CA2051975A1

CA2051975A1 - Polypeptide

Info

Publication number: CA2051975A1
Application number: CA 2051975
Authority: CA
Inventors: Nobutoshi Yamada; Masanari Kato; Keizo Miyata; Yoshiyuki Aoyama; Hiroshi Shikama
Original assignee: Individual
Current assignee: Ishihara Sangyo Kaisha Ltd
Priority date: 1990-09-21
Filing date: 1991-09-20
Publication date: 1992-03-22

Abstract

ABSTRACT
A polypeptide which is a tumor necrosis factor polypeptide having an amino acid sequence represented by from the 1st Ser to the 155th Leu as shown by SEQ ID NO:1 in the Sequence Listing, or its mutein, wherein the amino acid sequence of the 1st Ser to the 8th Asp of the SEQ ID
NO:1 or the corresponding amino acid sequence of the mutein is replaced by an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids. Also disclosed are a recombinant plasmid containing a DNA encoding such a polypeptide, a recombinant microbial cell transformed by such a recombinant plasmid, a process for producing the polypeptide, a pharmaceutical composition comprising the polypeptide as an active ingredient, and a DNA for the polypeptide.

Description

2051g7~

Our Ref.: IH-85 TITLE OF THE INVENTION
POLYPEPTIDE
BAC~CGROUND OF THE INVENTION

The present invention is concerned with providing a novel polypeptide which is a human TNF N-terminal mutein and relates to the polypeptide itself, a pharmaceutical composition containing the polypeptide, a process for producing the polypeptide, a recombinant DNA sequence encoding the polypeptide, a plasmid containing the recombinant DNA sequence and a transformed microbial cell having the plasmid.
DISCUSSION OF BACKGROUND

TNF (tumor necrosis factor alpha) is a physiologically active compound, which was found to be present in the serum of a mouse preliminarily transfected with _acillus Calmette Guerin (BCG) and treated by endotoxin, by Carswell et al. in 1975 (Proc. Natl. AcadO
Sci. USA, 72, 3666 (1975)). In 1984, cDNA of human TNF
was cloned by Pennica et al., and the entire primary structure (amino acid sequence) of the human TNF protein was clarified (Nature, 312, 724 (1984)). TNF has specific antitumor effects such as a cytotoxic activity against tumor cells and hemorrhagia necrosis or growth inhibition against transplanted tumors. However, it has been reported recently that side effects such as 205197~

hyperlipemia, hypotension or fever, are likely to result from the administration of TNF. Accordingly, many research and development effects are being made to obtain a product superior in the activity as compared to TNF, while exhibiting reduced side effects For example, Japanese Vnexamined Patent Publications No. 40221/1986 (U.S. 4,650,674), No. 119692/1988 (U.S. 4,990,455) and No. 277488/1989 (EP-A-340,333~ disclose deletion of a certain specific amino acid residues in the human TNF
protein, or replacement of such an amino acid residues by other amino acid residues or addition of other amino acid residues, to provide a human TNF mutein.
However, it has not yet been possible to obtain a human TNF mutein having fully satisfactory pharmacological effects.
SUMMARY OF THE INVENTION
Accordingly, it is an object of the present invention to provide a novel human TNF N-terminal mutein having antitumor effects similar to human TNF or its mutein while being free of side effects associated with TNF.
It is another object of the present invention to provide a human TNF N-terminal mutein, having antitumor effects similar to human TNF or a mutein thereof, which is free of the side effect of promoting metastasis as observed with human TNF or muteins thereof.
It is another object of the present invention to provide a method for preparing such human TNF N-terminal 20~1~7~

muteins.
It is another object of the present invention to provide pharmaceutical compositions containing such human TNF N-terminal muteins.
It is another object of the present invention to provide recombinant DNA sequences which encode such human TNF N-terminal muteins.
It is another object of the present invention to provide plasmids which contain such recombinant DNA
sequences.
It is another object of the present invention to provide transformed microbial cells which have such plasmids.
These and other objects, which will become apparent during the following detailed description, have been achieved by a polypeptide which is a tumor necrosis factor polypeptide having an amino acid sequence represented by the sequence from the 1st Ser to the 155th Leu as shown by SEQ ID NO:l in the Sequence Listing, or a mutein thereof, wherein the amino acid sequence of the 1st Ser to the 8th Asp of said SEQ ID NO:l or the corresponding amino acid sequence of said mutein is replaced by an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and having from 3 to 16 amino acids.
The present inventors have found it possible to obtain a novel human TNF N-terminal mutein polypeptide 2 ~ 7 ~

which has substantially the same antitumor activity as human TNF or a mutein thereof but which does not substantially promote tumor metastasis as observed with human TNF or its mutein, by incorporating an amino acid sequence of ~rg-Gly-Asp at a certain amino acid sequence domain of the amino acid sequence of human TNE` or a mutein thereof. The present invention has been accomplished on the basis of this discovery.
RIEF DESCRIPTION OF THE DRAWINGS
10A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein Figure 1 illustrates the process steps for cloning a human TNF gene by ligation of synthetic oligonucleotides.
Figure 2 illustrates the process steps for cloning a human TNF gene by ligation of synthetic oligonucleotides.
20Figure 3 illustrates the process steps for cloning an expression plasmid vector.
Figure 4 illustrates the process steps for cloning a human TNF expression vector.
Figure 5 illustrates the process steps for preparing a human TNF mutein or N-terminal mutein gene by site directed mutagenesis.
Figure 6 illustrates the process steps for preparing 20~197~

a human TNF mutein or N-terminal mutein gene by site directed mutagenesis.
Figure 7 illustrates the process steps for cloning a human TNF N-terminal mutein expression vector by gene recombination utilizing restriction endonuclease cleavage sites.
Figure ~ illustrates the process steps for cloning a human TNF N-terminal mutein expression vector by gene recombination utilizing restriction endonuclease cleavage sites.
Figure 9 illustrates the process steps for cloning an expression plasmid vector.
Figure 10 illustrates the process steps for cloning an expression plasmid vector.
Figure 11 illustrates the process steps for cloning an expression plasmid vector.
Figure 12 illustrates the process steps for cloning a human TNF N-terminal mutein expression vector by ~ene recombination utilizing restriction endonuclease cleavage sites.
Figure 13 illustrates the results of electrophoresis of the purified samples of the human TNF polypeptide and the human TNF N-terminal mutein polypeptide expressed by Escherichia Coli.
Figure 14 illustrates the results of electrophoresis of the purified samples of the human TNF N-terminal mutein polypeptide expressed by Escherichia Coli.

2~975 DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
The tumor necrosis factor polypeptide having an amino acid sequence represented by the sequence from the 1st Ser to the 155th Leu as shown by SEQ ID NO:l in the Sequence Listing represents human TNF.
In the present invention, the term "the mutein of human TNF" and the term "human TNF or a mutein thereof"
include a mutein obtained by applying a single or combined treatment of modifications such as addition, deletion and replacement of one or more amino acids, suitably to the amino acid sequence as shown by SEQ ID
NO:l in the Sequence Listing and having antitumor effects similar to human TNF. Such muteins may be obtained by recombinant DNA techniques. Accordingly, in the present invention, the amino acid sequence of said mutein corresponding to the amino acid sequence of from the 1st Ser to the 8th Asp of SEQ ID NO:l, corresponds to the amino acid sequence after modification, in a case where the above amino acid sequence is modified in the mutein.
This modification includes deletion of one or more amino acids and thus includes partial or entire deletion of the amino acid sequence of from the 1st Ser to the 8th ASp.
Specifically, the human TNF mutein includes, for example, the following, but the present invention is not limited to such specific examples.
(1) As disclosed in Japanese Unexamined Patent Publication No. 141999/1988 (U.S. 4,948,875):

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To the N-terminal, Val-Arg is added, and further, 29Arg-30Arg is changed to 29Asn-30Thr.
(2) As disclosed in Japanese Unexamined Patent Publication No. 119692/1988 (U.S. 4,990,455):
(A) 32Asn is changed to 32Tyr, 32His 32Asp or 32Se B) ll5Pro is changed to ll5Leu 115Ser llsAsp or Gly .
(C) 1l7Tyr is changed to l17His.

(3) As disclosed in Japanese Unexamined Patent Publication No. 277488/1989 (EP-A-340,333):
lSer to 3Asp are deleted, and Arg-Lys-Arg is added to the N-terminal of 9Lys.

(4) As disclosed in Japanese Unexamined Patent Publication No. 163094/1990 (WO-90-03395):
lSer to 3Asp are deleted, and Arg-Lys-Arg is added to the N-terminal of 9Lys, and l54Ala is changed to l54Phe.

(5) As disclosed in Japanese Unexamined Patent Publication No. 142493/1990 (WO-90-03395):
lSer to 3Asp are deleted, Arg-Lys-Arg is added to the 20 N-terminal of 9Lys, and l54Ala is changed to l54Trp.

(6) As disclosed in Japanese Unexamined Patent Publication No. 270697/198~:
100Gln to l07Ala are deleted.
From lSer, from 2 to 8 amino acid residues are deleted.

(7) As disclosed in Japanese Patent Application No.
193935/1990:

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68Pro is changed to 58Asp, 68Met or 68Tyr.

(8) As disclosed in Japanese Patent Application No.
311129/1990: l06Gly is deleted or replaced by another amino acid.
~9) As disclosed in Japanese Patent Application No.
311130/1990: 29Arg is replaced by another amino acid.
Throughout the specification, symbols in the following list are used to represent amino acids, polypeptides, bases or their sequences.
Amino acids:
Symbols: Ala, Cys, Asp, Meaning: alanine, cysteine, aspartic acid, Symbols: Glu, Phe, Gly, Meaning: glutamic acid, phenylalanine, glycine, Symbols: His, Ile, Lys, Leu, Meaning: histidine, isoleucine, Lysine, Leucine, Symbols: Met, Asn, Pro, Meaning: methionine, asparagine, proline, Symbols: Gln, Arg, Ser, Thr, Meaning: glutamine, arginine, serine, threonine, Symbols: Val, Trp, Tyr Meaning: valine, tryptophan, tyrosine When used in a polypeptide sequence, these symbols represent amino acid residues, rather than free amino acids.

~051975 Bases:
Symbols: A, C, G, T, U
Meaning: adenine, cytosine, guanine, thymine, uracil When used in a DNA sequence, these symbols represent deoxyribonucleic acid residues rather than free molecules such as adenosine phosphate or free bases such as adenine.
Further, various abbreviations used in the specification have the following meanings.
dATP: Deoxy adenosine triphosphate dGTP: Deoxy guanosine triphosphate dCTP: Deoxy cytidine triphosphate TTP: Thymidine triphosphate ATP: Adenosine triphosphate SDS: Sodium dodecyl sulfate BPB: Bromophenol Blue DTT: Dithiothreitol BSA: Bovine serum albumin PMSF: Phenylmethylsulfonyl fluoride EDTA: Ethylenediaminetetraacetic acid CPG resin: Controlled-Pore Glass resin In the polypeptide N-terminal mutein of the present invention, the amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp at a certain position and from 3 to 16 amino acids, is optionally determined taking the antitumor activity, the degree of metastasis of cancer, the side effects, the applicability 205197~

of the gene recombination technique, etc. into consideration. The amino acid sequence containing from 3 to 16 amino acids, is preferably an amino acid sequence containing from 3 to 11 amino acids, which has one or more amino acid sequences of Arg-Gly-Asp. Specifically, amino acid sequences shown by SEQ ID NOS:2 to 9 in the Sequence Listing, and Arg-Gly-Asp may be mentioned.
Among them, SEQ ID NOS:2, 3, 5 and 6, and Arg-Gly-Asp are particularly preferred.
The sequence of the present polypeptides, other than the amino acid sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, corresponds substantially to the sequence from the 9th Lys to the 155th Leu in SEQ ID NO:l and may contain up to 15 additions, deletions or substitutions of amino acid residues or combinations thereof. The sequence other than the amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, of the polypeptide N-terminal mutein of the present invention, is preferably an amino acid sequence of human TNF represented by the sequence from the 9th Lys to the 155th Leu of SEQ ID NO:l, or such an amino acid sequence having the 29th Arg, the 68th Pro or the 106th Gly deleted or replaced by another amino acid residue.
Such another amino acid residue is preferably Gln, Lys, Asp, Val or Leu for the 29th Arg; it is preferably Asp or Met for the 68th Pro; and it is preferably Trp, Pro, Ala, 205~975 Asp or Arg for the 106th Gly.
Thus, the present polypeptide N-terminal mutein is suitably from 135 to 178 amino acid residues long, preferably 135 to 173 amino acid residues long.
The DNA for a tumor necrosis factor polypeptide having a nucleotide sequence represented by the 1st T to the 465th G as shown by SEQ ID NO:10 in the Sequence Listing, is one form of DNA encoding the amino acid sequence of human TNF.
The mutational DNA of a DNA encoding the amino acid sequence of human TNF, is a DNA obtained by applying a single or composite treatment of modifications such as addition, deletion and replacement of one or more sets of codons appropriately to the nucleotide sequence as shown by SEQ ID NO:10 in the Sequence Listing and encoding the amino acid sequence of the above-mentioned human TNF
mutein. Accordingly, such modifications are applicable to the entire region of the nucleotide sequence represented by the 1st T to the 465th G as shown by SEQ
ID NO:10. Namely, such modifications are applicable not only to the nucleotide sequence of from the 1st T to the 24th C, but also to the nucleotide sequence of from the 25th A to the 465th G.
Now, the present invention will be described in detail with reference to Examples. For the gene manipulation involved in the present invention, conventional methods and techniques disclosed in many 2~197~

references may be employed with suitable adjustments.
Some of such references will be listed below.
T. Maniatis et al., (1982): Molecular Cloninq, _ Laboratory Manual (hereinbelow, referred to simply as Molecular Cloning), Cold Spring Harbor Laboratory, R. Wu et al., (1983): Methods in Enzymoloqy, 100 and 101, R. Wu et al., (1987): Methods in Enzymoloqyl 153, 154 and 155 The polypeptide of the present invention can be produced by various methods, by means of various techniques and equipments. A typical method for its production will now be described.
(1) Designing of a human TNF gene As mentioned above, the nucleotide sequence of a human TNF gene and the amino acid sequence of the human TNF have been clarified by Pennica et al., and the nucleotide sequence is changed as the case requires to design the human TNF gene as shown by SEQ ID NO:10. At that time, it is preferred to select codons suitable for the host cell (such as Escherichia coli), and it is further preferred to provide restriction endonuclease cleavage sites at appropriate positions to facilitate the gene modification for the preparation of a mutein and to facilitate the cloning by ligating DNA fragments as described hereinafter. It is of course necessary to provide a translation initiation codon (ATG) at the 5'-side and a translation termination codon (TAA, TGA or TAG) at the 3'-side of the human TNF gene respectively.

