EP1198579A1 - Non-human adenoviral vector for gene transfer, its use and the production thereof - Google Patents

Abstract

The invention relates to the production of a non-human adenoviral vector for gene transfer into mammal cells. This vector is especially suited for the gene transfer into muscle, in particular, into the skeletal muscle, or into cell types found in the muscle or skeletal muscle. Areas of application include the fields of medicine, biotechnology and genetic engineering. When functional DNA sequences are inserted, the vector is suited for treating modified as well as pathological symptoms in cells or cell complexes, for producing biological materials and for vaccinating.

Description

 NON-HUMAN ADENOVIRAL VECTOR FOR GENE TRANSFER, ITS APPLICATION AND PRODUCTION

description

The invention relates to the production of a non-human adenoviral vector for gene transfer in mammalian cells. This vector is particularly suitable for gene transfer into the muscle, in particular into the skeletal muscle, or into cell types that occur in the muscle or skeletal muscle. Areas of application are medicine, biotechnology and genetic engineering. When functional DNA sequences are inserted, the vector is suitable for the treatment of altered, also pathological phenomena in cells or cell complexes, for the production of biological material and for vaccination.

In recent years, numerous methods and vectors for gene transfer with the aim of gene therapy or vaccination have been developed (review by: Verma, M.l. And Somia, N. (1 997). Nature 389, 239-242). In particular, vectors derived from retroviruses, adeno-associated viruses (AAV) or human adenoviruses are used for gene transfer e.g. favored with the goal of gene therapy. These vector types have a broad spectrum of efficiently infectable cell types and are therefore suitable for gene transfer into different tissues.

The adenoviral vectors of the so-called first generation have been intensively researched as gene transfer vectors over the past decade (review by: Bramson, JL et al. (1 995). Curr. Op. Biotech. 6, 590-595). They are derived from the human adenovirus of serotype 5 and are, in the essential E1 region, often also deleted in the non-essential E3 region, whereby up to 8 KBp of foreign DNA can be inserted into the virus genome. These vectors can complement E1 deficiency Cells with high titers can be stored well and mediate an effective gene transfer in vitro and in vivo. In vivo, however, there is a rapid loss of expression of the transgenes and of the vector genome. In addition, massive tissue toxicity was sometimes observed after application of high vector doses. For example, administration of first generation human adenovirus vectors into the skeletal muscle of mice leads to leukocyte infiltration of the infected tissue and activation of a T cell subclass (Vilquin et al., Hum. Gene Ther. 6 (1 995), 1 391 -1401; Yang et al., Hum. Mol. Genet. 5 (1 996), 1 703-1 71 2). Both are caused at least in part by immunological reactions to the viral genes remaining in the vector. An attempt was therefore made to outsource, above all, other early viral genes, but a decisive improvement in in vivo gene transfer could not be achieved.

Recently developed, completely recombinant human adenovirus vectors (Kochanek, S. et al. (1 996). Proc. Natl. Acad. Sci. USA 93; 5731 - 5736) showed an effective gene transfer with reduced toxicity and a prolonged transgene expression in animal models (Morral, N. et al. (1,998), Hum. Gen. Ther. 9: 2709-271 6). However, since these vectors also have the normal envelope of the human adenovirus and, in the vector genome, the cis elements necessary for replication and packaging - the inverted terminal repeats (ITRs) and the packaging signal - two limitations remain with these vectors, which are the main problems human adenovirus vectors can apply. Both are due to the human origin of the adenovirus vectors used and the widespread use of these viruses in the human population: (1) The mostly existing immunity to human adenoviruses leads to extensive neutralization and opsonization of the vector. Current studies in animal models have shown that efficient gene transfer in the presence of this immunity is only possible by using high vector doses (Nunes, FA et al. (1 999), Hum. Gen. Ther. 10, 251 5-2526), However, this can lead to strong toxic side effects, including serious haematological side effects (Cichon, G. et al. (1 999), J. Gene Med. 1, 360-371). (2) In addition, there is a risk of the recombinant vector being replicated in the event of a natural infection with a wild-type adenovirus with unpredictable consequences. Human adenovirus vectors currently described can therefore only be considered to a limited extent for use in gene therapy in humans. An approach to overcoming the problem of immunity against human adenoviruses has recently been found by developing adenoviral vectors of non-human origin. The viral genome is largely unchanged in these vectors; as a rule, smaller regions which are not essential for virus propagation have been replaced by a transgene (WO 97/06826; Mittal, SK et al. (1 995), J.Gen. Virol. 76, 93-1 02; Klonjkowski, B. et al. (1 997), Hum. Gen. Ther. 8: 21 03-21 1 5; Michou, I. Et al. (1 999). J. Virol. 72, 1 399-1410). However, efficient gene transfer with non-human adenoviral vectors in vivo has not yet been demonstrated experimentally.

