 -

SUBSIITUIE SHEET (RULE 26) (b) comparing wild type codons for observed frequency of use by human genes;

(c) replacing wild-type codons with codons optimized for high expression of human genes; and (d) testing for improved expression.

13. A vaccine for inducing immune responses against HIV infection which comprises the polynucleotide of Claim 2 wherein the polynucleotide is delivered by a canarypox, vaccinia virus, adenovirus, adeno-associated virus, retrovirus, Listeria, Shigella, specific ligand, BCG, or salmonella.

14. A method of inducing an immune response to HIV which comprises administration of the polynucleotide of Claim 2 and administration of an attenuated HIV, a killed HIV, an HIV protein, a fragment of an HIV protein, or combinations thereof, wherein the administration of the polynucleotide is prior to or simultaneous with or subsequent to the administration of the attenuated HIV, the killed HIV, the HIV protein, the fragment of the HIV protein or the combinations thereof.

15. A method of inducing an immune response to HIV which comprises administration of the polynucleotide of Claim 2 with an adjuvant.

16. A method of treating HIV infection which comprises administration of the polynucleotide of Claim 2 to a patient and administration of an anti-HIV compound to the patient, wherein the administration of the polynucleotide is prior to or simultaneous with or subsequent to the administration of the anti-HIV compound.

17. A method of increasing expression of a gene in a nonhomologous host, comprising:

- 100 -

SUBSπTUIE SHEET (RULE 26) a) comparing codons of a wild type gene to codons preferred by the nonhomologous host; b) replacing codons of the wild type gene with new codons, the new codons having a DNA sequence preferred by the nonhomologous host: c) inspecting third nucleotides of the new codons and first nucleotides of adjacent new codon immediately 3'- of the first, and if a 5'-CG-3' pairing has been created by the new codon selection, replacing it; d) eliminating undesired sequences to yield a synthetic optimized gene; and e) inserting the synthetic gene into the nonhomologous host.

18. A method of expressing a peptide in a host comprising administration of the synthetic polynucleotide of Claim 1 to the host.

19. A method of increasing production of a recombinant protein by a host, comprising: a) transforming a host cell with the synthetic polynucleotide of Claim 1 to produce a transformed host; and b) cultivating the transformed host under conditions that permit expression of the synthetic polynucleotide and production of the recombinant protein.