Drug – bio-affecting and body treating compositions – Immunoglobulin – antiserum – antibody – or antibody fragment,... – Binds hormone or other secreted growth regulatory factor,...
Reexamination Certificate
1998-12-07
2001-10-09
Eyler, Yvonne (Department: 1646)
Drug, bio-affecting and body treating compositions
Immunoglobulin, antiserum, antibody, or antibody fragment,...
Binds hormone or other secreted growth regulatory factor,...
C424S145100, C424S139100, C530S388230, C530S387900, C530S388100, C530S389100, C530S351000
Reexamination Certificate
active
06299877
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates generally to the identification of a novel member of the type I interferon family. More specifically, the present invention concerns the isolation of a novel nucleic acid encoding a new and distinct type I interferon, termed interferon-epsilon (IFN-&egr;).
BACKGROUND OF THE INVENTION
Interferons are relatively small, single-chain glycoproteins released by cells invaded by viruses or certain other substances. Interferons are presently grouped into three major classes, designated leukocyte interferon (interferon-alpha, &agr;-interferon, IFN-&agr;), fibroblast interferon (interferon-beta, &bgr;-interferon, IFN-&bgr;), and immune interferon (interferon-gamma, &ggr;-interferon, IFN-&ggr;). In response to viral infection, lymphocytes synthesize primarily &agr;-interferon (along with a lesser amount of a distinct interferon species, commonly referred to as omega interferon, IFN-&ohgr;), while infection of fibroblasts usually induces &bgr;-interferon. &agr;- and &bgr;-interferons share about 20-30 percent amino acid sequence homology. Thus, the gene for human IFN-&bgr; lacks introns, and encodes a protein possessing 29% amino acid sequence identity with human IFN-&agr;I, suggesting that IFN-&agr; and IFN-&bgr; genes have evolved from a common ancestor (Taniguchi et al.,
Nature
285, 547-549 (1980)). By contrast, IFN-&ggr; is not induced by viral infection, rather, is synthesized by lymphocytes in response to mitogens, and is scarcely related to the other two types of interferons in amino acid sequence. Interferons-&agr;, &bgr; and &ohgr; are known to induce MHC Class I antigens, and are referred to as type I interferons, while IFN-&ggr; induces MHC Class II antigen expression, and is also referred to as type II interferon.
A large number of distinct genes encoding different species of IFNs-&agr; have been identified. Alpha interferon species identified previously fall into two major classes, I and II, each containing a plurality of discrete proteins (Baron et al.,
Critical Reviews in Biotechnology
10, 179-190 (1990); Nagata et al.,
Nature
287, 401-408 (1980); Nagata et al.,
Nature
284, 316-320 (1980); Streuli et al.,
Science
209, 1343-1347 (1980); Goeddel et al.,
Nature
290, 20-26 (1981); Lawn et al.,
Science
212, 1159-1162 (1981); Ullrich et al.,
J. Mol. Biol.
156, 467-486 (1982); Weissmann et al.,
Phil. Trans. R. Soc. Lond.
B299, 7-28 (1982); Lund et al.,
Proc. Natl. Acad. Sci.
81, 2435-2439 (1984); Capon et al.,
Mol. Cell. Biol.
5, 768 (1985)). The various IFN-&agr; species include IFN-&agr;A (IFN-&agr;2), IFN-&agr;B, IFN-&agr;C, IFN-&agr;C1, IFN-&agr;D (IFN-&agr;1), IFN-&agr;E, IFN-&agr;F, IFN-&agr;G, IFN-&agr;H, IFN-&agr;I, IFN-&agr;J1, IFN-&agr;J2, IFN-&agr;K, IFN-&agr;L, IFN-&agr;4B, IFN-&agr;5, IFN-&agr;6, IFN-&agr;74, IFN-&agr;76 IFN-&agr;4a), IFN-&agr;88, and alleles of these species. According to our current knowledge, the IFN-&agr; family consists of 13 expressed alleles producing 12 different proteins that exhibit remarkably different biological activity profiles. Pestka, S.,
Semin. Oncol.
24(suppl. 9), S9-4-S9-17 (1997).
Interestingly, while only a single human IFN-&bgr; gene has been unequivocally identified, bovine IFN-&bgr; is encoded by a family of five or more homologous, yet distinct genes.
Interferons were originally produced from natural sources, such as buffy coat leukocytes and fibroblast cells, optionally using known inducing agents to increase interferon production. Interferons have also been produced by recombinant DNA technology.
The cloning and expression of recombinant IFN-&agr;A (rIFN-&agr;A, also known as IFN-&agr;2) was described by Goeddel et al.,
Nature
287, 411 (1980). The amino acid sequences of rIFNs-&agr;A, B, C, D, F, G, H, K and L, along with the encoding nucleotide sequences, are described by Pestka in
Archiv. Biochem. Biophys.