The problems which arise with previously known adenoviral vectors can be solved by using a non-human adenoviral vector which can transfer DNA sequences into target cells, in particular mammalian cells, and where there results a preferably transient expression of the transduced gene in the cell or in the organism , In particular, the non-human adenoviral vector is suitable for efficient gene transfer in vivo, e.g. for transduction of mammalian cell types, which in

Muscle occur, or in the skeletal muscles. primary

The field of application is the transfer of genetic material into cells, for example with the goals: therapy of genetically determined and acquired

Diseases, production of recombinant proteins and vaccination of animals and humans. An object of the invention is thus the use of a non-human adenovirus vector for the production of an agent for the transfer of genetic material, comprising the envelope of a non-human adenovirus and genetic material packaged therein, which (a) DNA sequences from a non-human adenovirus and

(b) contains one or more DNA sequences which code for peptides or polypeptides which are heterologous to the non-human adenovirus, in operative linkage with expression control sequences.

The genetic material of the gene transfer vector according to the invention contains DNA sequences from a non-human adenovirus, i.e. an adenovirus naturally occurring in a non-human species selected, for example, from mammals and birds, as listed in Russell, W.C. and Benkö, M. (1 999), Adenoviruses (Adenoviridae): Animal viruses. In: Granoff, A. and Webster, R.G. (Eds): Encyclopedia of Virology. Academic Press, London, especially adenoviruses from monkeys (SAV, various serotypes), goats (caprine, various serotypes), dogs (CAV, various serotypes), pigs (PAV, various serotypes), cattle (BAV, various serotypes), Sheep (OAV1 -6 and OAV287) and chickens (FAV, various serotypes) and EDS virus. The virus is preferably a sheep or bovine adenovirus. Examples of suitable sheep adenoviruses are ovine mastadenoviruses or ovine atadenoviruses such as OAV isolate 287, whose nucleotide sequence is given under Genbank Acc. No. U40389. Suitable bovine adenoviruses are bovine atadenoviruses or bovine mastadenoviruses, negative bovine and ovine atadenoviruses being particularly interesting in the complement fixation assay.

Furthermore, the gene transfer vector according to the invention contains one or more DNA sequences which code for peptides or polypeptides which are heterologous with respect to the non-human adenovirus, in operative linkage with

Expression control sequences, ie an expression cassette for one or several transgenes. The expression cassette for the transgene can, for example, be inserted into a cloning site.

The transgene expression cassette preferably contains expression control sequences which allow expression in mammalian cells, for example in human cells. The expression control sequences can be constitutively active and / or regulatable in the desired target cell. The expression control sequences can be of viral or cellular origin or comprise a combination of viral and cellular elements. Examples of suitable promoters are viral promoters, e.g. RSV promoter, CMV immediate early promoter / enhancer, SV40 promoter, or tissue-specific, especially liver-specific promoters, e.g. the human albumin promoter (Ponder et al., Hum. Gene Ther. 2 (1991), 41-52), the human σ-1-antitrypsin promoter / enhancer (Shen et al., DNA 8 (1989), 101-108 ), the PEPCK promoter (Ponder et al., Hum. Gene Ther. 2 (1991), 41-52) or HBV-derived hybrid promoters, e.g. EilmCMV promoter (Loser et al., Biol. Chem. Hoppe-Seyler 377 (1996), 187-193). Furthermore, the expression regulation sequences conveniently comprise a polyadenylation signal, for example that of bovine growth hormone gene (Goodwin & Rottman, J. Biol. Chem. 267 (1992); 16330-16334), which is the SV40 early transcription unit (van den Hoff et al., Nucleic Acids Res. 21 (1993), 4987-4988) or that of the herpes simplex thymidine kinase gene (Schmidt et al., Mol. Cell. Biol. 10, (1990), 4406-4411.