20~197~ -Further, it is preferred to provide appropriate restriction endonuclease cleavage sites upstream of the translation initiation codon and downstream of the translation termination codon, respectively, to improve the applicability to a vector and to facilitate the cloning.
Here, the preparation is based on the above-mentioned DNA double-strands. The upper (coding or sense) strand contains 474 bases (hereinafter referred to as a coding 474U strand) having 5'-ATG-3' joined in an upstream direction to the 1st T in SEQ ID NO:10 and having 5'-TAATGA-3' joined in a downstream direction to the 4b5th G
in SEQ ID NO:10. Accordingly, the lower strand (hereinafter refered to as a complementary 474L strand) contains 474 bases starting from T and ending at T, as described below the upper strand, and is complementary to the coding 474U strand.
The human TNF gene can be prepared by a method wherein each of the upper and lower strands is divided into a plurality of oligonucleotides, such a plurality of oligonucleotides are chemically synthesized, and blocks of such synthesiæed oligonucleotides are then sequentially appropriately ligated. For example, in the case of DNA double-strands prepared on the basis of the DNA double-strands comprising the coding 474U strand and the complementary 474L strand, each of the strands for the human TNF gene is divided into ten oligonucleotides each comprising about 50 bases, and a total of twenty oligonucleotides are chemically synthesized.
As the method for such synthesis, a diester method (H.G. Khorana, "Some Recent Developments in Chemistry of Phosphate Esters of Biological Interest", John Wiley and Sons, Inc., New York (1961)), a triester method (R. L.
Letsinqer et al., J. Am. Chem. Soc., 89, 4801 (1967)), or a phosphite method (M. D. Matteucci et al., Tetrahedron Lett., 21, 719 (1980)) may be mentioned. However, in view of the operation efficiency, it is preferred to employ a phosphite method using a completely automated DNA synthesizer.
Synthesized oligonucleotides are then purified by a conventional purification method such as high performance chromatography using a reversed phase chromatocolumn or electrophoresis using polyacrylamide gel. Thereafter, the oligonucleotides are phosphorylated by means of, e.g., T4 polynucleotide kinase, then annealed and ligated by means of T4 DNA ligase. Here, the oligonucleotides are divided into several blocks and sequentially ligated so that the human TNF gene sequence will eventually be obtained, followed by digestion with restriction endonuclease or polishing (make blunt-end) with T4 DNA
polymerase, and the resulting DNA fragments are then purified by electrophoresis. The obtained DNA fragments are inserted into plasmid vectors such as pUC8, pUC9, pUC18 and pUCl9 (J. Messinq et al., Gene, 19, 259 20~197S

(1982)), and the inserted plasmid vectors are introduced into competent cells for cloning in accordance with a conventional method. From the obtained clones, plasmid DNAs are extracted and purified by a conventional method, and they are examined to see whether or not the nucleotide sequences of the DNA fragments inserted into the vectors agree with the desired gene sequence. The respective sections of the human TNF gene thus-obtained, are then cut out from the plasmid vectors containing them, by means of restriction endonucleases, then ligated and inserted again into the above vector to obtain a plasmid vector having the desired full length of the human TNF gene. The plasmid vector thus-obtained is digested by restriction endonucleases and separated and purified by gel electrophoresis to obtain the desired human TNF gene.
On the other hand, a method which comprises preparing cDNA encoding human TNF from mRNA derived from human cells expressing TNF and using such cDNA, may be used in combination with the above described method, as the case requires.
(2) Cloning of human TNF expression vector The human TNF gene obtained in the above step (1) is appropriately inserted into an expression vector to clone a human TNF expression vector. The expression vector is required to have a promoter and a SD (Shine-Dalgano) sequence upstream of the translation initiation codon 20~197~

(ATG) and a terminator downstream of the translation termination codon (TAA, TGA or TAG). As the promoter, trp promoter, lac promoter, tac promoter, PL promoter, ~-lactamase promoter, ~-amylase promoter, PH05 promoter, or ADCI promoter may be suitably used, and as the terminator, trp terminator, rrnB terminator or ADCI
terminator may be suitably used. Such an expression vector is readily available among commercial products such as pKK223-3 (Pharmacia), pPL-lambda (Pharmacia) and pDR720 (Pharmacia). However, such commercial products may further be improved for use to have better expression properties or handling efficiency.
(3) Cloning of human TNF mutein or N-terminal mutein expression vector The following methods may, for example, be employed for the preparation of DNA encoding the human TNF mutein or N-terminal mutein polypeptide.
(A) In the same manner as the method described in the above step (1) for designing the human TNF gene, chemically synthesized oligonucleotides are appropriately ligated to obtain such a mutant DNA. According to this method, modification such as the replacement, addition or deletion of a codon or codons encoding an amino acid, an oligopeptide or a polypeptide, can freely be performed.
(B) q'he human TNF gene prepared in the above step (1) is cut by appropriate restriction endonucleases to remove a certain specific region in the gene, and then a 20~197~

synthetic oligonucleotide having a nucleotide sequence with a mutation introduced (for example: a double-stranded DNA fragment prepared by annealing the upper and lower strands, and ligating them) or an appropriate other gene is inserted. The modification can freely be performed also by this method in the same manner as in the above method (A).
(C) Introduction of a mutation is conducted by extending the DNA strand by using, as a primer, a synthesized oligonucleotide having a nucleotide sequence with the mutation introduced [site directed mutagenesis method (T. A. Kunkel et al., Methods in Enzymoloqy, 154, 367 (1987))]. This method is not suitable for addition or insertion of a relatively long DNA chain exceeding ten base pairs. However, other modifications can freely be performed in the same manner as in the above method (A).
This method is suitable, particularly for replacing any desired amino acids.
In the present invention, the site directed mutagenesis method (C) and the method (B) of using the fragments cut by restriction endonucleases, are usually used in combination, as the case requires. Such a method will be described below.
(i) By the site directed mutagenesis method, DNA
encoding a mutein or N-terminal mutein polypeptide is prepared and suitably inserted into an expression vector.
Firstly, to conduct the site directed mutagenesis 205197~

method, template DNA is prepared. The human TNF gene obtained in the above step (1) is ligated to a plasmid vector (such as pUC118 or pUCll9) for the preparation of a single-stranded plasmid DNA developed by Messinq et al.
(Methods in Enzymoloqy, 153, 3 (:Lg87)), and then _ introduced into Escherichia coli. From the transformant thereby obtained, a clone having the desired plasmid is selected.
This plasmid is introduced into a dut- and ung~ E.
coli mutant (such as a CJ236 strain) to have uracil taken in the gene, and the E. coli mutant is infected with a recombinant helper phage such as M13K07 to obtain the desired single stranded plasmid DNA.
On the other hand, an oligonucleotide primer with from about 15 to 50 bases having the mutation introduction site and the forward and backward base sequences thereof according to the present invention, is chemically synthesized. This primer and the uracil-introduced single-stranded plasmid DNA obtained by the previous step, are annealed and then double-stranded by means of e.g. T4 DNA polymerase and T4 DNA ligase. The double stranded plasmid is introduced into a ung+ E. coli strain, to deactivate the DNA strand containing uracil as a template and thereby to improve the frequency for introduction of the mutation.
Using the above primer as a probe, colony hybridization is conducted, whereupon a clone having a 20~197~

plasmid containing DNA encoding the desired mutein or N-terminal mutein polypeptide, is selected from the ~btained transformants.
From the plasmid thus-obtained, a DNA fragment encoding the human TNF mutein or N-terminal mutein polypeptide, is cut out by restriction endonucleases and inserted into an expression vector in the same manner as in the case of the above step (2) to clone the desired human TNF mutein or N-terminal mutein expression vector.
(ii) A section to which a mutation is to be introduced, is cut out by suitable restriction endonucleases and substituted by a DNA fragment prepared by, e.g., chemical synthesis in accordance with the modification design, to obtain an expression vector of the mutein or N-terminal mutein polypeptide.
To modify the amino acid sequence in the vicinity of the N-terminal of human TNF, it is preferred that there exists suitable restriction endonuclease cleavage site in the vicinity of the N-terminus. Therefore, a suitable restriction endonuclease cleavage site is introduced near the N-terminus of human TNF by the site directed mutagenesis. It is further preferred to provide two types of cleavage sites, i.e., this restriction endonuclease cleavage site and a restriction endonuclease cleavage site provided before or after the translation initiation codon located upstream thereof.
On the other hand, in accordance with the 2 ~ 7 ~
- 2~ -modification design of the present invention, oligonucleoti.des corresponding to the upper (coding) and lower (noncoding) strands are chemically synthesized in the same manner as in the case oE the above step (1). It is, of course, necessary to provide the above-mentioned restriction endonuclease cleavage sites at both termini in consideration oE the insertion into an expression vector. Such oligonucleotides (the upper and lower strands) are phosphorylated by means of, e.g., T4 polynucleotide kinase, followed by annealing, to obtain a double-stranded DNA fragment. This double-stranded DNA
fragment is inserted and ligated by means of, e.g., T4 DNA ligase in the expression plasmid vector containing the majority of human TNF digested by the above-mentioned two types of restriction endonucleases (with the N-terminal portion deleted), to obtain the desired expression vector of the human TNF N-terminal mutein having the amino acid sequence near the N-terminus modified.
By using appropriate restriction endonuclease cleavage sites in the gene encoding the mutein or N-terminal mutein polypeptide, recombination among the respective expression vectors may be conducted to produce further expression vectors for novel mutein or N-terminal mutein polypeptides.
Introduction of an expression vector into host cells such as cells of a E. coli strain can be conducted by a 20~1~7S

conventional method, such as a method of employing competent cells of an E. coli strain prepared by a calcium chloride method (Molecular Cloninq, T. Maniatis et al., (1982)). As such host cells, microbial cells such as Escherichia coli, Bacillus or yeast can be used.
Among them, as Escherichia coli, mutants of a E. coli K-12 strain such as JM83, JM103 and HB101, may be mentioned.
(4) Preparation of human TNF N-terminal mutein polypeptide In the present invention, the transformed microbial cells disclosed in the above step (3) are cultured, whereby the desired human TNF N-terminal mutein polypeptide will be produced and accumulated in the culture, and the accumulated polypeptide is ther.
extracted and separated. As a method for culturing the microbial cells, particularly cells of Escherichia coli, a conventional method may be employed such as a method wherein Escherichia coli is inoculated to a medium containing nutrients requested by Escherichia coli, and cultured in a large amount in a short period of time usually by shaking or stirring the inoculated medium at a temperature of from 32 to 37~C for from 12 to 24 hours.
As the medium, L-broth, M9 medium or M9CA medium (see the above-mentioned Molecular Cloning) may, for example, be used. If necessary, an antibiotic such as ampicillin may be added, and in order to improve the efficiency of the 2~9~

promoter, it is possible to add a reagent such as isopropyl-~-D-thiogalactopyranoside in the case where lac promoter or tac promoter is used, or a reagent such as 3-~-indole acrylic acid in the case where trp promoter is used, at the initiation of culturing or during the culturing.
The human TNF N-terminal mutein polypeptide of the present invention is obtained usually by sonicating microbial cells after culturing, in a suspended state in Tris-buffer, followed by centrifugal separation to remove debris. The product thus-obtained may further be purified by treatment with nucleic acid endotoxin removing agent, filtration by a filter, anion exchange chromatography or any other conventional protein-sepa~ation and purification method~
~ y applying the above-described methods appropriately, the human TNF N-terminal mutein gene of the present invention can be produced directly, or can be produced after the preparation of the human TNF gene, or can be produced after preparing the human TNF gene, followed by preparation of its mutein gene.
The human TNF N-terminal mutein polypeptide of the present invention has the same antitumor activity as human TNF or a mutein thereof, while being free of the metastasis-promoting side effect. ~hile it shows antitumor activities at the same level as human TNF or its mutein, it shows no substantial activity for 20~975 promoting metastasis of tumor which is observed ~ith human TNF or its mutein. Therefore, it is effective as an active ingredient for an antitumor agent or pharmaceutical. Specific examples of the human TNF N-terminal mutein polypeptide of the present inventioninclude, for example, F4168, F4415, F4416, F4417, F4418, F4420, F4421, E`4113, F4137, F4601, F4602, F4607, F4608, F4626, F4627, F4634, F4635, F4609, F4610, F4628, F4629, F4638, F4639, F4611, F4612, F4613, F4614, F4615, F4642, F4643, F4644, F4645 and F4646, which will be described hereinafter. Among them, F4168, F4415, F4417, F4418, F4420, F4601, F4609 and F4639 are preferred, and F4168 and F4418 are particularly preferred. To prepare its pharmaceutical compositions containing the present polypeptide, the present polypeptide can be formulated into pharmaceutical compositions together with pharmaceutically acceptable carriers or diluents. The types of the pharmaceutical compositions of the present invention include agents for external application, agents for oral administration and agents for injection. The pharmaceutical compositions are administered by administration methods suitable for the respective formulations.
As the administration method, injection is preferred.
The injection includes systemic injection and local injection. The systemic injection includes intravenous injection, subcutaneous injection, intramuscular 20~197~

injection and intradermal injection. The pharmaceutical composition of the present invention may be applied to any method. However, the system:ic injection is preferred taking into consideration the applicability to various cancer species. Further, Erom the nature of the drug, intravenous injection is particularly preferred. The cancer species include solid tumors such as colorectal cancer, lung cancer, gastric cancer, pancreatic cancer and melanoma, and leukemia. The pharmaceutical composition of the present invention may be applied to any cancer species. However, it is particularly preferred to apply it to a solid tumor.
Having generally described the invention, a further understanding can be obtained by reference to certain specific examples, which are provided herein for purposes of illustration only and are not intended to be limiting unless otherwise specified.

EXAMPLES

Desiqninq of human TNF qene On the basis of the amino acid sequence of the human TNF structural gene already reported by Pennica et al. as mentioned above, a nucleotide sequence of DNA double-strands, i.e. coding 474U strand and complementary 474L
strand, in the DNA strand sequence of SEQ ID NO:10 in the Sequential Listing and a nucleotide sequence of such DNA
double-strands with a certain modification, were designed 20~197~

for the convenience of gene cloning and mutein preparation with respect to the nucleotide sequence of the human TNF gene. Here, restriction endonuclease cleavage sites were inserted at appropriate intervals.
Further, in order to facilitate the ligation to a plasmid vector, a cleavage site by restriction endonuclease EcoR
I was provided upstream of a translation initiation codon (ATG), and a cleavage site by restriction endonuclease Hind III was provided downstream of a translation termination codon (TAA and TGA).

Chemical synthesis of oliqonucleotides The DNA designed in Example 1 was chemically synthesized by a phosphite method by means of an automatic DNA synthesizer (Model 381A, manufactured by Applied Biosystems). After dividing the designed DNA
into twenty oligonucleotides of U-l to U-10 and L-l to L-10 having nucleotide sequences as described hereinafter, they were synthesized. Cleavage of the synthesized oligonucleotides from CPG resin (sold by Funakoshi Company) and removal of the protecting groups were conducted in accordance with the Manual of Applied Biosystems, Inc. The separation and purification of each oligonucleotide was conducted by HPLC (high performance liquid chromatography) using a reversed phase chromatocolumn or by electrophoresis on a polyacrylamide gel containing 7M urea (gel concentration: 10-20%).

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The nucleotide sequences of U-l to U-10 and L-l to L-10 are as follows.
U-l: Comprises 27 bases and has a sequence of from the 1st T to the l9th A of SEQ ID NO:10, and yet has a sequence in which 5'-ATG-3' is joined upstream of the 1st T and 5'-AATTC-3' is joined upstream thereof.
U-2: Comprises 50 bases and has a sequence of from the 20th G to the 69th G of SEQ ID NO:10.
U-3: Comprises 49 bases and has a sequence of from the 70th C to the 118th G of SEQ ID NO:10.
U-4: Comprises 50 bases and has a sequence of from the ll9th A to the 168th C of SEQ ID NO:10.
U-5: Comprises 50 bases and has a sequence of from the 169th T to the 218th T of SEQ ID NO:10.
U-6: Comprises 52 bases and has a sequence of from the 219th C to the 270th C of SEQ ID NO:10.
U-7: Comprises 48 bases and has a sequence of from the 271st C to the 318th C of SEQ ID NO:10.
U-8: Comprises 49 bases and has a sequence of from the 319th G to the 367th C of SEQ ID NO:10.
U-9: Comprises 51 bases and has a sequence of from the 368th A to the 418th C of SEQ ID NO:10.
U-10: Comprises 53 bases and has a sequence of from the 419th T to the 465th G of SEQ ID NO:10, and further has 5'-TAATGA-3' downstream thereof.
L-l to L-10 are for the lower strand (complementary sequence) corresponding to the DNA strand of SEQ ID

20~L97~

NO: 10 .
L-l: Comprises 29 bases and has a sequence complementary to the sequence of from the 25th A to the 1st T of SEQ ID NO:10, and yet has a sequence having 5'-CATG-3' joined to the 3'-side of A complementary to the 1st T, of the upper strand.
L-2: Comprises 52 bases and has a sequence complementary to the sequence of from the 77th G to the 26th A of SEQ ID NO:10.

