Chemistry: molecular biology and microbiology – Micro-organism – tissue cell culture or enzyme using process... – Recombinant dna technique included in method of making a...
Reexamination Certificate
2001-04-04
2004-03-09
Eyler, Yvonne (Department: 1646)
Chemistry: molecular biology and microbiology
Micro-organism, tissue cell culture or enzyme using process...
Recombinant dna technique included in method of making a...
C435S320100, C435S325000, C530S350000, C536S023500
Reexamination Certificate
active
06703222
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to the soluble low density lipoprotein (LDL) receptor, to its production and to pharmaceutical compositions containing it.
2. Description of the Background Art
Interferons (IFN) are inducible proteins that are produced by various cells and induce an antiviral state in animal cells. There are three major types of IFNs, distinguished by their antigenic properties: &agr;, &bgr; and &ggr;. IFN-&agr; and IFN-&bgr; are related proteins of 166 or 165 amino acid residues that are induced by viruses or nucleic acids and are produced by cells from various tissues, including immune cells. IFN-&ggr; is a protein of 130-143 amino acid residues which is produced by mitogen-activated T-cells and by large granular lymphocytes. The production of IFN is usually transient and it stops shortly after the inducer disappears. For a recent review of these issues, see Taylor S. L. and Grossberg S. E., 1990,
Virus Research
15:1-26.
In addition to the three well-characterized types of interferons, there are several reports describing partially characterized species of interferons. A group of IFN-&agr;-like (IFN-&agr;1) genes and pseudogenes, also known as class II IFN-&agr; or IFN-omega was discovered and reported (Revel, M., 1984, in
Antiviral Drugs and Interferon: The Molecular Basis of their Activity
, Y. Becker (ed.), Martinus Neijhoff Publ., Boston, pp. 357-434; Capon, D. J. et al., 1985,
Molec. Cell. Biol.
5:768-779; Hauptmann, R. and Swetly, P., 1985,
Nuc. Acid. Res.
13:4739-4749). These are virus-induced interferons having about 172 amino acid residues which are present in the natural mixture of human IFN-&agr; produced by leukocytes (Adolf, G. R., 1990,
Virology,
175:410-417).
Treatment of human peripheral blood mononuclear leukocytes with a mitogen resulted in production of IFN-&ggr; and a novel IFN-like substance named IFN-&dgr; (Wilkinson, M. and Morris, A., 1983,
Biochem. Biophys. Res. Comm.
111:498-503). IFN-&dgr; was found to be acid resistant and active only on human fibroblasts having chromosome-21 trisomy and not on WISH cells. It was antigenically distinct from the three known IFN types.
Acid-labile alpha-interferons were described in several publications. An acid-labile IFN-&agr; was induced in cultures of lymphocytes from individuals who have recently received influenza vaccine, by stimulation in vitro with the influenza virus (Balkwill, F. R. et al, 1983,
J. Exp. Med.
157:1059-1063). This type of IFN was neutralized by anti-IFN-&agr; serum and was active on Mandin Darby Bovine Kidney (MDBK) cells. The presence of such acid-labile alpha-type IFN in sera of patients with systemic lupus erythematosus was reported (Klippel, J. H. et al, 1985,
Annals Rheum. Disease
44:104-108). An acid-labile IFN-&agr; was produced similarly to IFN-&agr; by Sendai virus induction of human peripheral leukocytes (Matsuoka, H. et al., 1985,
J. Gen. Virol.
66:2491-2494). Acid-labile IFN-&agr; was spontaneously produced in cultures of peripheral blood mononuclear cells (Fischer, D. G. and Rubinstein, M., 1983,
Cellular Immunology
81:426-434).
Another type of IFN, called IFN-epsilon, was produced by epithelial cells exposed to virus. It was produced together with IFN-&agr; but was active on epithelial cells and not on other cell types (Jarvis, A. P. and Kosowsky, D. I., 1984, U.S. Pat. No. 4,614,651).
Among other cytokines, TNF, IL-6 and IL-1 were reported to exhibit antiviral activity (Mestan, J. et al., 1986,
Nature
323:816-819; Wong, G. H. W. and Goedell, D., 1986,
Nature
323:819-822; Billiau, A., 1987,
Antiviral Research
8:55-70). TNF is produced only by immune cells and it was suggested that IL-1 and TNF exert their antiviral activity by inducing the production of IFN-&bgr; (Billiau, A., op. cit.).