The viral gene transfer vector can be used to transfer heterologous nucleic acids into permissive cells, cell groups, organs and organisms, in particular for gene therapy or for vaccination. For the purpose of gene therapy, the genomic sequence or the cDNA of a gene can be used, the product of which is missing in the patient to be treated, occurs in unphysiological amounts or / and is defective. You can also use part of a genomic sequence that a mutation in Target gene spanned and can be homologously recombined with this. To achieve the goal of tumor therapy, various genes can be used, which slow down the growth or kill the tumor cells, possibly in combination with pharmaceuticals or by immunostimulation. One or more, possibly modified genes of a pathogenic organism against which immunization is to be achieved can be used for the purpose of vaccination.

Furthermore, the gene transfer vector according to the invention can contain genetic material from other viruses, for example expressed or regulatory sequences of hepatitis B and hepatitis C virus (HBV, HCV), and of bacteria and pathogenic single or multi-cells, for example Plasmodium faiciparum.

Preferred specific examples of transgenes for the purpose of substitution gene therapy are genes for secreted serum factors (for example human blood coagulation factors IX (FIX) and VIII (FVIII), erythropoietin (Epo) σ-1 - antitrypsin (AAT)), and genes for proteins which could be used in muscle diseases (e.g. dystrophin, utrophin), and the gene defective in Wilson's disease (ATP7B). For the goal of tumor therapy, preferred specific transgenes are tumor suppressor genes such as p 1 6 or p53 (individually or in combination, e.g. P1 6 / p53), genes for various interleukins (individually or in combination, e.g. IL2 / IL7) and suicide genes, e.g. Herpes simplex virus type I thymidine kinase (HSV-TK).

The vector is suitable for gene transfer in cells or cell complexes which have changed, also pathological phenomena, for example for gene therapy, for example for the therapy of inherited or malignant diseases. The vector is also suitable for vaccination, for example for vaccination against pathogens, in particular viruses, bacteria and eukaryotic single or multi-cells, or for vaccination against malignant or non-malignant cells or cell populations. Surprisingly, efficient expression of the transgene can be achieved even after multiple administration of the vector. This leads to considerable advantages, especially for applications in the field of gene therapy and vaccination. Another advantage is the - compared to human adenovirus vectors - observed reduced expression of vector-inherent genes of the vector after the gene transfer into the target cell, preferably essentially no expression of vector-inherent genes after the gene transfer. This leads to a significantly increased safety for use in the organism, especially in humans.

An important area of application is the use of the gene transfer vector to obtain proteins by overexpression in cultured cells. Due to the very efficient expression of the genes transduced by the vector in cell cultures, e.g. in IMR-90 and human liver-derived cells, an innovative basis for the production of recombinant proteins on an industrial scale is made possible, which can compete with the previously mainly used production in CHO cells.

The vector according to the invention can be used to transfer genetic material into a target cell and preferably to express this genetic material in the target cell and preferably to express this genetic material in the target cell. The target cell is preferably a human cell. However, non-human target cells, in particular non-human mammalian cells, can also be used, for example, for veterinary or research applications. The gene transfer can take place in vitro, ie in cultured cells, but also in vivo, ie in living organisms or specific tissues or organs of such organisms. The vector according to the invention is particularly preferably used for gene transfer into muscle, in particular into the skeletal muscle. This finding is all the more surprising since previously used human adenoviral vectors only poorly infected the skeletal muscle. The muscle cells are preferably selected from myocytes / myotubes / myofibers, fibroblasts, dendritic cells, endothelial cells and combinations thereof.

The preferred mode of administration of the vector depends on the intended application. For muscle-directed gene transfer or transfer to a solid tumor, for example, local application of the vector by intramuscular / intratumoral injection is preferable. A systemic introduction, for example by intra-arterial or intravenous injection, can take place for gene transfer to other target organs or tissues. In the latter case, the directed transfer into special tissues or organs can take place either by a natural or modified tropism of the vector for certain cell types or by selecting vessels which supply the tissue to be found.

The dosage can only be decided after more detailed studies on the efficiency of gene transfer by the respective vector. Animal studies typically use 1 0 ⁷ to 1 0 ¹³ , eg 1 0 ⁹ to 10 ^{1 1} viral particles / kg body weight. However, the exact dosage can be modified depending on the type of vector, the type and severity of the disease and the type of administration.

In the event that several doses of the vector are to be administered at intervals, a relatively low dose of the vector, for example 1 0 ⁷ to 1 0 ⁹ viral particles per kilogram of body weight, is preferably used in the first doses in order to prevent an immune response from developing prevent the vector that could render the administration of subsequent doses ineffective. Surprisingly, it was found that even with the Ver v er i g eri n ge r vector d o sations an efficient transgene expression is found.