L-3: Comprises 50 bases and has a sequence complementary to the sequence of from the 127th G to the 78th G of SEQ ID NO:10.
L-4: Comprises 50 bases and has a sequence complementary to the sequence of from the 177th G to the 128th A of SEQ ID NO:10.
L-5: Comprises 49 bases and has a sequence complementary to the sequence of from the 226th C to the 178th G of SEQ ID NO:10.
L-6: Comprises 49 bases and has a sequence complementary to the sequence of from the 275th T to the 227th A of SEQ ID NO:10.
L-7: Comprises 51 bases and has a sequence complementary to the sequence of from the 326th C to the 276th C of SEQ ID NO:10.
L-8: Comprises 49 bases and has a sequence complementary to the sequence of from the 375th G to the 327th C of SEQ ID NO:10.

20~75 L-9: Comprises 51 bases and has a sequence complementary to the sequence of from the 426th T to the 376th A of SEQ ID NO:10.
L-10: Comprises 49 bases and has a sequence complementary to the sequence of from the 465th G to the 427th G of SEQ ID NO:10, and yet has a sequence having 5'-TCATTA-3' joined to the 5'-side of C complementary to the 465th G and having 5'-AGCT-3' joined to the 5'-side thereof.
With respect to the HPLC methodr separation and purification were conducted by eluting with an acetonitrile-containing triethylamino acetic acid (100 mM) buffer (pH 7.0) by means of reversed chromatography using a Nucleosil 5C18 column (~4.6 x 150 mm, sold by Chemco Scientific Co., Ltd.). The elution was conducted at a linear concentration gradient of acetonitrile of from 5 to 35% (30 minutes), and a peak of about 15 minutes was recovered.
With respect to the polyacrylamide gel electrophoresis, the respective synthesized oligonucleotide samples were separated by electrophoresis, and the band portion having the desired size was cut out as a result of the observation of the migration pattern by a UV-shadowing method, and the polyacrylamide gel fragment was cut into a size of about 1 to 2 mm3, and about 2 me of an eluting buffer (0.5M
NH40Ac and 1 mM EDTA) was added, and the mixture was 20~97~

shaken overnight at 37C. The eluted buffer solutions containing the respective oligonucleotides were recovered, followed by phenol extraction (using a 50%
phenol/50% chloroform solution) and isobutanol extraction, and ethanol precipitation operation to obtain purified samples of the respective oligonucleotides.
With respect to some of the oligonucleotides thus-synthesized and purified, it was confirmed by a Maxam-Gilbert method (A. M. Maxam et al, Methods in Enzymoloqy, 65, 499 (1980)) that they had the desired nucleotide sequences.
In the following gene recombination operations (Examples 3, 4, 5, 6, 7, 8, 9, 10, 11 and 12), the reaction conditions, etc. of restriction endonucleases and other related enzymes were mainly in accordance with the method disclosed in the above-mentioned "Molecular Cloning". Further, the above enæymes, etc. were available mainly from I'akara Shuzo, and the manual of Takara Shuzo was also used as a reference.

Cloninq of a human TNF qene by liqation of sYnthesized oliqonucleotides (1) Firstly, cloning of a human TNF gene was tried in accordance with Figure 1. The synthesized oligonucleotides obtained in Example 2 were divided into three groups (U- and L-l to 4, U- and L-5 to 7 and U- and L-8 to 10) for cloning. Namely, the 5'-terminus of each 2 ~ 7 5 (1-2 ~g) of oligonucleotides U-2, 3, 4, 6, 7, 9 and 10 and L-l, 2, 3, 5, 6, 8 and 9 was separately phosphorylated by means o~ from 2 to 5 units of T4 polynucleotide kinase (Takara Shuzo). The phosphorylation reaction was conducted at 37C for one hour in 10 ~ll of an aqueous solution (50 mM Tris-HCl pH
7.6, 10 mM MgCl2, 0.1 mM Spermidine, 0.1 mM ~DTA, 10 mM
DTT and 1 mM ATP), and after the reaction, T4 polynucleotide kinase was deactivated by treatment at 70C for 10 minutes. Separately, 10 ~1 of aqueous solutions of the same compositions as above which contained from 1 to 2 ~g of oligonucleotides U-l, 5 and 8 and L-4, 7 and 10, respectively, were prepared. The aqueous solutions of oligonucleotides with the same U-and L-numbers (U-l to 10 and L-l to 10) were mixed, respectively (20 ~1), and the respective mixtures were boiled at 100C for 5 minutes, followed by gradual cooling for annealing. Then, the obtained ten annealed fragments (double stranded DNA fragments) were divided into the above groups, and the fragments in each group were added to an aqueous solution for a ligation reaction (66 mM Tris-HCl pH 7.6, 6.S mM MgCl2, 10 mM DTT, 1 mM ATP
and 100 ~g/ml BSA) ~total amount: 120-160 ~1), and the solution was heated to 40C and then gradually cooled for annealing. Then, 700 units of T4 DNA ligase (Takara Shuzo) was added thereto, and the ligation reaction was conducted at 16C for 15 hours.

20~1~75 After completion of the reaction, the respective reaction solutions were separated by polyacrylamide gel electrophoresis (gel concentration: 6%). From the results of observing the migration patterns by the Ethidium Bromide Staining method, the band portions having the desired sizes (176 bp, 150 bp and 153 bp) were cut out, and the desired three DNA fragments were recovered by an electro-elution method. Further, the recovered samples were subjected to phenol extraction (using a 50% phenol/50% chloroform solution) and isobutanol extraction, followed by an ethanol precipitation operation to purify the desired DNAs. The three double stranded DNA fragments thus-purified, in accordance with the above-mentioned method, were phosphorylated respectively at their 5'-termini by means of T4 polynucleotide kinase, and then they were mixed in an aqueous solution for a ligation reaction, then annealed at 40C and ligated by an addition of T4 DNA
ligase. The ligated DNA was recovered by an ethanol precipitation operation and then dissolved in 50 ~1 of a high salt buffer (50 mM Tris-HCl pH 7.5, 100 mM NaCl, 10 mM MgCl2) containing 1 mM of DTT and 100 ~g/ml of BSA.
Then, a digestion reaction was conducted at 37C for two hours by an addition of 15 units of restriction endonuclease EcoR I (Takara Shuzo) and 15 units of restriction endonuclease Hind III (Takara Shuzo). After completion of the reaction, the desired DNA fragment 20~197~

(about 480 bp) was separated and purified by polyacrylamide gel electrophoresis (gel concentration:
4%) in accordance with the above-mentioned method.
On the other hand, 5 ~g of plasmid vector pUC9 (obtained from Research Laboratory for Genetic Information of Kyushu University) was digested with restriction endonuclease EcoR I and Hind III in accordance with the above method, and a DNA fragment of about 2.7 Kbp was separated and purified by agarose gel electrophoresis (gel concentration: 1%). This pUC9 fragment and the previously purified DNA fragment of about 480 bp (containing the human TNF gene) were mixed in 20 ~1 of a ligation reaction solution, and a ligation reaction was conducted at 16C for 3 hours by an addition of 350 units of T4 DNA ligase. Competent cells of E.
coli K-12 JM83 strain (obtained from Research Laboratory for Genetic Information of Kyushu University) prepared by a calcium chloride method (see Molecular Cloninq) were transformed with the above-mentioned ligation reaction mixture in accordance with a conventional method (see Molecular Cloninq).
From the ampicillin resistant clone thus-obtained, a plasmid was prepared by a conventional method, and it was treated with restriction endonucleases (EcoR I and Hind III) in accordance with the above-mentioned method, and then its migration pattern was analyzed by agarose gel electrophoresis to examine the insertion of the human TNF

205197~

gene into the pUC9 vector. As a result, insertion of the gene of about 250 bp was confirmed. With respect to the clone, the nucleotide sequence of the inserted gene was examined by a dideoxy method (F. Sanqer, Science, 214, 1205 (1981)), whereby it was confirmed to be a gene fragment having the nucleotide sequence of the desired human TNF gene with a size of about 130 bp downstream from the EcoR I site and a size of about 90 bp upstream from the Hind III site. The clone and the plasmid were designated as pUA41/JM83 and pUA41, respectively.
(2) Then, cloning of a human TNF gene was tried in accordance with Figure 2.
In the nucleotide sequence of the human TNF gene, the region which was not accomplished by the cloning in the above step (1), was divided into two groups (U- and L-3 to 6 and U- and L-6 to 9), and in the same manner as in the above step (1), the oligonucleotides U-4 to 6 and U-7 to 9 and L-3 to 5 and L-6 to 8 were 5'-phosphorylated, then the two groups were annealed and ligated by means of T4 DNA ligase. The products were separated and purified by polyacrylamide gel electrophoresis (gel concentration:
6%) in accordance with the above-mentioned method, and two DNA fragments thereby obtained (201 bp and 200 bp) were respectively dissolved in 100 yl of aqueous solutions containing 67 mM of Tris-HCl (pH 8.8), 6.7 mM
of MgCl2, 16.6 mM of (NH4)2SO4, 6.7 ~M of EDTA, 1 mM of DTT, 200 ~g/ml of BSA and 330 ~M of each of 2 ~ 7 5 deoxyribonucleotide triphosphates (dATP, dGTP, dCTP and TTP), and from 2 to 5 units of T4 DNA polymerase (Takara Shuzo) was added. The mixture was reacted at 37C for 30 minutes to polish both termini of the DNA fragments.
After completion of the reaction, the mixture was treated at 68C for 10 minutes to deactivate the T4 DNA
polymerase, and the desired two DNA fragments were recovered by precipitation with ethanol.
On the other hand, 5 ~g of pUC9 vector was dissolved in 50 ~1 of a medium salt buffer (10 mM Tris-HCl pH 7.5, 50 mM NaCl and 10 mM MgCl2) containing 1 mM of DTT and 100 ~g/ml of BSA, and 15 units of restriction endonuclease Hinc II (Takara Shuzo) was added thereto.
The mixture was reacted at 37C for two hours, and then the vector was recovered by precipitation with ethanol.
Into the cut and ring-opened pUC9 vector thus-obtained, the previously polished and recovered two DNA fragments were, respectively, inserted by means of T4 DNA ligase in accordance with the above-mentioned method, whereby the E. coli K-12 JM83 strain was transformed. With respect to the respective clones thereby obtained, the nucleotide sequences of the inserted DNA were examined in the same manner as in the above step (1) to confirm that they were the desired nucleotide sequences. These clones were designated as pUA42/JM83 and pUA43/JM83, respectively, and the plasmids were designated as pUA42 and pUA43, respectively.

2 ~ 7 ~

The pUA41 obtained in the above step (1) was digested with restriction endonuclease RcoR I (high salt buffer) and Sac I (low salt buffer, manufactured by Takara Shuzo) and restriction endonuclease Hae II (Takara Shuzo) and Hind III (medium salt buffer); the pUA42 obtained in the above step (2) was digested with restriction endonuclease Sac I (low salt buffer) and Hpa I (KCl buffer, manufactured by Takara Shuzo); and the pUA43 was digested with restriction endonuclease Hpa I and Hae II (KCl buffer), respectively, in accordance with the above-mentioned method. With respect to the combination of the low salt buffer (10 mM Tris-HCl pH 7. 5 and 10 mM MgCl2) and the high salt buffer or the KCl buffer ( 20 mM Tris-HCl pH 8.5, 100 mM KCl and 10 mM MgC12), the digestion reaction was conducted twice separately, and the precipitation operation with ethanol was conducted in between the two reactions. EcoR I-Sac I DNA fragment (127 bp) and Hae II-Hind III DNA fragment (80 bp) from the pUA41, Sac I-Hpa I DNA fragment (147 bp) from the pUA42 and Hpa I-~ae II DNA fragment (126 bp) from the pUA43 were, respectively, separated and purified by polyacrylamide gel electrophoresis (gel concentration:
6%) in accordance with the above-mentioned method.
On the other hand, 5 ~g of a pUCl9 plasmid vector (obtained from Research Laboratory for Genetic Information of Kyushu University) was digested with restriction endonuclease EcoR I and Hind III in 20~197~

accordance with the above-mentioned method, and a DNA
fragment of about 2.7 Kbp was separated and purified by agarose gel electrophoresis (gel concentration: 1%). As illustrated (Figure 2), the previously purified four DNA
fragments were sequentially added and ligated thereto by means of T4 DNA ligase in accordance with the above-mentioned method, and finally inserted into the above-purified pUCl9 vector (fragment of about 2.7 Kbp), whereby the JM83 strain was transformed. With respect to the plasmid contained in this transformant, the nucleotide sequence of the inserted gene was examined in accordance with the above-mentioned method, whereby it was confirmed to be a clone having a plasmid vector (about 3.2 Kbp) containing the desired human TNF gene of full length (about 480 bp). This clone was designated as pUA44/JM83, and the plasmid was designated as pUA44.

Clonin~ of a human TNF exPression vector (1) The following improvements were applied to expression vector pKK 223-3 (obtained from Pharmacia) having a tac promoter so that the vector can more easily be handled.
(A) To lower the molecular weight of the expression vector.

(B) To make the cleavage site by restriction endonuclease Bam~ I unique.
(C) To make the direction of the tac promoter 20~197~

opposite to the direction of the ampicillin resistant gene.
The method is illustrated in Figure 3.
5 ~g of plasmid vector pBR 322 (obtained from Research Laboratory for Genetic Information of Kyushu University) was digested with restriction endonuclease EcoR I and Hind III in accordance with the method of Example 3, and both termini thereof were polished by means of T4 DNA polymerase. In accordance with the method of Example 3, a DNA fragment of about 4.4 Kbp was separated and purified by agarose gel electrophoresis (gel concentration: 1%). Then, lO0 ng of nonphosphorylated Bgl II linker (a double-stranded DNA
fragment of lO bp containing a restriction endonuclease Bgl II cleavage site, obtained from Takara ~huzo, Catalogue No. 4721A, Takara Biotechnology Catalogue l991 Vol. l) was inserted and ligated to the ring-opened site thereof by means of T4 DNA ligase. The plasmid contained in the transformant obtained in the same manner as in Example 3 was examined by the digestion with the restriction endonucleases, whereby it was confirmed that a clone having the desired plasmid pBR 9333 (about 4.4 Kbp) having the restriction endonuclease EcoR I and Hind III cleavage sites deleted and having a restriction endonuclease Bgl II cleavage site newly inserted, was obtained.
Then, 5 ~g of plasmid pBR 9333 thus-obtained, was 2051~7~

dissolved in a high salt buffer, in accordance with the method of Example 3, and digested with restriction endonuclease Bgl II (Takara Shuzo) and Pvu II (Takara Shuzo). Then, a DNA fragment of about 2.3 Kbp containing a replication origin was separated and purified by agarose gel electrophoresis (gel concentration: 1%). On the other hand, 5 ~9 of expression vector pKK 223-3 (about 4.6 Kbp) was dissolved in a high salt buffer in the same manner as above and digested with restriction endonuclease BamH I (Takara Shuzo) and Sca I (Takara Shuzo). The digestion reaction with the restriction endonuclease BamH I was conducted by partial digestion for a reaction time of from 5 to 30 minutes by reducing the amount of the added enzyme to a level of about 1/2 of a usual amount. After the digestion treatment, the obtained DNA fragment of about 1.1 Kbp containing tac promoter and rrnBTlT2 terminator was separated and purified by agarose gel electrophoresis in the same manner as above. The DNA fragment of about 1.1 Kbp was inserted and ligated to the previously purified DNA
fragment of about 2.3 Kbp containing a replication origin, by means of T4 DNA ligase in the same manner as described above. The ligated DNA was introduced into competent cells of an E. coli K-12 JM103 strain (obtained from Research Laboratory for Genetic Information of Kyushu University) prepared by a calcium chloride method, in accordance with the method of Example 3. From the 2Q~7~

transformants thus--obtained, a clone having the desired expression vector (about 3.4 Kbp) containing tac promoter was selected, and this expression vector was designated as pKK 101.
(2) Referring to Figure 4, the subsequent step will be described.
Five ~lg of the expression vector pKK 101 obtained in the above step (1) was digested with restriction endonuclease EcoR I and Hind III, in accordance with the above-mentioned method, and a DNA fragment of about 3.4 Kbp containing a replication origin and a transcriptional regulation region, was separated and purified by agarose gel electrophoresis (gel concentration: 1~). Likewise, the plasmid pUA44 (about 3.2 Kbp) containing the human TNF gene obtained in Example 3 was digested with restriction endonuclease EcoR I and Hind III, whereupon a DNA fragment of about 480 bp containing the entire region of a human TNF gene was separated and purified by agarose gel electrophoresis. This DNA fragment containing the entire region of a human TNF gene was inserted and ligated to the DNA fragment of about 3.4 Kbp previously purified from the expression vector pKK 101, by means of T4 DNA ligase in accordance with the above-mentioned method. The ligated DNA was introduced into an E. coli K-12 JM103 strain in accordance with the above-mentioned method. From the transformants thus-obtained, a clone having the desired human TNF expression vector (about 3.9 2~S197~

Kbp) was selected, and this expression vector was designated as pKF 4102.