221, 1 (1983). The amino acid sequences and the underlying nucleotide sequences of rIFNs-&agr;E, I and J are described in British Patent Specification No. 2,079,291, published Jan. 20, 1982. Hybrids of various IFNs-&agr; are also known, and are disclosed, e.g. by Pestka et al., supra. Nagata et a.,
Nature
284, 316 (1980), described the expression of an IFN-&agr; gene, which encoded a polypeptide (in non-mature form) that differs from rIFN-&agr;D by a single amino acid at position 114. Similarly, the cloning and expression of an IFN-&agr; gene (designated as rIFN-&agr;2) yielding a polypeptide differing from rIFN-&agr;A by a single amino acid at position 23, was described in European Patent Application No. 32 134, published Jul. 15, 1981.
The cloning and expression of mature rIFN-&bgr; is described by Goeddel et al.,
Nucleic Acids Res.
8, 4057 (1980).
The cloning and expression of mature rIFN-&ggr; are described by Gray et al.,
Nature
295, 503 (1982).
IFN-&ohgr; has been described by Capon et al,
Mol. Cell. Biol.
5, 768 (1985).
IFN-
T
has been identified and disclosed by Whaley et al.,
J. Biol. Chem.
269, 10864-8 (1994).
All of the known IFNs-&agr;, -&bgr;, and -&ggr; contain multiple cysteine residues. These residues contain sulfhydryl side-chains which are capable of forming intermolecular disulfide bonds. For example, the amino acid sequence of mature recombinant rIFN-&agr;A contains cysteine residues at positions 1, 29, 98 and 138. Wetzel et al.,
Nature
289, 606 (1981), assigned intramolecular disulfide bonds between the cysteine residues at positions 1 and 98, and between the cysteine residues at positions 29 and 138.
Antibodies specifically binding various interferonsare also well known in the art. For example, anti-&agr;-interferon agonist antibodies have been reported by Tsukui et al.,
Microbiol. Immunol.
30, 1129-1139 (1986); Duarte et al.,
Interferon
-
Biotechnol.
4, 221-232 (1987); Barasoain et al.,
J. Immunol.
143, 507-512 (1989); Exleyetal.,
J. Gen. Virol.
65, 2277-2280 (1984); Shearer et al.,
J. Immunol.
133, 3096-3101 (1984); Alkan et al.,
Ciba Geigy Foundation Symposium
119, 264-278 (1986); Noll et al.,
Biomed. Biochim. Acta
48, 165-176 (1989); Hertzog et al.,
J. Interferon Res.
10(Suppl. 1) 5170 (1990); Kontsek et al.,
J. Interferon Res.
11 (special issue) 327-332 (1991), and U.S. Pat. No. 4,423,147 issued Dec. 27, 1983.
The actions of type I interferons appear to be mediated by binding to the IFN-&agr; receptor complex on the cell surface. This receptor is composed of at least two distinct proteins identified as IFN-&agr;R1 (Uze et al.,
Cell
60, 225-234[1990]) and IFN-&agr;R2 (Novick et al.,
Cell
77, 39-400 [1994]). The engagement of receptors by ligand binding activates Janus family kinases (JAK) and protoplasmic latent signal transducers and activators of transcription (STAT) proteins by tyrosine phosphorylation. Activated STATs translocate to the nucleus in forms of complexes and interact with their cognitive enhancer elements of IFN-stimulated genes (ISGs), leading to a corresponding transcription activation and biological responses. Darnell et al.,
Science
264, 1415-21 (1994). However, despite similarities in their binding properties, the biological responses stimulated by type I interferons are significantly different.
Interferons have a variety of biological activities, including antiviral, immunoregulatory and antiproliferative properties, and are, therefore, of great interest as therapeutic agents in the control of cancer, and various viral diseases. Interferons have been implicated in the pathogenesis of various autoimmune diseases, such as systemic lupus erythematoses, Behcet's disease, insulin-dependent diabetes mellitus (IDDM, also referred to as type I diabetes). It has been demonstrated in a transgenic mouse model that &bgr; cell expression of IFN-&agr; can cause insulitis and IDDM, and IFN-&agr; antagonists (including antibodies) have been proposed for the treatment of IDDM (WO 93/04699, published Mar. 18, 1993). Impaired IFN-&ggr; and IFN-&agr; production has been observed in multiple sclerosis (MP) patients. An acid-labile IFN-&agr; has been det
Chen Jian
Godowski Paul
Wood William I.
Zhang Dong-Xiao
Agarwal Atulya R.
Andres Janet L.
Eyler Yvonne
Genentech Inc.
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