Heteroaryl amidines, methylamidines and guanidines,...

Drug – bio-affecting and body treating compositions – Designated organic active ingredient containing – Having -c- – wherein x is chalcogen – bonded directly to...

Reexamination Certificate

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C514S444000, C514S370000, C514S314000, C514S342000, C549S068000, C549S060000, C548S198000, C546S162000, C546S280400

Reexamination Certificate

active

06291514

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to novel heteroaryl compounds that function as enzyme inhibitors, and particularly to a new class of non-peptidic inhibitors of proteolytic enzymes such as urokinase (uPa).
2. Related Art
Proteases are enzymes that cleave proteins at single, specific peptide bonds. Proteases can be classified into four generic classes: serine, thiol or cysteinyl, acid or aspartyl, and metalloproteases (Cuypers et al.,
J. Biol. Chem.
257:7086 (1982)). Proteases are essential to a variety of biological activities, such as digestion, formation and dissolution of blood clots, reproduction and the immune reaction to foreign cells and organisms. Aberrant proteolysis is associated with a number of disease states in man and other mammals. The human neutrophil proteases, elastase and cathepsin G, have been implicated as contributing to disease states marked by tissue destruction. These disease states include emphysema, rheumatoid arthritis, corneal ulcers and glomerular nephritis. (Barret, in
Enzyme Inhibitors as Drugs
, Sandler, ed., University Park Press, Baltimore, (1980)). Additional proteases such as plasmin, C-1 esterase, C-3 convertase, urokinase and tissue-type plasminogen activators, acrosin, and kallikreins play key roles in normal biological functions of mammals. In many instances, it is beneficial to disrupt the function of one or more proteolytic enzymes in the course of therapeutically treating a mammal.
Serine proteases include such enzymes as elastase (human leukocyte), cathepsin G, plasmin, C-1 esterase, C-3 convertase, urokinase and tissue-type plasminogen activators, acrosin, chymotrypsin, trypsin, thrombin, factor Xa and kallikreins.
Human leukocyte elastase is released by polymorphonuclear leukocytes at sites of inflammation and thus is a contributing cause for a number of disease states. Cathepsin G is another human neutrophil serine protease. Compounds with the ability to inhibit the activity of these enzymes are expected to have an anti-inflammatory effect useful in the treatment of gout, rheumatoid arthritis and other inflammatory diseases, and in the treatment of emphysema. Chymotrypsin and trypsin are digestive enzymes. Inhibitors of these enzymes are useful in treating pancreatitis. Inhibitors of urokinase plasminogen activator are useful in treating excessive cell growth disease states, such as benign prostatic hypertrophy, prostatic carcinoma and psoriasis.
Urokinase (urinary-type plasminogen activator or uPA; International Union of Biochemistry Classification Number: EC3.4.21.31) is a proteolytic enzyme which is highly specific for a single peptide bond in plasminogen. It is a multidomain serine protease, having a catalytic “B” chain (amino acids (aa) 144-411), and an amino-terminal fragment (“ATF”, aa 1-143) consisting of a growth factor-like domain (4-43) and a Kringle domain (aa 47-135). The uPA Kringle domain appears to bind heparin, but not fibrin, lysine, or aminohexanoic acid. The growth factor-like domain bears some similarity to the structure of epidermal growth factor (EGF) and is thus also referred to as “EGF-like” domain. The single chain pro-uPA is activated by plasmin, cleaving the chain into a two-chain active form that is stabilized by a disulfide bond.
Cleavage of the peptide bond in plasminogen by urokinase (“plasminogen activation”) results in the formation of a potent general protease, plasmin. Many cell types use urokinase as a key initiator of plasmin-mediated proteolytic degradation or modification of extracellular support structures (e.g., the extracellular matrix (ECM) and the basement membrane (BM)). Cells exist, move, and interact with each other in tissues and organs within the physical framework provided by the ECM and BM. Movement of cells within the ECM or across the BM requires local proteolytic degradation or modification of these structures, allowing cells to “invade” into adjacent areas that were previously unavailable.