The production of non-human gene transfer adenovirus vectors can be carried out by inserting transgene expression cassettes and, if appropriate, further genetic elements into a base vector, e.g. B. a natural non-human adenovirus or a variant derived therefrom, e.g. B. a partially deleted variant and propagation of the resulting vector in suitable permissive cells.

The invention is further illustrated by the following figures and examples. Show it:

Figure 1: Efficient expression of human oyAntitrypsin (hAAT) after injection of OAVhaat into the quadriceps muscle. 5 animals each from two mouse strains (Balb / C and C57 / BI-6) were injected with a total of approx. 1 x 10 ⁹ infectious particles OAVhaat in a volume of 1 50 μ \ (75 μ \ per hind leg). Blood was drawn three days after infection and the concentration of hAAT in the serum was determined by ELISA. Each pillar represents an individual animal.

Figure 2: The skeletal muscle is the site of OAV infection and the site of OAV-mediated gene expression after intramuscular injection of OAVhaat in mice. Balb / C mice were injected with 1x10 ⁹ infectious particles OAVhaat (2 and 3) or with buffer (1) as described in Figure 1 and killed three days after application. DNA and RNA were prepared from the injected skeletal muscle as well as from liver and spleen according to standard methods, a) Southern blotting of 20 μg DNA from skeletal muscle, liver and spleen digested with EcoRI. The hybridization was carried out against an OAV-specific probe, the position of the 2399 bp EcoRI fragment from the OAV vector is indicated. OAV DNA digested with EcoRI, equivalent to 5 copies per cell, was identified as Positive control used. Identical numbers denote identical animals, b) RNase protection assay with 20 μg total RNA from skeletal muscle. The hybridization was carried out against a 364 base long probe that spanned the EcoNI fragment of the human aat gene. 20 and 40 pg of a haat mRNA synthesized in vitro were used as a positive control; the position of the band specific to the haat transcript is indicated by the arrow.

Figure 3: Dose-response relationship of OAV-dependent expression and the possibility of intramuscular readministration of OAV vectors in mice. C57 / BI-6 mice received the specified amounts of infectious particles of OAVhaat (10 ⁹ to 3x1 0 ⁷ ) in an intramuscular injection. The expression of the haat gene was determined by measuring the concentration of σ antitrypsin in the serum of the mice three days after infection using an ELISA (dark columns). The second injection took place on day 35 after the first application of the vector, all animals received a dose of 5x10 ⁸ infectious particles. Serum hAAT was determined three days after the second vector administration (light gray columns).

Examples:

1 . Material and methods 1. 1 cells and viruses

HEK-293 cells (human embryonic kidney cells ATCC CRL-1 573), permissive for E1-deleted human adenoviruses were cultivated in DMEM (Gibco BRL) supplemented with 2 mM glutamine and 10% fetal calf serum at 5% CO ₂ . CSL 503 cells (fetal ovine lung cells, permissive for OAV, Pye et al, Austr. Vet. J. 66 (1 998), 231-232) were cultivated under the same conditions but in 1 5% fetal calf serum.

OAVhAAT was used as the viral vector, which encodes the human σ1-antitrypsin (hAAT) cDNA under transcriptional control of the Rous Sarcoma virus 3'LTR contains (Hofmann et al., J. Virol 73 (1 999), 6930-6936). Adδhaat, an E1-deleted human Ad5 adenovirus vector, which contains the identical haat expression cassette as OAVhaat was used as a control. The viruses were cultivated in permissive cell lines and purified as previously described (Sandig et al., Gene Therapy 3 (1 996), 1 002 - 1 009). Virus titers were determined by an endpoint dilution assay with permissive cell lines. Typical titers for OAV and Ad5 vectors were 0.5 - 1 x ¹⁰ 0 and 0.5 - 1 x 1 0 ^{1 1} infectious particles per ml. The ratio of particles to infectious particles for recombinant Ad5 and OAV Vectors was 40: 1.

1.2 laboratory animals

Eight week old female Balb / C and C57 / BI-6 mice were purchased from Charles River, Germany. The mice were given intramuscular injections into the quadriceps muscle with a maximum volume of 35 μ per injection. Blood was obtained from the outer tail vein to determine the serum αi-antitrypsin level. HAAT was determined by ELISA as described in Cichon and Strauss (Gene Therapy 5 (1 998) 85-90).

