Peptidase cathepsin

Careful examination of the yellowish sediment obtained after spinning down the crude mitochondrial fraction showed it was frequently overlaid with loosely packed, fluffy material —the fluffy layer. Experiments from de Duve s and, later, Novikoff s laboratories in the 1950s demonstrated that the lighter, lysosomal fraction was enriched in a number of hydrolases including acid phosphatase, aryl sulphatase, B glucuronidase, RNAase, and a peptidase, cathepsin. All the enzymes had optimal pHs in the acid range (pH 5-pH 6). Density... 

Stypmann J, Glaser K, Roth W, Tobin DJ, Petermann I, et al. Dilated cardiomyopathy in mice deficient for the lysosomal cysteine peptidase cathepsin L. Proc. Natl. Acad. Sci. U.S.A. 2002 99 6234-6239. 

For many serine and cysteine peptidases catalysis first involves formation of a complex known as an acyl intermediate. An essential residue is required to stabilize this intermediate by helping to form the oxyanion hole. In cathepsin B a glutamine performs this role and sometimes a catalytic tetrad (Gin, Cys, His, Asn) is referred too. In chymotrypsin, a glycine is essential for stabilizing the oxyanion hole. 

CA C1 C01.033 Cathepsin L-like peptidase (Fasciola sp.) Potential drug target for liver fluke infection... 

Gener ally, a family of peptidases contains either exopeptidases or endopeptidases, but there are exceptions. Family Cl contains not only endopeptidases such as cathepsin L, but also the aminopeptidase bleomycin hydrolase. Some members of this family can act as exopeptidases as well as endopeptidases. For example, cathepsin B also acts as a peptidyl-dipeptidase, and... 

Cleavage occur s at the scissile bond. Residues in the substrate towards the N-terminus are numbered PI, P2, P3, etc, whereas residues towards the C-terminus are numbered PI, P2, P3 etc. Cleavage occurs between PI and P1. For a peptidase with limited specificity, only the residue in PI or PI is important for specificity. A peptidase with an extended substrate binding site will have a preference for residues in other positions. For example cathepsin L prefers substrates with phenylalanine in P2 and arginine in PI. However, this is a preference only, and cathepsin L cleaves substrates after other amino acids. Caspase-3 has a preference for Asp in both P4 and PI, but it is unusual for substrate specificity to extend much further from the scissile bond. The peptidase with the most extended substrate specificity may be mitochondrial intermediate peptidase that removes an octopeptide targeting signal from the N-terminus of cytoplasmically synthesized proteins that are destined for import into the mitochondrial lumen. 

This is a 29-kDa protein that has NH 2-terminal sequence homology with elastase and cathepsin G. However, it contains glycine and not serine at the predicted catalytic site, and so lacks protease and peptidase activity. Purified azurocidin kills a range of organisms (e.g. E. coli, S.faecalis, and C. albicans) in vitro. It functions optimally at pH 5.5 and in conditions of low ionic strength. 

One of the general principles of the Nomenclature Committee is that enzymes should be classified and named according to the reaction they catalyze. However, the overlapping specificities of and great similarities in the action of different peptidases render naming solely on the basis of function impossible [10]. For example, some enzymes can act as both endo- and exopeptidases. Thus, cathepsin H (EC 3.4.22.16) is not only an endopeptidase but also acts as an aminopeptidase (EC 3.4.11), and cathepsin B (EC 3.4.22.1) acts as an endopeptidase as well as a peptidyl-dipeptidase (EC 3.4.15). The actual classification of peptidases is, therefore, a compromise based not only on the reaction catalyzed but also on the chemical nature of the catalytic site, on physiological function, and on historical priority. 

Tumor cells express many hydrolytic enzymes, particularly peptidases, some of which are partially specific for certain tumor types, e.g., plasmin, plasminogen activator protease, and cathepsins. A number of prodrug strategies have been developed for the tumor-selective delivery of cytotoxic drugs [45-47], as illustrated below with a few representative examples. 

This enzyme [EC 3.4.16.5] (also known as serine-type carboxypeptidase I, cathepsin A, carboxypeptidase Y, and lysosomal protective protein) is a member of the peptidase family SIO and catalyzes the hydrolysis of the peptide bond, with broad specificity, located at the C-terminus of a polypeptide. The pH optimum ranges from 4.5 to 6.0. The enzyme is irreversibly inhibited by diisopropyl fluorophosphate and is sensitive to thiolblocking reagents. 

This lysosomal enzyme [EC 3.4.22.1], also known as cathepsin Bl, is a member of the peptidase family Cl. The catalyzed reaction is the hydrolysis of peptide binds with a broad specificity. The enzyme prefers the ArgArg—Xaa bond in small peptide substrates (thus distinguishing this enzyme from cathepsin L). The enzyme also exhibits a peptidyl-dipeptidase activity, releasing C-terminal dipeptides from larger polypeptides. 

This mammalian lysosomal endopeptidase [EC 3.4.22.16] is also known as aleurain, cathepsin B3, cathepsin BA, and benzoylarginineinaphthylamide hydrolase. A member of the peptidase family Cl, the enzyme also acts with an aminopeptidase activity, preferring Arg— Xaa peptide bonds. 

This peptidase family Cl enzyme [EC 3.4.22.15] is an lysosomal endopeptidase with specificity akin to papain. Cathepsin L displays a higher activity toward protein substrates than does cathepsin B. 

This enzyme [EC 3.4.14.1], also called cathepsin C and cathepsin J, catalyzes the hydrolysis of a peptide bond resulting in the release of an N-terminal dipeptide, XaaXbb-Xcc, except when Xaa is an arginyl or a lysyl residue, or Xbb or Xcc is a prolyl residue. This enzyme, a member of the peptidase family Cl, is a CF-dependent lysosomal cysteine-type peptidase. 

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