Cloninq of human TNF N-terminal mutein expression vector pKF 4168 (1) The operation will be described with reference to Figure 5.
The plasmid pUA44 obtained in Example 3 was digested with restriction endonuclease EcoR I and Hind III, in accordance with the above-mentioned method, and a DNA
fragment of the human TNF gene (about 480 bp containing the entire region) was separated and purified by agarose gel electrophoresis. On the other hand, plasmid vector pUCll9 (obtained from Takara Shuzo) for the preparation of a single-stranded plasmid DNA developed by Messinq et al. (Methods in Enzymoloqy, 153, 3 (1987)) was likewise digested with restriction endonuclease EcoR I and Hind III, and a DNA fragment of about 3.2 Kbp containing an intergenic (IG) region was separated and purified by agarose gel electrophoresis. By the presence of this IG
region (intergenic region of M13 phage DNA), the plasmid pUCll9 will, after being infected to a helper phage M13K07, preferentially become a single-stranded DNA and will be enclosed by phage particles and will be discharged out of the microbial cells. The DNA fragment of about 480 bp ,purified as above and containing the entire region of the human TNF gene and the pUCll9 2~51~7~

fragment of about 3.2 Kbp containing the IG region were ligated by means of T4 DNA ligase in accordance with the above-mentioned method, and the ligated DNA was introduced into an E. coli K-12 JM83 strain in accordance with the method of Example 3. From the transformants thus-obtained, a clone having the desired plasmid (about 3.7 Kbp) was selected. This clone was designated as pUCll9-hTNF/JM83, and the plasmid was designated as pUCll9-hTNF.
The plasmid pUC119-hTNF thus-obtained was introduced into competent cells of an E. coli CJ236 strain ~dut , ung~) prepared by a calcium chloride method, in accordance with the method of Example 3, to incorporate uracil into the DNA of the plasmid. The CJ236 strain has a mutation (dut ) in the enzyme dUTPase (deoxyuridine triphosphate-phosphatase) gene, and a competing reaction is thereby caused, whereby it is possible to produce a DNA having uracil partially incorporated instead of thymine. Further, due to the ung~ mutation, it lacks the enzyme uracil N-glycosylase, whereby it is possible to maintain uracil in the DNA. Such CJ236 strain was obtained from Bio-Rad. The clone (pUCll9-hTNF/CJ236) obtained by such introduction was, after infected with helper phage M13K07 (obtained from Takara Shuzo), cultured in a 2 x YT broth (1.6% tryptone, 1% yeast extract and 0.5% NaCl pH 7.6) containing 100 ~g/ml of ampicillin, 70 ~g/ml of Kanamycin and 30 ~g/ml of 2 ~ 7 ~

chloramphenicol, whereby the des:ired single-stranded plasmid DNA (about 3.7 K bases) having uracil introduced was discharged out of the cells in a form enclosed by phage particles. The discharged phage particles were recovered from the supernatant of the broth, and the desired single-stranded plasmid DNA was prepared in accordance with a method for preparing a single-stranded phage DNA.
(2) The operation will be described with reference to Figure 6.
Primer 4168 was designed to introduce a mutation to the human TNF gene using a coding strand oligonucleotide.
Primer 4168 is an oligonucleotide comprising 12 bases with a nucleotide sequence of from the 10th C to the 21st T as shown by SEQ ID NO:10 wherein the 13-15th 5'-ACC-3' is replaced by 5'-GGC-3' and the 16-18th 5'~CCG-3' is replaced by 5'-GAT-3'.
The chemical synthesis and purification of this oligonucleotide was conducted in accordance with the method of Example 2.
The site-directed mutagenesis of the human TNF gene was conducted in accordance with the Bio-Rad system (Muta-GeneTM in vitro mutagenesis kit). Namely, about 0.5 ~g of the primer prepared as above and having the 5'-terminus phosphorylated with T4 polynucleotide kinase inaccordance with the above-mentioned method and about 200 ng of the previously prepared uracil-introduced single-20~1~7~

stranded plasmid DNA (pUCll9-hTNF) were annealed in 10 ~1 of an annealing buffer (20 mM Tris-HCl pH 7.4, 2 mM MgCl2 and 50 mM NaCl) (i.e. heated at 70C followed by gradual cooling). After completion of the annealing, a 1/10 volume of 10 x synthesis buffer (5 mM deoxyribonucleotide triphosphates (dATP, dGTP, dCTP and TTP), 10 mM ATP, 100 mM Tris-HCl pH 7.4, 50 mM MgCl2 and 20 mM DTT) was added thereto, and a double-stranding reaction (37C, 90 minutes) was conducted by means of 1 unit of T4 DNA
polymerase and from 2 to 4 units of T4 DNA ligase. About 8 volumes of TE buffer (10 mM Tris-HCl pH 7.5 and 1 mM
EDTA) was added and the mixture was freezed to stop the reaction. This reaction mixture was applied to competent cells of the E. coli K-12 TGl strain (ung+, obtained from Amersham) prepared by a calcium chloride method, in accordance with the method of Example 3, to introduce the double-stranded DNA.
By the introduction of the hetero double-stranded DNA
into the ung+ strain, the uracil-containing DNA strand as the template was deactivated and not replicated.
(Therefore, the mutation frequency becomes as high as more than 50%.) From the transformants thus-obtained, a clone having a plasmid (about 3.7 Kbp) containing the desired mutein DNA was selected by means of colony hybridization method employing as a probe the primer used for the introduction of mutation. With respect to the selected clone, the nucleotide sequence around the 20~1975 mutation-introduced site of the plasmid was examined by the dideoxy method (F. Sanger: as mentioned above) to confirm that it was modified to the mutein DNA as designed. This plasmid was designated as pUCll9-F4168.
(3) The desired human TNF N-terminal mutein gene obtained by the introduction of mutation was inserted into expression vector pKK 101 having tac promoter in accordance with the method of cloning the human TNF
expression vector of Example 4, to obtain a human TNF N-terminal mutein expression vector. The human TNF N-terminal mutein gene (about 480 bp) was separated and purified after digestion of the plasmid pUCll9-F4168 (about 3.7 Kbp) obtained above with restriction endonuclease EcoR I and Hind III in accordance with the above-mentioned method. The desired human TNF N-terminal mutein expression vector (pKF 4168) was obtained by using as host an E. coli K-12 JM103 in the same manner as in the case of the human TNF expression vector (pKF 4102).
The N-terminal mutein expression vector induces the expression to produce a novel physiologically active polypeptide having the following replacement, in E. coli cells.
Vector pKF 4]68: coding for polypeptide F4168 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is substituted by the amino acid sequence shown by SEQ ID NO:2.

20~1~75 Cloninq of human TNF N-termina _mutein expressior~ vectors EKF 4415, pKF 4416, pKF 4417 and pKF 4418 (1) As in Example 5 (2), except that primer 4415, 4416, 4417 or 4418 was used instead of primer 4168 to obtain a plasmid (about 3.7 Kbp) containing the desired mutein DNA. After confirming by the dideoxy method that the DNA was modified to the mutein DNA as designed, such plasmid was designated as pUCll9-F4415, pUCll9-F4416, pUCll9-F4417 or pUCll9-F4418, respectively.
Primers 4415, 4416, 4417 and 4418 ùsed here were the following oligonucleotides, and their chemical synthesis and purification were conducted in accordance with the method of Example 2.
Primer 4415: an oligonucleotide comprising 24 bases having the nucleotide sequence of from the 7th T to the 30th T as shown by SEQ ID NO:10 wherein the 16-18th 5'-CCG-3' is replaced by 5'-CGT-3' and the 19-21st 5'-AGT-3' is replaced by 5'-GGT-3'.
Primer 4416: an oligonucleotide comprising 27 bases having the nucleotide sequence of from the 1st T to the 18th G as shown by SEQ ID NO:10 wherein 5'-CGTGGTGAT-3' is inserted between the 9th T and the 10th C.
Primer 4417: an oligonucleotide comprising 27 bases having the nucleotide sequence of from the 10th C to the 27th G as shown by SEQ ID NO:10 wherein 5'-CGTGGTGAT-3' is inserted between the 18th G and the l9th A.
Primer 4418: an oligonucleotide comprising 27 bases 20~197~

having the l-9th nucleotide sequence as shown by SEQ ID
NO:10 wherein 5'-CGTGGTGAT-3' is added to the 5'-side of the 1st T and 5'-GAATTCATG-3' is added to the 5'-side thereof.
(2) The desired human TNF N-terminal mutein gene obtained by the introduction of mutation was inserted into expression vector pKK 101 having tac promoter in accordance with the method of cloning a human TNF
expression vector of Example 4 to obtain a human TNF N-terminal mutein expression vector. The human TNF N-terminal mutein gene (about 480 bp) was separa~ed and purified after the digestion of the plasmid pUCll9-F4415, pUCll9-F4416, pUCll9-F4417 or pUCll9-F4418 (about 3.7 Kbp) obtained above, with restriction endonucleases EcoR
I and Hind III in accordance with the above-mentioned method. The desired human TNF N-terminal mutein expression vector pKF 4415, pKF 4416, pKF 4417 or pKF
4418 was obtained by using as the host an E. coli K-12 JM103 strain in the same manner as in the case of the human TNF expression vector (pKF 4102).
The above N-terminal mutein expression vector induces the expression of a novel physiologically active polypeptide having the following replacement in E. coli cells.
Vector pKF 4415: coding for polypeptide F4415 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino 2051~7~

acid sequence shown by SEQ ID NO:3.
Vector pKF 4416: coding for polypeptide F4416 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:4.
Vector pKF 4417: coding for polypeptide F4417 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:5.
Vector pKF 4418: coding for polypeptide F4418 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6.

Cloninq of human TNF N-terminal mutein expression vector pKF 4420 (1) An oligonucleotide having 16 bases of from the 5th C to the 20th G as shown by SEQ ID NO:10 wherein the 13th A is replaced by G, was designed and designated as primer 4104. The chemical synthesis and purification oE
this oligonucleotide were conducted in accordance with the method of Example 2. As in Example 5 (2), except this primer 4104 was used instead of primer 4168 to obtain a plasmid (about 3.7 Kbp) containing the desired mutein DNA. The nucleotide sequence around the mutation-introduced site was examined by the dideoxy method to confirm that the DNA was modified to the mutant DNA as 20~g75 designed, and this plasmid was designated as pUCll9-F4104.
(2) As in Example 5 (1), pUC119-F4104 was used instead of pUCll9--hTNF to obtain the desired single-stranded plasmid DNA. Further, an oligonucleotide having21 bases of from the 46th G to the 66th G as shown by S~Q
ID NO:10 wherein the 56th A is replaced by G, was designed and designated as primer 4226. The chemical synthesis and purification of this oligonucleotide were conducted in accordance with the method of Example 2.
Then, using the single-stranded plasmid DNA of pUCll9-F4104 and primer 4226 prepared above, the site directed mutagenesis of a human TNF mutein gene was conducted in accordance with the method of Example 5 (2) to obtain a plasmid (about 3.7 Kbp) containing the desired mutein DNA. It was confirmed by the dideoxy method that the DNA was modified to the mutein DNA as designed, and this plasmid was designated as pUCll9-F4226.
(3) Using the plasmid pUCll9-F4226 having two restriction endonuclease Xho I cleavage sites obtained in Example 7 (2), an expression vector (designated as pKF
4420) of the N-terminal substituted mutein polypeptide (designated as F4420) was cloned by ligating a chemically synthesized oligonucleotide (double-stranded by annealing) to the N-side of the formed restriction endonuclease Xho I cleavage site. The cloning method 20~1~75 will be described with reference to Figure 7.
Five ~g of plasmid pUCll9-F4226 (about 3.7 Kbp) was dissolved in a high salt buffer, in accordance with the method of Example 3, and digested with restriction endonuclease Xho I (Takara Shuzo) and Hind III, whereupon a DNA fragment of about 420 bp containing F4226 gene having the N-terminal portion deleted, was separated and purified by agarose gel electrophoresis (gel concentration: 1~). On the other hand, an upper (coding) strand (U-4920) and the lower (noncoding) strand (L-4420) of an oligonucleotide encoding an oligopeptide designed for the purpose of substitution at the N-terminal portion of E4226, were chemically synthesized and purified in accordance with the method of Example 2. The upper strand U-4420 is an oligonucleotide having the nucleotide sequence as shown by SEQ ID NO:ll. The lower strand L-4420 is a strand having a sequence complementary to the upper strand U-4420, but this lower strand does not have a sequence portion complementary to the l-4th 5'-AATT-3' of the upper strand U-4420. On the other hand, it is an oligonucleotide having a nucleotide sequence having 5'-TCGA-3' added to the 5'-side of the 5'-terminal G of the lower strand. The two oligonucleotides (each 1 ~g) obtained after purification were phosphorylated at their 5'-termini with T4 polynucleotide kinase in accordance with the method of Example 3, followed by annealing to obtain a double stranded DNA fragment (46 bp). On the 20~137~

other hand, the plasmid vector pECK 101 was digested with restriction endonuclease EcoR I and Hind III in accordance with the method of Example 4, whereupon a DNA
fragment of about 3.4 Kbp containing a replication origin and a transcriptional regulation region, was separated and purified.
The three DNA fragments obtained by the above method were ligated with T4 DNA ligase, in accordance with the method of Example 3, and ligated DNA was introduced into competent cells of E. coli K-12 JM103 strain. From the transformants thus-obtained, a clone having the desired F4420 expression vector pKF 4420 (about 3.9 Kbp) was selected by confirming the digestion pattern with restriction endonuclease EcoR I, Xho I and Hind III and by examining the nucleotide sequence around the N-terminal substituted site of the N-terminal mutein polypeptide.
The N-terminal mutein expression vector cloned in accordance with the above method, induces the expression Of a novel physiologically active polypeptide having the following replacement in E. coli cells.
Vector pKF 4420: coding for polypeptide F4420 having the amino acid sequence as shown by SEQ ID NO:l in the Sequence Listing wherein the 1-8th amino acid sequence is replaced by the amino acid sequence Arg-Gly-Asp.

Cloninq of human TNF N-terminal mutein expression vectors 205197~

pKF 4421 and pKF 4137 Using the plasnlid pUCll9-F4104 having restriction endonuclease Xho I cleavage site obtained in Example 7 (1), a chemically synthesized oligonucleotide (double-stranded by annealing) was ligated to the N-side of the restriction endonuclease Xho I cleavage site, whereby expression vectors (designated as pKF 4421 and pKF 4137) of the N-terminal substituted mutein polypeptides (designated as F4421 and F4137) were cloned.