The titer of neutralizing antibodies against viral vectors was determined based on the ability of serum to inhibit infection of 293 cells by human Ad vectors and of CSL503 cells by OAV vectors as described in Hoffmann et al. (1 999), supra. The antibody titer against hAAT in serum was determined by the method of Morral et al. (Hum Gene Ther 8 (1 997), 1 275 - 1 286).

1.3 Analysis of DNA and RNA

DNA and total RNA from mouse tissues and cultured cells was isolated using standard methods. Southern blots for Detection of OAV-specific DNA in mouse organs was carried out as previously described (Hoffmann et al. (1 999), supra) using 20 μg genomic DNA. RNase protection tests were performed on 20 g of total skeletal muscle RNA using standard procedures. A radiolabeled 362 bp RNA fragment comprising the EcoN 1 fragment of human hAAT cDNA was used as a probe.

RT-PCR was performed with 2 μg total RNA from skeletal muscle using the Titan ™ kit (Röche Diagnostics Mannheim, Germany) according to the manufacturer's instructions.

2 results

2.1 High expression of serum proteins after injection of a vector derived from OA V into the skeletal muscle of mice

Injection of approx. 1 0 ⁹ infectious particles of the vector OAVhaat in the M. quadriceps of Balb / C-resp. C57 / BI-6 mice produced concentrations of the transgene (hAAT) in mouse serum that were between 2.6 and 5.9 μg / ml (Balb / C) and 9.8 and 20.0 vg / ml (C57 / BI- 6) were.

In order to prove that the muscle is actually the site of both the infection by the vector and the expression of the hAAT cDNA, the presence for the vector of specific DNA by means of Southern blotting (Figure 2a) and for the hAAT transcript of specific RNA by means of RNase Protection assay (Figure 2b). As can be seen in Figure 2a, OAV-specific DNA was detectable in the skeletal muscle, but not in the liver and spleen, the organs that would be the primary target of infection if the vector were flushed out into the circulation. It can therefore be assumed that no major proportion of the administered vector has entered the system after intramuscular injection. Figure 2b clearly shows that high in the skeletal muscle Concentrations for the transgene product hAAT-specific RNA have to be detected, which shows the skeletal muscle as the site of the hAAT gene expression after intramuscular vector administration.

The high efficiency of muscle-specific gene transfer with OAV-derived vectors can be seen in Figure 3. The injection of decreasing doses of OAVhAAT into the skeletal muscle (1 0 ⁹ to 3x1 0 ⁷ infectious particles per injection) showed decreasing hAAT concentrations in the serum of the corresponding mice, however, the lowest dose (3 x 10 ⁷ infectious particles) was still a hAAT concentration of more than 100 ng / ml is reached. This is a concentration that is above the therapeutic concentrations necessary for most therapeutic serum proteins (eg coagulation factors). At low doses, repeated intramuscular injection of the same vector was also possible, which resulted in moderate serum concentrations of hAAT (250 - 2300 ng / ml, dark bars in the figure) after a second administration of 5 x 10 ⁸ infectious particles 35 days after the first administration 3). The cause of this phenomenon is obviously the induction of a minimal immune response against the vector, especially when using a small vector dose.

2.2 Induction of a humoral immune response against the transgene product after injection of an OA V-derived vector into the skeletal muscle of mice

To use a vector for vaccination, the efficient expression of the transgene and the presentation of the antigens encoded by the transgene are required. The efficiency of the vaccination is reflected in the antibody titer against the transgene / antigen. The potential of OAV as a vaccination vector was determined by a simple experiment. Balb / C mice received an intramuscular injection of 5 x 10 ⁸ infectious particles OAVhAAT. On day 30 after infection, the antibody titers against the transgene product, human αvAntitrypsin, in the serum of the mice were determined as follows: 96-well plates were tested with 100 μl of an antibody directed against hAAT (DiaSorin, Stillwater, USA, cat. No. 80852 ) coated for 1 h at 37 ° C, overnight with block buffer (5% skimmed milk powder in TBS, 0.05% Tween 20) at 4 ° C and then with a hAAT standard (100 ng / ml in 1 00 μl) for 2 h incubated at 37 ° C. Dilutions of the corresponding mouse sera (1: 10 to 1: 100,000, in a volume of 100 μm) were then added to the plate and the plates were incubated at 37 ° C. for 2 h. Then 100 μl of a rabbit peroxidase-coupled antibody directed against mouse IgG (Pierce, Rockford, USA) was added, and the incubation was continued for 2 h. The enzyme activity was determined using standard methods using OPD as the substrate, and the absorption was measured at 595 nm. In the serum of all mice of the Balb / C strain (n = 5) examined, the antibody titer against hAAT was greater than 1 00000 after an injection of approx. 10 ⁹ infectious particles. In the serum of mice of the strain C57 / BI-6 (n = 5) the antibody titer, according to the administered dose of the vector OAVhaat, was between 1 000 000 and 10 (see Table 1). The induction of antibodies directed against hAAT in the latter mouse strain is remarkable since this strain did not form antibodies against the transgene product after infection with human adenoviral vectors which transduce the hAAT gene (Michou et al., Gene Therapy 4 (1 997), 473-482; Morral et al., (1,997) supra). Table 1 . Antibody titers against hAAT in the serum of mice (C57 / BI-6) who received an intramuscular injection of the specified dose of OAVhaat.