Several interferon-induced proteins have been identified and some of them were shown to be instrumental in the induction of the antiviral state by IFNs. The best studied one is (2′-5′) oligo adenylate synthetase, an intracellular enzyme which polymerizes ATP into pp (A2′-5′p) nA, where n is preferably 2 or 3, but may be as long as 15 (Kerr, I. M. and Brown, R. E., 1978,
Proc. Natl. Acad. Sci. USA
75:256-260). Such oligomers activate a latent ribonuclease (RNASE-F) which degrades ribosomal RNA and polysomes, thereby inhibiting viral and cellular protein synthesis. Another IFN-induced intracellular enzyme is a 2′-5′; phosphodiesterase which may remove the CCA terminus of tRNA, thereby leading to inhibition of protein synthesis (Schmidt, A. et al., 1979,
Proc. Natl. Acad. Sci. USA
76:4788-4792). A third known IFN-induced intracellular enzyme is a 70 Kd protein kinase which phosphorylates the Initiation Factor eIF-2, thereby leading to inhibition of the initiation of mRNA translation into proteins (Ohtsuki, K. et al., 1980,
Nature
287:65-67).
Other IFN-induced intracellular proteins include the nuclear IFN-Responsive Factors (IRF-1 and IRF-2) which regulate IFN-responsive genes; metallothionein, a 56 Kd protein of unknown function in the IFN-induced antiviral state; Factor B of the alternative complement system and the murine Mx gene product, which is responsible for resistance to influenza (Reviewed in Taylor, I. L. and Grossberg, S. E., 1990,
Virus Research
15:1-26). Other IFN-induced cell associated polypeptides were identified on 2-D gels following IFN treatment and [
35
S]-methionine pulsing, but these proteins were not further characterized in terms of their structure and function (Weil, J. et al., 1983,
Nature
301:437-439). Several cell surface interferon-induced proteins were identified, including class I and II MHC antigens, IgG, Fc receptor and cytoskeletal components (Reviewed in Revel, M., 1984, in
Antiviral Drugs and Interferons: The Molecular Basis of their Activity
, Y. Becker (ed.), pp. 357-434, Martinus Neijhoff Publ., Boston).
Additional IFN-induced proteins that were secreted into the medium have been disclosed in the literature, such as &bgr;2-microglobulin, a shedded component of the cell-surface class I MHC antigens (Dolei, A. F. et al., 1981,
Antiviral Res.
1:367-373), and plasminogen activator and lymphotoxin, which were induced in lymphocytes by IFN (Jones, C. M. et al., 1982,
J. Interferon Res.
2:377-386; Wallach, D. and Hahn, T., 1983,
Cellular Immunol.
76:390-396). IFN-&ggr;-treated monocytes released TNF which enhanced the overall antiviral effect (Gerrard, T. et al., 1989,
J. Interferon Res.
9:115-124). IFN-&ggr;-induced proteins of molecular weight 30,000 (extracellular) and 25,000 (intracellular) were described (Luster A. D. et al., 1988,
J. Biol. Chem.
263:12036-12043), but their role was not determined.
Although many IFN-induced proteins have been disclosed, none of them is related to a soluble LDL receptor. The existence of a soluble LDL receptor as a separate protein has not been so far disclosed. The full size low density lipoprotein receptor (LDLR) is a transmembrane glycoprotein which is not soluble in the absence of detergents. It consists of 839 amino acid residues and exhibits a molecular weight of 164,000. Its only known function is to internalize LDL and VLDL. Structurally it consists of several domains, some of which are shared with other proteins. The N-terminal ligand-binding domain is made of 292 amino acid residues arranged in 7 cysteine-rich imperfect repeats. This domain is followed by a region homologous to the EGF precursor (400 amino acid residues), a region of 58 amino acid residues rich in O-linked sugars, a single trans-membrane domain of 22 amino acid residues and a cytoplasmic domain of 50 amino acid residues (Schneider W. J. et al.,
J. Biol. Chem.
257: 2664-2673, 1982; Yamamoto T. et al.,
Cell
39:27-38, 1984). However, there is no mention of antiviral properties of the LDL receptor. The predicted nucleotide sequence (SEQ ID NO:3) of the cDNA corresponding to the LDL receptor in the mRNA, including the predicted LDL receptor amino acid sequence (SEQ ID NO:4) encoded thereby, acc
Fischer Dina G.
Novick Daniela
Rubinstein Menachem
Tal Nathan
Browdy and Neimark , P.L.L.C.
Eyler Yvonne
Murphy Joseph F.
Yeda Research and Development Co. Ltd.
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