Five ~g of plasmid pUCll9-F4104 (about 3.7 Kbp) was dissolved in a high salt buffer, in accordance with the method of Example 3, and digested with restriction endonuclease Xho I and Hind III, whereupon a DNA fragment of about 460 bp containing F4104 gene having the N-1~ terminal portion deleted, was separated and purified by agarose gel electrophoresis (gel concentration: 1%). On the other hand, the upper (coding) strand (U-4421 or U-4137) and the lower (noncoding) strand (L-4421 or L-4137) of an oligonucleotide encoding an oligopeptide designed for the purpose of substitution to the N-terminal portion of F4104 were chemically synthesized and purified in accordance with the method of Example 2. The upper strand U-4421 is an oligonucleotide having the sequence shown by SEQ ID NO:12 in the Sequence Listing. Whereas, the lower strand L-4421 is a strand having a sequence complementary to the upper strand U-4421, but has no sequence portion complementary to the l-4th 5'-AATT-3' of 20~97~

the upper strand, and it is an oligonucleotide having a sequence in which 5'-TCGA-3' is added to the 5'-side of the 5'-terminal G of the lower strand. Further, the upper strand U-4137 is an oligonucleotide having the sequence shown by SEQ ID NO:13 in the Sequence Listing.
The lower strand L-4137 is a strand having a sequence complementary to the upper strand U-4137, but has no sequence portion complementary to the l-4th 5'-AATT-3' of the upper strand U-4137, and it is an oligonucleotide having a sequence wherein 5'-TCGA-3' is added to the 5'-side of the 5'-terminal G of the lower strand. The respective upper and lower two oligonucleotides ~each 1 ~g) obtained after the purification were phosphorylated at the 5'-termini by means of T4 polynucleotide kinase, followed by annealing to obtain a double stranded DNA
fragment (34 bp).
On the other hand, plasmid vector pKK 101 was digested with restriction endonuclease EcoR I and Hind III in accordance with the method of Example 4, and a DNA
fragment of about 3.4 Kbp containing a replication origin and a transcriptional regulation region was separated and purified.
The three DNA fragments obtained by the above method were ligated by means of T4 DNA ligase, in accordance with the method of Example 3, and the ligated DNA was introduced into competent cells of E. coli K-12 ~M103 strain. From the transformants thus-obtained, a clone 20~1~7~

having the desired F4421 expression vector pKF 4421 (about 3.9 Kbp) or F4137 expression vector pKF 4137 (about 3.9 Kbp) was selected by confirming the digestion patterns with restriction endonuclease EcoR I, Xho I and Hind III and by examining the nucleotide sequence around the N-terminal substituted site of the N-terminal mutein polypeptide.
The N-terminal mutein expression vector thus-cloned by the above method induces the expression of a novel physiologically active polypeptide having the following replacement in E. coli cells.
Vector pKF 4421: codinq for polypeptide F4421 having the amino acid sequence as shown by SEQ ID NO:l in the Sequence Listing wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:7.
Vector pKF 4137: coding for polypeptide F4137 having the amino acid sequence as shown by SEQ ID NO:l in the Sequence Listing wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:8.

Cloninq of human TNF N-terminal mutein expression vector pKF 4113 A plasmid vector (designated as pSK407) having trp promoter as the promoter, two translation initiation signals (SD sequence) arranged in tandem and rrnBTlT2 terminator as the terminator, was cloned in accordance with the method shown in Figures 9 to 11. Five ~g of 20~75 plasmid vector pGF101 (about 4.3 Kbp, obtained from Osaka University, Facalty of Pharmaceutical Science) was dissolved in a medium salt buffer in accordance with the above-mentioned method and digested by the addition of 10 units of restriction endonuclease Cla I (Takara Shuzo).
The cut DNA fragment was polished by means of T4 DNA
polymerase in accordance with the method of Example 3, and after the ethanol precipitation operation, it was dissolved in a high salt buffer having NaCl added to a NaCl concentration of 175 mM and digested by an addition of 15 units of restriction endonuclease Sal I (Takara Shuzo). A DNA fragment of about 4.0 Kbp was separated and purified by agarose gel electrophoresis (gel concentration: 1~) in accordance with the method of Example 3.
On the other hand, 5 ~g of plasmid pMC1403 (about 9.9 Kbp, obtained from Institute for Virus Research, Kyoto University) developed by Casadaban et al. (J. Bacteriol., 143, 971 (1980)), was digested with restriction endonuclease EcoR I in accordance with the above-mentioned method, followed by polishing and digestion with restriction endonuclease Sal I in the same manner as above, whereupon a DNA fragment of about 6.2 Kbp was separated and purified by agarose gel electrophoresis.
In accordance with the method of Example 3, this DNA
fragment was ligated to the previously purified DNA
fragment by means of T4 DNA ligase, and the ligated DNA

20~1~7~

was introduced into competent cells of an E. coli K-12 HB101 strain (obtained from Institute for Virus Research, Kyoto University) prepared by a calcium chloride method.
From the transformants thereby obtained, a clone having the desired plasmid vector (designated as pSK101) of about 10.2 Kbp containing trp promoter and restriction endonuclease EcoR I and BamH I cleavage sites, was selected.
In each of two tubes, 5 ~g of the plasmid vector pSK101 obtained above was dissolved in a high salt buffer in accordance with the above-mentioned method and digested by an addition of restriction endonuclease EcoR
I and Sal I, and restriction endonuclease BamH I and Sal I, respectively, whereupon DNA fragments of about 4.0 Kbp and about 6.2 Kbp were, respectively, separated and purified by agarose gel electrophoresis. On the other hand, the upper (coding) and lower (noncoding) strands (each 100 ng) of a portable translation initiation site-oligonucleotide (which is referred to simply as SD-ATG
linker and which is an oligonucleotide comprising 21 bases containing a translation initiation signal SD
sequence and a translation initiation codon ATG, obtained from Pharmacia, Catalogue No. 27-4878-01 and 27-4898-01 Pharmacia Molecular Biologicals, 1985 May) were phosphorylated at their 5'-termini and annealed to obtain a double stranded DNA f~agment (21 bp).
The three DNA fragments obtained above were ligated 2 ~ 7 ~

by means of T4 DNA ligase, in accordance with the above-mentioned method, and the ligated DNA was introduced into competent cells of an E. coli K-12 HB101 strain. From the transformants thereby obtained, a clone having the desired plasmid vector (designated as pSK211) of about 10.2 Kbp having the SD-ATG linker inserted downstream of the trp promoter and immediately upstream of the restriction endonuclease BamH I cleavage site, was selected. This plasmid vector has two SD sequences arranged in tandem downstream of the trp promoter.
The following operation was conducted for the purpose of eliminating the restriction endonuclease Sal I
cleavage site of this plasmid vector and introducing a new restriction endonuclease Hind III cleavage site in its vicinity. Five ~g of plasmid vector pSK211 was digested with restriction endonuclease Sal I in accordance with the above-mentioned method and then polished by means of T4 DNA polymerase. The DNA fragment recovered by an ethanol precipitation operation was digested with restriction endonuclease BamH I, whereupon a DNA fragment of about 4.0 Kbp was separated and purified by agarose gel electrophoresis. On the other hand, 5 ~g of plasmid vector pGFK 503-1 (about 5.7 Kbp) cloned by recombination in the same manner as the above-mentioned cloning of pSK211, using plasmid vector pKK223-3 having the tac promoter and SD-ATG linker, etc., was digested with restriction endonuclease Hind III in 20~1 97~

accordance with the above-mentioned method and then polished by means of T4 DNA polymerase. The DNA fragment recovered by an ethanol precipitation operation, was digested with restriction endonuclease BamH I, and a DNA
fragment of about 1~l Kbp was separated and purified by agarose gel electrophoresis.
The two DNA fragments purified above, were ligated by means of T4 DNA ligase, in accordance with the above-mentioned method, and the ligated DNA was introduced into competent cells of an E. coli K-12 HB101 strain. From the transformants thereby obtained, a clone having the desired plasmid vector (designated as pSK301) of about 5.1 Kbp, containing the trp promoter, having the restriction endonuclease Sal I cleavage site deleted, and having a Hind III cleavage site formed anew, was selected.
Five ~g of this plasmid vector pSK301 was dissolved in a low salt buffer in accordance with the above-mentioned method, and the digestion reaction was conducted by an addition of 5 units of restriction endonuclease Bal I (Takara Shuzo). After completion of the reaction, the NaCl concentration was adjusted to 50 mM, and digestion with restriction endonuclease Hind III
was conducted, whereupon a DNA segment of about 4.3 Kbp was separated and purified by agarose gel electrophoresis. On the other hand, 5 ~g of plasmid vector pKK 223-3 was dissolved in a high salt buffer in 20~1~7~

accordance with the above-mentioned method and digested with restriction endonuclease Hind III and Sca I, whereupon a DNA fragment of about 0.8 Kbp was separated and purified by agarose gel electrophoresis.
The two DNA fragments purified above, were ligated by means of T4 DNA ligase, in accordance with the above-mentioned method, and the ligated DNA was introduced into competent cells of an E. coli K-12 HB101 strain. From the transformants thereby obtained, a clone having the desired plasmid vector pSK407 (about 5.1 Kbp) having the rrnBTlT2 terminator located downstream of the trp promoter, was selected.
Then, two oligonucleotides (U-4113 and L-4113) were designed.

U-4113 (SEQ ID NO:14 in the Sequence Listing, number of bases: 32) L-4113 (number of bases: 32) which is complementary to U-4113, but does not have a nucleotide sequence complementary to the l-4th 5'-GATC-3' of SEQ ID NO:14, and on the other hand, has a nucleotide sequence in which 5'-TCGA-3' is added to the 5'-side of G complementary to the 32nd C of SEQ ID NO:14.
The oligonucleotides (1 ~g each) obtained by the chemical synthesis and purification in accordance with the method of Example 2 were phosphorylated at their 5'-termini by means of T4 polynucleotide kinase, followed by annealing, in accordance with the method of Example 3, to 205197~

obtain a double-stranded DNA fragment (32 bp). On the other hand, 5 ~g of plasmid vector pSK407 (about 5.1 Kbp) having the trp promoter and rrnBTlT2 terminater, etc., was dissolved in a high salt buffer in accordance with the method of Example 3 and digested with restriction endonuclease BamH I and Hind III, whereupon a DNA
fragment of about 4.0 Kbp containing a replication origin and a transcriptional regulation region, etc. was separated and purified by agarose gel electrophoresis (gel concentration: 1%). On the other hand, 5 ~g of plasmid pUCll9-E4104 (about 3.7 Kbp) obtained in Example 7 (1), was digested with restriction endonuclease Xho I
and Hind III in the same manner as in Example 8, whereupon a DNA fragment of about 460 bp containing the F4104 gene having the N-terminal portion deleted, was separated and purified (Figure 12).
The three DNA fragments obtained in accordance with the above methods, were ligated by means of T4 DNA
ligase, in accordance with the method of Example 3, and the ligated DNA was introduced into competent cells of an E. coli K-12 HB101 strain. From the transformants thereby obtained, a clone having the desired F4113 expression vector (designated as pKF 4113) of about 4.5 Kbp, was selected by confirming the digestion pattern with restriction endonuclease samH I, Xho I and Hind III
and by examining the nucleotide sequence around the N-terminal addition site of the N-terminal mutein 2~5~97~

polypeptide.
The N-terminal mutein expression vector cloned in accordance with the above method induces the expression of a novel physiologically active polypeptide having the following replacement in E. coli cells.
Vector pKF 4113: coding for polypeptide F4113 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:9.

Cloninq of human TNF N-terminal mutein expression vectors pKF 4601 and pKF 4602 (1) Primers 4291 and 4292 were designed. These primers are oligonucleotides comprising 21 bases having a nucleotide sequence of from the 193th C to the 213th T of SEQ ID NO:10 wherein the 202-204th 5'-CCA-3' is replaced by 5'-GAT-3' in the case of primer 4291 and by 5'-ATG-3' in the case of primer 4292.
The chemical synthesis and purification of these oligonucleotides were conducted in accordance with the method of Example 2. Using such primer 4291 or 4292, a plasmid (about 3.7 Kbp) containing the desired mutant DNA
was obtained in accordance with the method of Example 5 (1) and (2). It was confirmed by the dideoxy method that the DNA was modified to the mutein DNA as designed, and this plasmid was designated as pUCll9-F4291 or pUCll9-F4292. The desired human TNF mutein gene obtained by the 205197~

introduction of mutation, was inserted into expression vector pKK 101 having tac promoter in accordance with the method of cloning a human TNF expression vector of Example 4, to obtain a human TNF mutein expression vector. The human TNF mutein gene (about 480 bp) was separated and purified after digestion of the plasmid pUCll9-F4291 or pUCll9-F4292 (about 3.7 Kbp) obtained above with restriction endonuclease EcoR I and Hind III
in accordance with the above-mentioned method. The desired human TNF mutein expression vector pKF 4291 or pKF 4292 was obtained by using as the host an E. coli K-12 JM103 strain in the same manner as in the case of the human TNF expression vector (pKF 4102).
(2) The operation will be described with reference to Figure 8. Five ~g of the human TNF N-terminal mutein expression vector pKF 4168 (about 3.9 Kbp) obtained in Example 5 was dissolved in a medium salt buffer, in accordance with the method of Example 3, and digested with restriction endonuclease Sac I and Hind III, whereupon a DNA fragment of about 3.5 Kbp containing a replication origin and a transcriptional regulation region, was separated and purified by agarose gel electrophoresis (gel concentration: 1%). On the other hand, 5 ~g of the human TNF mutein expression vector pKF
4291 or pKF 4292 (about 3.9 Kbp) obtained in the above step (1) was digested with restriction endonuclease Sac I
and Hind III in the same manner as above, whereupon a DNA

205~975 fragment of about 360 bp containing a human TNF mutein gene having the N-terminal portion deleted, was separated and purified.
The two DNA fragments obtained by the above methods, were ligated by means of T4 DNA ligase, in accordance with the method of Example 3, and the ligated DNA was introduced into competent cells of an E. coli K-12 JM103 strain. From the transformants thus-obtained, a clone having the desired F4601 or F4602 expression vector pKF
4601 or pKF 4602 (about 3.9 Kbp) was selected by confirming the digestion pattern with restriction endonuclease Sac I and Hind III and by examining the nucleotide sequence around the replaced sites derived from the mutein polypeptide.
The N-terminal mutein expression vector cloned in accordance with the above method, induces the expression of a novel physiologically active polypeptide having the following replacements in E. coli cells.
Vector pKF 4501: coding for polypeptide F4601 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 68th Pro is replaced by Asp.
Vector pKF 4602: coding for polypeptide F4602 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 68th Pro is 20~1975 replaced by Met.
Host E. coll cells having the above expression vectors produce polypeptides showing antitumor activities. This was confirmed by a test in which a supernatant fraction obtained after the centrifugal separation of a suspension of sonicated E. coli cells, was tested in accordance with the method of Example 14 given hereinafter.