2.3 No detectable expression of OA V genes after infection.

In order to demonstrate whether the injection of OAV in the skeletal muscle of mice leads to the expression of early or late OAV genes, total RNA was obtained from the skeletal muscle 20 and 40 h after infection and analyzed for OAV-specific transcripts by RT-PCR. In control animals, an infection with the human adenovirus Ad 5haat (1 0 ¹⁰ infectious particles) and a corresponding transcript detection were carried out.

Neither early OAV genes (E4 gene, DNA binding protein gene) nor late OAV genes (hexon gene and pVII gene) were detected in mouse skeletal muscle cells infected with OAVhaat. In contrast, PCR products of the E4orf6 gene (20 and 40 h after infection) and the DNA binding protein gene (20 h after infection) were detected in skeletal muscle cells infected with Adδhaat.

While viral genes of the Ad5 vector are thus expressed in the mouse skeletal muscle, expression of viral genes of the OAV could not be detected. 2.4 Efficient expression of genes transduced by means of a non-human adenovirus vector in the cell culture system

IMR 90 cells (Nichols et al., Science 1 96 (1 977), 60-63) were infected with OAVhaat at an MOI of 1. After 3 days, the expression of recombinant hAAT was quantified by an ELISA. The amount of the recombinant protein was determined with 1 mg / ml cell culture supernatant / 1 0 ⁶ cells.

Claims

claims

1. Use of a non-human adenovirus vector for the preparation of an agent for the transfer of genetic material, comprising the envelope of a non-human adenovirus and genetic material packaged therein

(a) DNA sequences from a non-human adenovirus and

(b) contains one or more DNA sequences which code for peptides or polypeptides which are heterologous with respect to the non-human adenovirus, in operative linkage with expression control sequences.

2. Use according to claim 1, characterized in that the virus is an adenovirus from a non-human species selected from mammals and birds.

3. Use according to claim 2, characterized in that the virus is a sheep or cattle adenovirus.

4. Use according to claim 3, characterized in that the virus is an ovine or bovine mastadenovirus or

Is atadenovirus.

5. Use according to claim 3 and 4, characterized in that the sheep adenovirus is the OAV isolate 287.

6. Use according to one of claims 1 to 5 for gene transfer into cells or cell complexes which have changed, also pathological symptoms.

7. Use according to claim 6 for the therapy of inherited, acquired or malignant diseases.

8. Use according to one of claims 1 to 5 for DNA vaccination.

9. Use according to claim 8 for vaccination against pathogens, in particular viruses, bacteria and eukaryotic single or multi-cell.

1 0. Use according to claim 8 for vaccination against malignant or non-malignant cells or cell populations.

1 1. Use according to one of claims 1 to 5 for the production of recombinant proteins.

1 2. Use according to one of claims 1 to 1 1 for the transfer of genetic material in mammalian cells.

1 3. Use according to claim 1 2 for the transfer of genetic material in human cells.

14. Use according to claim 1 2 or 1 3 for the transfer of genetic material into the muscle, in particular into the skeletal muscle.

1 5. Use according to claim 14, characterized. that the muscle cells are selected from myocytes / myotubes / myofibers, fibroblasts, dendritic cells, endothelial cells and combinations thereof.

16. Use according to one of claims 1 to 15, characterized in that the gene transfer is carried out by injection.

17. Use according to one of claims 1 to 16, characterized in that the vector is administered multiple times.