Central to the ability of urokinase to mediate cellular migration and invasiveness is the existence of specific high affinity urokinase receptors (uPARs) which concentrate urokinase on the cell surface, leading to the generation of locally high plasmin concentrations between cells and ECM or BM (Blasi, F., et al.,
Cell Biol.
104:801-804 (1987); Roldan, A. L., et al.,
EMBO J.
9:467-74 (1990)). The binding interaction is apparently mediated by the EGF-like domain (Rabbani, S. A., et al.,
J. Biol. Chem.
267:14151-56 (1992)). Cleavage of pro-uPA into active uPA is accelerated when pro-uPA and plasminogen are receptor-bound. Thus, plasmin activates pro-uPA, which in turn activates more plasmin by cleaving plasminogen. This positive feedback cycle is apparently limited to the receptor-based proteolysis on the cell surface, since a large excess of protease inhibitors is found in plasma, including &agr;
2
antiplasmin, PAI-1 and PAI-2. High plasmin concentrations between invasive cells and ECM or BM are necessary in order to overcome inhibitory effect of these ubiquitous plasmin inhibitors. Thus, it is cell surface receptor-bound urokinase, and not simply free urokinase secreted by cells, which plays the predominant role in initiating cellular invasiveness.
Plasmin can activate or degrade extracellular proteins such as fibrinogen, fibronectin, and zymogens, including matrix metalloproteinases. Plasminogen activators thus can regulate extracellular proteolysis, fibrin clot lysis, tissue remodeling, developmental cell and smooth muscle cell migration, inflammation, and metastasis. Cellular invasiveness initiated by urokinase is central to a wide variety of normal and disease-state physiological processes (reviewed in Blasi, F., et al.,
J. Cell Biol.
104:801-804(1987); Dano, K., et al.,
Adv. Cancer Res.
44:139-266 (1985); Littlefield, B. A.,
Ann. N. Y. Acad. Sci.
622:167-175 (1991); Saksela, O.,
Biochim. Biophys. Acta
823:35-65 (1985); Testa, J. E., and Quigley, J. P.,
Cancer Metast. Rev.
9:353-367 (1990)). Such processes include, but are not limited to, angiogenesis (neovascularization), bone restructuring, embryo implantation in the uterus, infiltration of immune cells into inflammatory sites, ovulation, spermatogenesis, tissue remodeling during wound repair, restenosis and organ differentiation, fibrosis, local invasion of tumors into adjacent areas, metastatic spread of tumor cells from primary to secondary sites, and tissue destruction in arthritis. Inhibitors of urokinase therefore have mechanism-based anti-angiogenic, anti-arthritic, anti-inflammatory, anti-restenotic, anti-invasive, anti-metastatic, anti-osteoporotic, anti-retinopathic (for angiogenesis-dependent retinopathies), contraceptive, and tumoristatic activities. Inhibitors of urokinase are useful agents in the treatment of a variety of disease states, including but not limited to, benign prostatic hypertrophy, prostatic carcinoma and psoriasis.
Beneficial effects of urokinase inhibitors have been reported using anti-urokinase monoclonal antibodies and certain other known urokinase inhibitors. For instance, anti-urokinase monoclonal antibodies have been reported to block tumor cell invasiveness in vitro (Hollas, W., et al.,
Cancer Res.
51:3690-3695, (1991); Meissauer, A., et al.,
Exp. Cell Res.
192:453-459 (1991)), tumor metastasis and invasion in vivo (Ossowski, L.,
J. Cell Biol.
107:2437-2445 (1988); Ossowski, L., et al.,
J. Cancer Res.
51:274-81(1991)), and angiogenesis in vivo (Jerdan, J. A., et al.,
J. Cell Biol.
115[3 Pt 2]:402a (1991)). In addition, amiloride, a known urokinase inhibitor of only moderate potency, has been reported to inhibit tumor metastasis in vivo (Kellen, J. A., et al.,
Anticancer Res.
8:1373-1376 (1988)) and angiogenesis/capillary network information in vitro (Alliegro, M. A., et al.,
J. Cell Biol.
115[3 Pt 2]:402a (1991)).
Urokinase plays a significant role in vascular wound healing and arterial neointima formation after injury, most likely affecting cellular migration. Urokinase mediates plasmin proteo

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