Cloninq of human TNF N-terminal mutein expression vectors pKF 4607, pKF 4608, pKF 4626, pKF 4627, pKF 4634, pKF
4635, pKF 4609, pKF 4610, pKF 4628, pKF 4629, pKF 4638 and pKF 4639 (1) Primers 4268, 4150, 4222, 4267, 4123 and 4223 were designed. Primer 4268 is an oligonucleotide comprising 30 bases having a nucleotide sequence of from the 301st A to the 333rd C of SEQ ID NO:10 wherein the 316-318th 5'-GGC-3' is deleted. On the other hand, other primers are oligonucleotides having 21 bases having a nucleotide sequence of from the 307th A to 327th C of SEC
ID NO: 10 wherein the 316-318th 5'-GGC-3' is replaced by 5'-TGG-3' in the case of primer 4150, by 5'-CCC-3' in the case of primer 4222, by 5'-GCT-3' in the case of primer 4267, by 5'-GAC-3' in the case of primer 4123 and by 5'-CGC-3' in the case of primer 4223.
The chemical synthesis and purification of these oligonucleotides were conducted in accordance with the 20~1975 method of Example 2. Using each of these primers, a plasmid (about 3.7 Kbp) containing the desired mutant DNA
was obtained in accordance with the method of Example 5 (1) and (2). It was confirmed by the dideoxy method that the DNA was modified to the mutein DNA as designed, and this plasmid was designated as pUC119-F4268, pUCll9-F4150, pUCll9-F4222, pUCll9-F4267, pUC119-F4123 or pUC119-F4223. The desired human TNF mutein gene obtained by the introduction of mutation, was inserted into expression vector pKK 101 having tac promoter in accordance with the method of cloning a human TNF
expression vector of Example 4, to obtain a human TNF
mutein expression vector. The human TNF mutein gene (about 480 bp) was separated and purified after digestion Of the plasmid (about 3.7 Kbp) obtained above with restriction endonuclease EcoR I and Hind III in accordance with the above-mentioned method. The desired human TNF mutein expression vector pKF 4268, pECF 4150, pKF` 4222, pKF 4267, pKF 4123 or pKF 4223 (about 3.9 Kbp) was obtained by using as the host an E. coli K-12 JM103 strain in the same manner as in the case of the human TNF
expression vector (pKF 4102).
(2) In accordance with the method of Example 10 (2), 5 ~g of the human TNF N-terminal mutein expression vector pKF 4168 (about 3.9 Kbp) obtained in Example 5 was digested with restriction endonuclease Sac I and Hind III, whereupon a DNA fragment of about 3.5 Kbp containing 20~1 975 a replication origin and a transcriptional regulation region, was separated and purified.
On the other hand, 5 ~g of the human TNF mutein expression vector pKF 4268, pKF 4150, pKF 4222, pKF 4267, pKF 4123 or pKF 4223 obtained in the above step (1) was digested with restriction endonuclease Sac I and Hind III
in the same manner as above, whereupon a DNA fragment of about 360 bp containing a human TNF mutein gene having the N-terminal portion deleted, was separated and purified.
The two DNA fragments obtained by the above methods, were ligated by means of T4 DNA ligase, in accordance with the method of Example 3, and the ligated DNA was introduced into competent cells of an E. coli K-12 JM103 strain. From the transformants thus-obtained, a clone having the desired expression vector pKF 4607, pKF 4608, pKF 4626, pKF 4627, pKF 4634 or pKF 4635 (about 3.9 Kbp) for F4607, F4608, F4626, F4627, F4634 or F4635 was selected by confirming the digestion pattern with restriction endonuclease Sac I and Hind III and by examining the nucleotide sequence around the replaced sites derived from the mutein polypeptide.
The N-terminal mutein expression vector cloned in accordance with the above method, induces the expression of a novel physiologically active polypeptide having the following replacements in E. coli cells.
Vector pKF 4607: coding for polypeptide F4607 having 7 ~

the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 106th Gly is deleted.
Vector pKF 4608: coding for polypeptide F4608 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 106th Gly is replaced by Trp.
Vector pKF 4626: coding for polypeptide F4626 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 106th Gly is replaced by Pro.
Vector pKF 4627: coding for polypeptide F4627 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 106th Gly is replaced by Ala.
Vector pKF 4634: coding for polypeptide F4634 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 106th Gly is replaced by Asp.
Vector pKF 4635: coding for polypeptide F4635 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino 20~197~

acid sequence shown by SEQ ID NO:2, and the 106th Gly is replaced by Arg.
Host E coli cells having the above expression -vectors produce polypeptides showing antitumor activities. This was confirmed by a test in which a supernatant fraction obtained after the centrifugal separation of a suspension of sonicated E. coli cells, was tested in accordance with the method of Example 14 given hereinafter.
(3) Five ~g of the human TNF N-terminal mutein expression vector pKF 4418 (about 3.9 Kbp) obtained in Example 6 was dissolved in a medium salt buffer, in accordance with the method of Example 3, and digested with restriction endonuclease Sac I and Hind III, whereupon a DNA fragment of about 3.5 Kbp containing a replication origin and a transcriptional regulation region, was separated and purified by agarose gel electrophoresis (gel concentration: 1%). On the other hand, 5 ~g of the human TNF mutein expression vector pKF
4268, pKF 4150, pKF 4222, pKF 4267, pKF 4123 or pKF 42Z3 obtained in the above step (1) was digested with restriction endonuclease Sac I and Hind III in the same manner as above, whereupon a DNA fragment of about 360 bp containing a human TNF mutein gene having the N-terminal portion deleted, was separated and purified.
The two DNA fragments obtained by the above methods, were ligated by means of T4 DNA ligase, in accordance with the method of Example 3, and the ligated DNA was introduced into competent cells of an E. coli K-12 JM103 strain. E'rom the transformants thus~obtained, a clone having the desired expression vector pKF 4609, pKF 4610, pKF 4628, pKF 4629, pKF 4638 or pKF 4639 (about 3.9 Kbp) for F4609, F4610, F4628, F4629, F4638 or F4639 was selected by confirming the digestion pattern with restriction endonuclease Sac I and Hind III and by examining the nucleotide sequence around the replaced sites derived from the mutein polypeptide.
The N-terminal mutein expression vector cloned in accordance with the above method, induces the expression of a novel physiologically active polypeptide having the following replacements in E. coli cells.
Vector pKF 4609: coding for polypeptide F4609 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 106th Gly is dele'ed.
Vector pKF 4610: coding for polypeptide F4610 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 106th Gly is replaced by Trp.
Vector pKF 4628: coding for polypeptide F4628 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 106tn Gly is replaced by Pro.
Vector pKF 4629: coding for polypeptide F4629 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 106th Gly is replaced by Ala.
Vector pKF 4638: coding for polypeptide F4638 having the amino acid sequence as shown by SEQ ID NO:1 wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 106th Gly is replaced by Asp.
Vector pKF 4639: coding for polypeptide F4639 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 106th Gly is replaced by Arg.
Host E. coli cells having the above expression vectors produce polypeptides showing antitumor acti~ities. This was confirmed by a test in which a supernatant fraction obtained after the centrifugal separation of a suspension of sonicated E. coli cells, was tested in accordance with the method of Example 14 given hereinafter.

Cloninq of human TNF N-terminal mutein expression vectors pKF 4611, pKF 4612, pKF 4613, pKF 4614, pKF 4615, pKE`

20~1975 4642, pKF 4643, pKE' 4644, pKE 4645 and pKF 4646 (1) Primers 4134, 4391, 4392, 4409 and 4410 were desiyned. These primers are oligonucleotides comprising 21 bases having a nucleotide sequence of from the 76th T
to the 96th T of SEQ ID NO:10 wherein the 85-87th 5'-CGC-3' is replaced by 5'-CAA-3' in the case of primer 4134, by 5'-AAG-3' in the case of primer 4391, by 5'-GAC-3' in the case of primer 4392, by 5'-GTC-3' in the case of primer 4409 and by 5'-CTC-3' in the case of primer 4410.
The chemical synthesis and purification of these oligonucleotides were conducted in accordance with the method of Example 2.
(2) A desired single-stranded plasmid DNA was prepared by using pUCll9-F4168 obtained in Example 5 instead of pUCll9-hTNF in Example 5 (1). Then, using this uracil-containing single-stranded plasmid DNA of pUCll9-F4168 and primer 4134, 4391, 4392, 4409 or 4410 purified in the above step (1), the site-directed mutagenesis was conducted in accordance with the method Of Example 5 (2) to obtain a plasmid (about 3.7 Kbp) containing DNA having the desired mutation introduced.
It was confirmed by the dideoxy method that the mutation was introduced as designed, and this plasmid was designated as pUCll9-F4611, pUCll9-F4612, pUCll9-F4613, pUCll9-F4614 or pUCll9-F4615. The desired human TNF N-terminal mutein gene obtained by the introduct;on of mutation, was inserted into expression vector pKK 101 having tac promoter in accordance with the method of cloning a human TNF expression vector of Example 4, to obtain a human TNF N-terminal mutein expression vector.
The human TNF N-terminal mutein gene (about 480 bp) was separated and purified after digestion of the pla~mid pUCll9-F4611, pUCll9-F4612, pUCll9-F4613, pUCll9-F4614 or pUCll9-F4615 (about 3.7 Kbp) obtained above with restriction endonuclease EcoR I and Hind III in accordance with the above-mentioned method. The desired human TNF N-terminal mutein expression vector pKF 4611, pKF 4612, pKF 4613, pKF 4614 or pKF 4615 was obtained by using as the host an E. coli K-12 JM103 strain in the same manner as in the case of the human TNF expression vector (pKF 4102).
The N-terminal mutein expression vector cloned in accordance with the above method, induces the expression of a novel physiologically active polypeptide having the following replacements in E. coli cells.
Vector pKF 4611: coding for polypeptide F4611 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 29th Arg is replaced by Gln.
Vector pI~F 4612: coding for polypeptide F4612 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 29th Arg is 20~1975 replaced by Lys.
Vector pKF 4613: coding for polypeptide F4613 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 29th Arg is replaced by Asp.
Vector pKF 4614: coding for polypeptide F4614 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:2, and the 29th Arg is replaced by Val.
Veetor pKF 4615: coding for polypeptide F4615 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino aeid sequenee is replaeed by the amino aeid sequenee shown by SEQ ID NO:2, and the 29th Arg is replaeed by Leu.
Host E. coli eells having the above expression veetors produee polypeptides showing antitumor aetivities. This was eonfirmed by a test in whieh a supernatant fraetion obtained after the eentrifugal separation of a suspension of sonieated E. eoli eells, was tested in aceordance with the method of Example 14 given hereinafter.
(3) A uracil-eontaining single-stranded plasmid DNA
was prepared using pUC119-F4418 obtained in Example 6 instead of pUCll9-F4168 in the above step (2), and the site-directed mutagenesis was conducted in the same 2~51975 manner as in the above step (2) to obtain a plasmid containing DNA having the desirecl mutation introduced, i.e. p~C119-F4642, pUCll9-F4643, pUCll9-F4644, pUCll9-F4645 or pUC119-F4646 (about 3.7 Kbp). Using the plasmid containing the desired human TNF N-terminal mutein gene (about 480 bp) obtained as above, the desired human TNF
N-terminal mutein expression vector pKF 4642, pKF 4643, pKF 4644, pKF 4645 or pKF 4646 (about 3.9 Kbp) was cloned in the same manner as in the above step (2). In this operation, an E. coli K-12 JM103 strain was used as the host.
The N-terminal mutein expression vector cloned in accordance with the above method, induces the expression of a novel physiologically active polypeptide having the following replacements in E. coli cells.
Vector pKF 4642: coding for polypeptide F4642 having the amino acid sequence as shown by SEQ ID NO:l wherein the 1-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 29th Arg is replaced by Gln.
Vector pKF 4643: coding for polypeptide F4643 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 29th Arg is replaced by Lys.
Vector pKF 4644: coding for polypeptide F4644 having the amino acid sequence as shown by SEQ ID NO:l wherein ~0~1~75 the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 29th Arg is replaced by Asp.
Vector pKF 4645: coding for polypeptide F4645 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 29th Arg is replaced by Val.
Vector pKF 4646: coding for polypeptide F4646 having the amino acid sequence as shown by SEQ ID NO:l wherein the l-8th amino acid sequence is replaced by the amino acid sequence shown by SEQ ID NO:6, and the 29th Arg is replaced by Leu.
Host E. coli cells having the above expression vectors produce polypeptides showing antitumor activities. This was confirmed by a test in which a supernatant fraction obtained after the cen-trifugal separation of a suspension of sonicated E. coli cells, was tested in accordance with the method of Example 14 given hereinafter.

Expression of human TNF Polypeptide and human TNF N-terminal mutein polypeptide by E. coli and purification E. coli K-12 JM103 strains having the human TNF
expression vector (pKF 4102) obtained in Example 4 and the human TNF N-terminal mutein expression vectors (pKE' 4168, pKF 4415, pKF 4416, pKF 4417, pKF 4418, pKF 4420, 2051~7~

pKF 4421, pKF 4137~ pKF 4601, pKF 4609 and pKF 4639) obtained in E~amples 5, 6, 7, 8, 10 and 11 were, respectively, inoculated to 20 ml of a M9 culture medium (0.6% Na2HPO4, 0.3~ KH2PO4, 0.05% NaCl, 0.1% NH4Cl, 2 mM
MgSO4, 0.2% glucose and 0.1 mM CaCl2) containing from 25 to 50 ~g/ml of ampicillin and 0.001% of vitamin Bl and cultured with shaking at 37C for 18 hours. Twenty ml of each cultured solution was added to 1 e of the above culture medium, followed by cultivation with shaking at 37C for from 2 to 3 hours. Then, isopropyl-~-D-thiogalactopyranoside (IPTG) was added so that the final concentration would be 1 mM, and the culturing was continued with shaking for a further 18 hours at 37C.
An E. coli K-12 HB101 strain having the human TNF N-terminal mutein expression vector (pKF 4113) obtained inExample 9, was inoculated to 20 ml of a M9C~ culture medium (0.6% Na2HPO4, 0.3~ KH2PO4, 0.05% NaCl, 0.1% NH4Cl, 2 mM MgSO4, 0.2% glucose, 0.1 mM CaC12 and 0.2% casamino acid) containing from 25 to 50 ~g/ml of ampicillin, 0.001% of vitamin Bl and 5 ~g/ml of tryptophan, and cultured at 37~C for 18 hours. Twenty ml of this cultured solution was added to 1 e of the above culture medium not containing 5 ~g/ml of tryptophan, and the culturing was conducted with shaking at 37C for 18 hours.
The E. coli cells were recovered by a centrifugal separation, then the cells were washed by means of a TP

20~7~

buffer (10 mM Tris-HCl pH 8.0 and 100 ~M PMSF). Af~er washing, the cells were suspended in the TP buffer in an amount of 10 volume (ml) per wet weight (g) of the cells, and the suspension was sonicated by means of a sonicator (Ultrasonic Proccesor, Model W-225 (Heat Systems, Ultrasonics, Inc.)). The obtained suspension was subjected to centrifugal separation, and the debris was removed, and the supernatant fraction was recovered. The purification process subsequent to this sonicating treatment, was conducted mainly at a low temperature (0 to 4C).
This supernatant was filtered by a 0.45 ~m filter and then fractionated by anion exchange chromatography ~column size: ~ 2.5 x 1.5 cm, flow rate: 0.5 ml/min) using Sepabeads FP-DA13 (Mitsubishi Chemical Industries Ltd.), whereupon an active fraction was recovered through identifying by SDS-polyacrylamide gel electrophoresis which will be described hereinafter and by determining the presence or absence of the activity in accordance with the method of Example 14 using L929 cells. For elution, TP buffer containing NaCl was employed, and the NaCl concentration was stepwise increased from 0.05M to O.lM, 0.2M and 0.5M. The human TNF N-terminal mutein F4639 was eluted with 0.05M NaCl. The human TNF (1) was eluted with O.lM NaCl, the human TNF (2) and the human TNF N-terminal muteins F4415, F4417, F4418, F4420, F4601 and F4609 were eluted with 0.2M NaCl, and the human TNF

2~197~

N-terminal mutein F4168 was eluted with 0.5M NaCl.
Further, in order to remove endotoxin, etc. derived from E. coli cells, treatment with nucleic acid endotoxin removing agent C-9 (manufactured by Kurita Water Industry Ltd. and sold by Dainippon Pharmaceutical Co., Ltd.) was conducted in accordance with the attached manual. Thus, partially purified samples of the human TNF polypeptides and the human TNF N-terminal mutein polypeptides were obtained.
Using these samples, evaluation of the antitumor activities and evaluation of the effects to experimental lung metastasis were conducted in Examples 14, 15 and 16.
With respect to the N-terminal mutein polypeptides F4416, F4421 and F4137, no active fraction was obtained probably because they are unstable in the host E. coli K-12 JM103 strain used, and likewise with respect to F4113, no active fraction was obtained probably because it is unstable in the host E. coll K-12 HB101 strain used.
However, it may be possible to obtain the active fractions by using other host cells.
The above samples were filtered by a 0.20 ~m filter, and then subjected to anion exchange chromatography using Mono Q (registered trademark) tHR 10/10 and HR 5/5) prepacked column (manufactured by Pharmacia LKB
Biotechnology) under the control by a FPLC system and eluted with TPQ buffer (20 mM Tris-HCl pH 8.0 and 10 ~M
PMSF) containing NaCl, whereupon an active fraction was 20~197~

recovered through identifying by SDS-polyacrylamide gel electrophoresis which will be described hereinafter and by determining the presence or absence of the activity in accordance with the method of Example 14 employing L929 cells. The procedure of elution was conducted in accordance with the following program under the control by a FPLC system. The third step was repeated a ~ew times until a single band was obtained by the SDS-polyacrylamide gel electrophoresis, in order to increase the purity.
First step: Mono Q (registered trademark) (HR 10/10) column was used (flow rate: 4 ml/min) 0-5 minutes: 0-0.2M NaCl linear gradient in concentration 5-16 minutes: 0.2M NaCl 16-20 minutes: 0.2-0.5M NaC1 linear gradient in concentration 20-24 minutes: 0.5M NaC1 The fractionation results (NaC1 concentration and retention time) of the active fractions in accordance with the above method were as follows: 0.2M, 6.6 minutes in the case of human TNF (1); 0.2M, 5.6 minutes in the case of human TNF (2); 0.2M, 6.4 minutes in the case of human TNF N-terminal mutein F4168; 0.2M, 7.8 minutes in the case of human TNF N-terminal mutein F4415; 0.2M, 5.4 minutes in the case of human TNF N-terminal mutein F4417;
0.2M, 5.4 minutes in the case of human TNF N-terminal 20~975 mutein F4418; 0.18M, 4.1 minutes in the case of human T~F
N-terminal mutein F4420; 0.2M, 7.0 minutes in the case of human TNF N-terminal mutein F4601; 0.2M, 5.0 minutes in the case of human TNF N-terminal mutein F4609; and 0.14M, 3.1 minutes in the case of human TNF N-terminal mutein F4639.
Second step: Mono Q (registered trademark) (HR 5/5) column was used (flow rate: 1 ml/min) 0-2.5 minutes: 0-0.2M NaCl linear ~radient in concentration 2.5-8 minutes: 0.2M NaCl 8-10 minutes: 0.2-0.5M NaCl linear gradient in concentration 10-12 minutes: 0.5M NaCl The fractionation results (NaC1 concentration and retention time) of the active fractions in accordance with the above method were as follows: 0.2M, 3.7 minutes in the case of human TNF (1); 0.2M, 4.1 minutes in the case of human TNF (2); 0.2M, 3.9 minutes in the case of human TNF N-terminal mutein F4168; 0.2M, 6.0 minutes in the case of human TNF N-terminal mutein F4415; 0.2M, 3.9 minutes in the case of human TNF N-terminal mutein F4417;
0.2M, 3.3 minutes in the case of human TNF N-terminal mutein F4418; 0.2M, 3.2 minutes in the case of human TNF
N-terminal mutein F4420; 0.2M, 4.9 minutes in the case of human TNF N-terminal mutein F4601; 0.2M, 3.2 minutes in the case of human TNF N-terminal mutein F4609; and flow 20~1~7~

through in the case of human TNF N-terminal mutein F4639.
Third step: Mono Q (registered trademark) (HR 5/5) column was used (flow rate: 1 ml/min) 0-6 minutes: 0-0.15M NaCl linear gradient in concentration 6-11 minutes: 0.15-0.2M NaCl linear gradient in concentration 11-13 minutes: 0.2-0.5M NaCl linear gradient in concentration 13-15 minutes: 0.5M NaCl The fractionation results (NaCl concentration and retention time) of the active fractions in accordance with the above method were as follows: 0.16M, 6.5 minutes in the case of human TNF (1); 0.16M, 6.5 minutes in the case of human TNF (2); 0.17M, 6.7 minutes in the case of human TNF N-terminal mutein F4168; 0.16M, 6.4 minutes in the case of human TNF N terminal mutein F4415; 0.16M, 6.5 minutes in the case of human TNF N-terminal mutein F4417;
0.16M, 6.2 minutes in the case of human TNF N-terminal mutein F4418; 0.15M, 5.6 minutes in the case of human TNF
N-terminal mutein F4420; O.l9M, 9.8 minutes in the case of human TNF N-terminal mutein F4601; 0.15M, 5.7 minutes in the case of human TNF N-terminal mutein F4609; and flow through in the case of human TNF N-terminal mutein Thus, purified samples of human TNF polypeptides and human TNF N-terminal mutein polypeptides were obtained.

20~97~

Using these samples, evaluation of the antitumor activities was conducted in the following Example 14.
During the above purification and with respect to the purified samples, SDS-polyacrylamide gel electrophoresis was conducted to confirm the expression and purification of the human TNF polypeptides and the human TNF N-terminal mutein polypeptides. Each sample was added in a Laemmli's sample buffer (62.5 mM Tris--HCl pH 6.8, 2% SDS, 0.01% BPB and 10% glycerol) containing 10 mM of DTT, and electrophoresis was conducted in accordance with the method of Laemmli (Nature, 227, 680 (1970)) using a 15%
separation gel. After completion of the electrophoresis, the protein in the separation gel was confirmed by staining it with Coomassie Brilliant Blue. Some of the results are shown in Figures 13 and 14. The expression quantities by the respective expression vectors for the human TNF polypeptides and the human TNF N-terminal mutein polypeptides for which active fractions were recovered, were substantially equal, and when the expression efficiency was calculated by subjecting the obtained stained gels to a chromatoscanner (CS-920 Model, manufactured by Shimadzu Corporation), it was found to be about 20% of the total cell proteins of E. coli.
Further, each of the finally purified samples showed a single band in the obtained stained gel. From the migration positions, the molecular weights of the human TNF polypeptides and the human TNF N-terminal mutein 2~5~97~

polypeptides were calculated and shown in Table 1.
As one of the physical properties of proteins, isoelectric points of the human TNF polypeptides and the human TNF N-terminal mutein polypeptides were measured by an isoelectric focusing method using Ampholine (manufactured by l,KB), and the results thereby obtained are shown in Table 1.

~0~1~75 Table 1 Table 1 (1) Isoelectric points ancl molecular weights of human TNF polypeptide and human TNF N-terminal mutein polypeptide Polypeptide Isoelectric Molecular weight (Kd) point Human TNF 5.6 17.0 (1) F4168 5.3 17.0 Table 1 (2) Isoelectric points and molecular weights of human TNF polypeptide and human TNF N-terminal mutein polypeptides Polypeptide Isoelectric Molecular weight (Kd) point Human TNF 5.6 17.0 (2) F4415 6.5 17.0 F4417 5.6 17.0 2G F4418 5.6 17.5 F4420 6.5 16.5 F4601 5.2 17.0 F4609 5.6 17.5 F4639 6.4 17.5 20~197~

Example 14 Evaluation of antitumor activities in vitro With respect to the partially purified samples and finally purified samples of the human TNF polypeptides and the human TNF N-terminal mutein polypeptides obtained in Example 13, cell lytic activities against fibroblast cells (L929 (ATCC CCLl) derived from connective tissues of mouse), were determined in accordance with the method of Aqqarwal et al. (J. Biol. Chem., 260, 2345 (1985)).
Namely, L929 cells were seeded on a 96-well microplate for tissue culture (manufactured by Corning) in an amount of 3 x 104 cells/0.1 ml/well and cultured overnight at 37C in the presence of 5% carbon dioxide gas. As the culture medium, Dulbecco's modified Eagle's minimum essential medium (DME medium, manufactured by Sigma) containing 10% fetal calf serum, was used. On the next day, the medium was changed to the above culture medium having Actinomycin D added to a final concentration of 1 ~g/ml. Each sample diluted stepwisely by this culture medium, was applied to the respective wells (total amount of the medium: 0.1 ml). After culturing for further 20 hours, live cells attached to the plate were stained with a 0.5% Crystal Violet solution (0.5% Crystal Violet/20%
methanol) (at room temperature for 15 minutes). The plate having stained cells was thoroughly washed with a phosphate buffer PBS (10 mM Na-K phosphates pH 7.4, 0.8%
NaCl and 0.02~ KCl) containing 1 mM of CaCl2 and 1 mM of 20~1975 MgCl2, and then Crystal Violet remained on the plate was extracted with 0.1 ml of a O.OlN ~Cl solution containing 30% ethanol, and then the absorbance (492 nm) was measured by an EIA reader (Model 2550, manufactured by Bio-Rad). This absorbance corresponds to the number of live cells. Therefore, the final dilution ratio of a sample at a well showing the absorbance corresponding to a 50% value of the absrobance of the well non-treated by the sample was obtained, and the reciprccal number of this dilution ratio of the sample is defined as the number of units per 1 ml of the sample (units/ml).
To calculate the specific activities (units/mg-protein) of the respective samples from the cell lytic activities (units/ml) against L929 obtained in accordance with the above method, the quantitative analysis of the proteins of the respective samples was conducted. The quantitative analysis was conducted in accordance with a Bradford method (Anal. Biochem , 72, 248 (1976)), whereby the protein concentration (mg/ml) was obtained by using bovin serum albumin (sSA) as the standard sample. From these results, the specific activities were calculated with respect to the human TNF
polypeptide samples and the human TNF N-terminal mutein polypeptide samples and are shown in Table 2.

20~197~

Table 2 Table 2 (1) Cell lytic activities against L929 of human TNF polypeptide and human TNF N-terminal mutein polypeptide Specific activity (units/mq-protein) Polypeptide Partially purified Finally purified sample sample Human TNF 2.7 x 107 8.0 x 107 (1) F4168 4.0 x 106 3.2 x 107 Table 2 (2) Cell lytic activities against L929 of human TNF polypeptide and human TNF N-terminal mutein polypeptides Specific activity (units/mq-protein) Polypeptide Partially purified Finally purified sample sample Human TNF 1.2 x 107 2.0 x 107 (2) F4415 3.5 x 106 1. 7 x 107 F4417 1.2 x 107 3.3 x 107 F4418 1.3 x 107 2.1 x 107 F4420 3.0 x 106 2.3 x 107 F4601 1.4 x 1o6 2.5 x 106 F4609 3.0 x 107 F4639 3.0 x 107 2~51~7~

From the above Table 2, it is apparent that the human TNF N-terminal mutein polypeptides of the present invention have cell lytic activities, against fibroblast cells L929 derived from connective tissues of mouse, similar to that of the human TNF.

Evaluation of antitumor activities in vivo With respect to the partially purified samples of the human TNF polypeptides and the human TNF N-terminal mutein polypeptides obtained in Example 13, the antitumor activities against a Meth A fibrosarcoma were determined.
The test was conducted in such a manner that 1 x 106 cells/0.2 ml of Meth A fibrosarcoma cells (obtained from Sasaki Institutes, Sasaki Foundation) suspended in a saline were subcutaneously transplanted to the side part of the back of a BALB/C mouse (male, five weeks old, Charles River), and eight days later, after confirming that the tumor diameter reached a level of from 6 to 10 mm, a sample (0.2 ml/mouse) diluted stepwise with a saline was intravenously administered in the tail vein.
The lethal dose was taken as the maximum dose, and samples of various doses were prepared by stepwise dilution.
For about two weeks after the administration, observation of tumor growth, etc. was continued. With respect to the tumor growth, the tumor volume 205~97~

ab2/2:
a = long diameter of the tumor ~ b = short diameter of the tumor J
was measured, and the tumor volume ratio of the tumor volume after administration to the tumor volume on the day of administration of the sample (O day) was obtained, whereby the number of days from O da~ when the tumor volume ratio became 2 or 5 (D2 or D5) was calculated.
Then, the ratio to the control group (to which the saline was administered) was calculated, and the D2% control value and the D5% control value were obtained. The larger the values, the lower the tumor growing ability, i.e., the higher the antitumor activities.
The results obtained in the above manner are shown in Tables 3 and 4.

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2051~75 _ ~, ~o __C o co a~ ~ ~ a~ c~ ~r In r) ~r m Cl~ ~ Lr ~ C~ CO
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ra ,~ ,~ r~ o o r~ o o ~ o o r~ o o r~ o o ~ o o ~o\
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E~ O ~ r~ r~ n r~ ~ r~
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o ~ n u~ O O O O O O O O O O O O O O O O O O
U~ ~ o ~, ~ ~ ~ ~ ~ ~, ~ ~ ~ ~. ~ ~, ~ V ~ X X X X X X X X X X X X X X X X X X
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From Tables 3 and 4, it is evident that the human TNF
N-terminal mutein polypeptides of the present invention have antitumor activities, against Meth A fibrosarcoma transplanted to mouse, similar to that of the human TNF.

Effects aqainst lunq metastasis of tumor By cloning B16F10 mouse melanoma cells (obtained from School of Medicine, Chiba University) by the following method, a clone showing a high level of metastasis to the lung was produced. Namely, 2 x 104 cells/0.2 ml of B16F10 cells suspended in an Eagle's minimum essential medium (MEM medium, manufactured by Nissui Pharmaceutical Co., Ltd.), were injected into the tail vein of a C57BL/6 NCrj mouse (female, six weeks old, Charles River), and 14 days later, the lung was taken out. After washing the lung with a DME culture medium, one of metastatic nodules having a diameter of about 1 mm formed on the surface of the lung was sucked by a 26 G injection needle-attached syringe (manufactured by Termo) and suspended in 1 ml of the DME medium and cultured on a DME medium-containing soft agar containing 10% of fetal calf serum at 37C in the presence of 5% carbon dioxide gas to form a colony.
This colony formation method was conducted in accordance with the method disclosed in "Tissue Culturing Techniques" (p. 35-36, 1984, compiled by Japan Tissue Culture Association, Asakura Shoten). Ten to twelve days later, when the colony diameter reached a level of from 1 20~197a to 2 mm, the colony was sucked by a Pasteur pipet and cultured in a DME medium containing 10% of fetal calf serum. After the culturing, the proliferated cells were adjusted to a cell concentration of 2 x 10~ cells/0.2 ml again by using the MEM medium and injected into the tail vein of a C57BL/6 NCrj mouse in the same manner as above.
Fourteen days later, the lung was taken out, and one of metastatic nodules was isolated and cultured in the same manner as above. Such operation was repeated five times to obtain a clone (designated as B16F10/L5) resulting in a high level of metastasis to the lung.
The B16F10/L5 cells in a logarithmic phase cultured in the DME medium containing 10% of fetal calf serum by means of a dish for tissue culture having a diameter of 10 cm (Coning (registered trademark), manufactured by Iwaki Glass Co., Ltd.), were washed once with a phosphate buffer PBS in a state attached to the dish, and 5 ml of the MEM medium was added, followed by pipetting to obtain a cell suspension. The cells were collected by centrifugal separation and again suspended in 2 ml of the MEM medium. On the other hand, the partially purified samples of the human TNF polypeptides and the human TNF
N-terminal mutein polypeptides obtained in Example 13 were diluted with the MEM medium to prescribed concentrations (the doses at which the antitumor effects were observed in the antitumor test in Example 15, were used as the doses for this test).

20~1~7~

To this solution, the previously prepared B16~10/L5 cell suspension was added to prepare a cell suspension containing 2 x 104 cells/0.2 ml of each partially purified sample solution. This cell suspension (0.2 ml/mouse) was injected into the tail vein of a C57BL/6 NCrj mouse (female, six weeks old). To the control group, only L16F10/L5 cells were injected. Fourteen days after the injection, the lung was taken out, and the number of metastatic nodules on the lung surface was counted.
The results obtained in the above manner are shown in Tables 5 and 6.

~0~1975 _ __.
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v a oI x x o ~

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2051~7~

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~0 E~ ~ Z 4Z.,1 q) ~ ~4 r~ ro E-l ~ '-I ~ ~a C ~
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Q E4~ 1~ Z ,~ _ v v 2~51975 From Tables 5 and 6, it is evident that while the human TNF polypeptide and the human TNF mutein polypeptide have activities to promote experimental lung metastasis, the human TNF N-terminal mutein polypeptide of the present invention, having an Arg-Gly-Asp sequence introduced in the vicinity of the N-terminus, does not promote the experimental lung metastasis.
According to the present invention, a novel human TNF
N-terminal mutein is provided which has substantially the same antitumor activities as the human TNF or a mutein thereof and which, on the other hand, does not have an activity to promote tumor metastasis observed with the human TNF or its mutein, by replacing, on the human TNF
or its mutein, the amino acid sequence of from the 1st Ser to the 8th Asp of SEQ ID NO:l in the Sequence Listing or the corresponding amino acid sequence of the human TNF
mutein with an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and having from 3 to 16 amino acids.
Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.

2051~75 SEQUENCE l,ISTING

SEQ ID NO:l:
SEQUENCE CHARACTERISTICS:
LENGTH: 155 amino acids TYPE: amino acid TOPOLOGY: linear MOLEC~LE TYPE: protein PUBLICATION :[NF`ORMATION:
A~THORS: Pennica, et al JOURNAL: Nature VOLUME: 312 PAGES: 724-DATE: 1984 SEQUENCE DESCRIPTION: SEQ ID NO:l:
Ser Ser Ser Arg Thr Pro Ser Asp Lys Pro Val Ala His Val Val Ala Asn Pro Gln Ala Glu Gly Gln Leu Gln Trp Leu Asn Arg Arg Ala Asn Ala Leu Leu Ala Asn Gly Val Glu Leu Arg Asp Asn Gln Leu Val Val Pro Ser Glu Gly Leu Tyr Leu Ile Tyr Ser Gln Val Leu Phe Lys Gly Gln Gly Cys Pro Ser Thr His Val Leu Leu Thr His Thr Ile Ser Arg Ile Ala Val Ser Tyr Gln Thr Lys Val Asn Leu Leu Ser Ala Ile Lys Ser Pro Cys Gln Arg Glu Thr Pro Glu Gly Ala Glu Ala Lys Pro Trp Tyr Glu Pro Ile Tyr Leu Gly Gly Val Phe Gln Leu Glu Lys Gly Asp Arg Leu Ser Ala Glu Ile Asn Arg Pro Asp Tyr Leu Asp Phe Ala Glu Ser Gly Gln Val Tyr Phe Gly Ile Ile Ala l,eu SEQ ID NO:2:
SEQ~ENCE CHARACTERISTICS:
LENGTH: 8 amino acids TYPE: amino acid TOPOLOGY: linear MOLEC~LE TYPE: peptide - 9S - 2~51 9 7~

SEQ~ENCE DESCRIPTION: SEQ ID NO:2:
Ser Ser Ser Arg Gly Asp Ser Asp SEQ ID NO:3:
SEQUENCE CHARACTERISTICS:
LENGT~: 8 amino acids TYPE: amino acid TOPOLOGY: linear MOLEC~LE TYPE: peptide SEQUENCE DESCRIPTION: SEQ ID NO:3:
Ser Ser Ser Arg Thr Arg Gly Asp SEQ ID NO:4:
SEQUENCE CHARACTERISTICS:
LENGTH: 11 amino acids TYPE: amino acid TOPOLOGY: linear MOLECULE TYPE: peptide SEQUENCE DESCRIPTION: SEQ ID NO:4:
Ser Ser Ser Arg Gly Asp Arg Thr Pro Ser Asp SEQ ID NO:5:
SEQUENCE CHARACTERISTICS:
LENGTH: 11 amino acids TYPE: amino acid TOPOLOGY: linear MOLECULE TYPE: peptide SEQUENCE DESCRIPTION: SEQ ID NO:5:
Ser Ser Ser Arg Thr Pro Arg Gly Asp Ser Asp SEQ ID NO:6:
SEQUENCE CHARACTERISTICS:
LENGTH: 11 amino acids TYPE: amino acid TOPOLOGY: linear MOLECULE TYPE: peptide 99 ~ ~5197a SEQUENCE DEscRIeTIoN: SEQ ID NO:6:
Arg Gly Asp Ser Ser Ser Arg Thr Pro Ser Asp SEQ ID NO:7:
SEQUENCE CHARACTERISTICS:
LENGTH: 14 amino acids TYPE: amino acid TOPOLOGY: linear MOLECULE TYPE: peptide SEQUENCE DESCRIPTION: SEQ ID NO:7:
Ser Ser Arg Gly Asp Arg Gly Asp Ser Arg Ala Pro Ser Asp SEQ ID NO:8:
SEQVENCE CHARACTERISTICS:
LENGTH: 14 amino acids TYPE: amino acid TOPOLOGY: linear MOLECULE TYPE: peptlde SEQUENCE DESCRIPTION: SEQ ID NO:8:
Gly Arg Gly Asp Ser Pro Ser Ser Ser Arg Ala Pro Ser Asp SEQ ID NO:9:
SEQUENCE CHARACTERISTICS:
LENGTH: 16 amino acids TYPE: amino acid TOPOLOGY: linear MOLECULE TYPE: peptide SEQUENCE DESCRIPTION: SEQ ID NO:9:
Asp Pro Gly Arg Gly Asp Ser Pro Ser Ser Ser Arg Ala Pro Ser Asp SEQ ID NO:10:
SEQUENCE CHARACTERISTICS:
LENGTH: 465 bases TYPE: nucleic acid STRANDEDNESS: single TOPOLOGY: linear - loo - 2 ~5 ~ ~ 7~

MOLEC~LE TY~E: DNA (genomic) SEQ~ENCE DESCRIPTION: SEQ ID NO:10:

GAAGGGCAGC TCCAGTGGCT GAACCGCCGG GCC'AATGCCC TCCTGGCTAA TGGAGTGGAG 120 SEQ ID NO:ll:
SEQUENCE CHARACTERISTICS:
LENGTH: 46 bases TYPE: nucleic acid STRANDEDNESS: single TOPOLOGY: linear MOLECULE TYPE: DNA (genomic) SEQUENCE DESCRIPTION: SEQ ID NO:ll:

SEQ ID NO:12:
SEQUENCE CHARACTERISTICS:
LENGTH: 34 bases TYPE: nucleic acid STRANDEDNESS: single TOPOLOGY: linear MOLECULE TYPE: DNA (genomic) SEQUENCE DESCRIPTION: SEQ ID NO:12:

SEQ ID NO:13:
SEQUENCE CHARACTERISTICS:
LENGTH: 34 bases TYPE: nucleic acid STRANDEDNESS: single TOPOLOGY: linear MOLECULE TYPE: DNA (genomic) - 101- 205197~

SEQ~ENCE DESCRlPTlON: SEQ ID NO:13:
AATTCATGGG GCGCGGAGAT TCTCCCTCAT CTI'C 34 SEQ ID NO:L4:
SEQ~ENCE C~IARACTERISTICS:
LENGTH: 32 bases TYPE: nucleic acid STRANDEDNESS: single TOPOI,OGY: linear MOLECULE TYPE: DNA (genomic) SEQ~ENCE DESCRIPTION: SEQ ID NO:14:

Claims

1. A polypeptide which is a tumor necrosis factor polypeptide having an amino acid sequence represented by the sequence from the 1st Ser to the 155th Leu as shown by SEQ ID NO:1 in the Sequence Listing, or a mutein thereof, wherein the amino acid sequence of the 1st Ser to the 8th Asp of said SEQ ID NO:1 or the corresponding amino acid sequence of said mutein is replaced by an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, wherein said polypeptide is from 135 to 178 amino acid residues long and has the antitumor activity of human tumor necrosis factor and the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, corresponds to the sequence of the 9th Lys to the 155th Leu in SEQ ID NO:1 in which up to 15 additions, deletions, substitutions or combinations thereof of amino acid residues have been made.

2. The polypeptide according to Claim 1, wherein the amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, is as shown by SEQ ID NO:2, 3, 4, 5, 6, 7, 8 or 9 in the Sequence Listing or Arg-Gly-Asp.

3. The polypeptide according to Claim 1, wherein the amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, is as shown by SEQ ID NO:2, 3, 5 or 6 in the Sequence Listing or Arg-Gly-Asp.

4. The polypeptide according to Claim 1, 2 or 3, wherein the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, has an amino acid sequence of from the 9th Lys to the 155th Leu as shown by SEQ ID NO:1 or the same amino acid sequence as such except that the 29th Arg, the 68th Pro or the 106th Gly is deleted or replaced by another amino acid residue.

5. The polypeptide according to Claim 4, wherein said 29th Arg is deleted or replaced by Gln, Lys, Asp, Val or Leu; said 68th Pro is deleted or replaced by Asp or Met;
or said 106th Gly is deleted or replaced by Trp, Pro, Ala, Asp or Arg.

6. A recombinant plasmid containing a DNA sequence encoding a polypeptide which is a tumor necrosis factor polypeptide having an amino acid sequence represented by the sequence from the 1st Ser to the 155th Leu as shown by SEQ ID NO:1 in the Sequence Listing, or a mutein thereof, wherein the amino acid sequence of the 1st Ser to the 8th Asp of said SEQ ID NO:1 or the corresponding amino acid sequence of said mutein is replaced by an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, wherein said polypeptide is from 135 to 178 amino acid residues long and has the antitumor activity of human tumor necrosis factor and the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, corresponds to the sequence of the 9th Lys to the 155th Leu in SEQ ID NO:1 in which up to 15 additions, deletions, substitutions or combinations thereof of amino acid residues have been made.

7. The recombinant plasmid according to Claim 6, wherein said recombinant plasmid is pKF 4168, pKF 4415, pKF 4416, pKF 4417, pKF 4418, pKF 4420, pKF 4421, pKF 4113, pKF
4137, pKF 4601, pKF 4602, pKF 4607, pKF 4608, pKF 4626, pKF 4627, pKF 4634, pKF 4635, pKF 4609, pKF 4610, pKF
4628, pKF 4629, pKF 4638, pKF 4639, pKF 4611, pKF 4612, pKF 4613, pKF 4614, pKF 4615, pKF 4642, pKF 4643, pKF
4644, pKF 4645 or pKF 4646.

8. A recombinant microbial cell transformed by a recombinant plasmid containing a DNA sequence encoding a polypeptide which is a tumor necrosis factor polypeptide having an amino acid sequence represented by the sequence from the 1st Ser to the 155th Leu as shown by SEQ ID NO:1 in the Sequence Listing, or a mutein thereof, wherein the amino acid sequence of the 1st Ser to the 8th Asp of said SEQ ID NO:1 or the corresponding amino acid sequence of said mutein is replaced by an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, wherein said polypeptide is from 135 to 178 amino acid residues long and has the antitumor activity of human tumor necrosis factor and the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, corresponds to the sequence of the 9th Lys to the 155th Leu in SEQ ID
NO:1 in which up to 15 additions, deletions r substitutions or combinations thereof of amino acid residues have been made.

9. The recombinant microbial cell according to Claim 8, wherein the recombinant microbial cell is Escherichia coli.

10. A process for producing a polypeptide, which comprises culturing in a medium a recombinant microbial cell transformed by a recombinant plasmid containing a DNA sequence encoding a polypeptide which is a tumor necrosis factor polypeptide having an amino acid sequence represented by the sequence from the 1st Ser to the 155th Leu as shown by SEQ ID NO:1 in the Sequence Listing, or a mutein thereof, wherein the amino acid sequence of the 1st Ser to the 8th Asp of said SEQ ID NO:1 or the corresponding amino acid sequence of said mutein is replaced by an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, wherein said polypeptide is from 135 to 178 amino acid residues long and has the antitumor activity of human tumor necrosis factor and the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, corresponds to the sequence of the 9th Lys to the 155th Leu in SEQ ID NO:1 in which up to 15 additions, deletions, substitutions or combinations thereof of amino acid residues have been made, to produce a polypeptide having such an amino acid sequence, followed by separating the formed polypeptide.

11. A pharmaceutical composition which comprises, as an active ingredient, a polypeptide which is a tumor necrosis factor polypeptide having an amino acid sequence represented by the sequence from the 1st Set to the 155th Leu as shown by SEQ ID NO:1 in the Sequence Listing, or a mutein thereof, wherein the amino acid sequence of the 1st Ser to the 8th Asp of said SEQ ID NO:1 or the corresponding amino acid sequence of said mutein is replaced by an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, wherein said polypeptide is from 135 to 178 amino acid residues long and has the antitumor activity of human tumor necrosis factor and the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, corresponds to the sequence of the 9th Lys to the 155th Leu in SEQ ID NO:1 in which up to 15 additions, deletions, substitutions or combinations thereof of amino acid residues have been made; and a pharmaceutically acceptable carrier or diluent.

12. The pharmaceutical composition according to Claim 11, wherein the amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, is as shown by SEQ ID NO:2, 3, 4, 5, 6, 7, 8 or 9 in the Sequence Listing, or Arg-Gly-Asp.

13. The pharmaceutical composition according to Claim 11, wherein the amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, is as shown by SEQ ID NO:2, 3, 5 or 6 in the Sequence Listing, or Arg-Gly-Asp.

14. The pharmaceutical composition according to Claim 11, 12 or 13, wherein the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, has an amino acid sequence of from the 9th Lys to the 155th Leu as shown by SEQ ID NO:1 or the same amino acid sequence as such except that the 29th Arg, the 68th Pro or the 106th Gly is deleted or replaced by another amino acid residue.

15. The pharmaceutical composition according to Claim 14, wherein said 29th Arg is deleted or replaced by Gln, Lys, Asp, Val or Leu; said 68th Pro is deleted or replaced by Asp or Met; or said 106th Gly is deleted or replaced by Trp, Pro, Ala, Asp or Arg.

16. A polypeptide which is a tumor necrosis factor polypeptide having an amino acid sequence represented by the sequence from the 1st Ser to the 155th Leu as shown by SEQ ID NO:1 in the Sequence Listing, or a mutein thereof, wherein the amino acid sequence of the 1st Ser to the 8th Asp of said SEQ ID NO:1 or the corresponding amino acid sequence of said mutein is replaced by an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, and which has Met at the N-terminus, wherein said polypeptide is from 135 to 178 amino acid residues long and has the antitumor activity of human tumor necrosis factor and the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, corresponds to the sequence of the 9th Lys to the 155th Leu in SEQ ID NO:1 in which up to 15 additions, deletions, substitutions or combinations thereof of amino acid residues have been made.

17. A DNA sequence which encodes a tumor necrosis factor polypeptide, said DNA sequence having a nucleotide sequence represented by the sequence from the 1st T to the 465th G as shown by SEQ ID NO:10 in the Sequence Listing, or a mutant DNA thereof, wherein the nucleotide sequence from the 1st to 3rd TCA (1st codon) to the 22nd to 24th GAC (8th codon) or the corresponding nucleotide sequence of said mutant DNA is replaced by a nucleotide sequence coding for an amino acid sequence containing at least one amino acid sequence of Arg-Gly-Asp and from 3 to 16 amino acids, wherein said polypeptide is from 135 to 178 amino acid residues long and has the antitumor activity of human tumor necrosis factor and the amino acid sequence of said polypeptide, other than the sequence replacing the sequence corresponding to the 1st Ser to the 8th Asp, corresponds to the sequence of the 9th Lys to the 155th Leu in SEQ ID NO:1 in which up to 15 additions, deletions, substitutions or combinations thereof of amino acid residues have been made.