Peptidases carboxypeptidase

Several different types of proteases hydrolyze intact storage proteins first into large fragments and then into smaller peptides and amino acids within the protein body. The peptides are transported to the cytosol where other enzymes, e. g. amino-peptidases, carboxypeptidases, dipeptidases and tripeptidases, cleave them and eventually form a pool of free amino acids [11]. 

In 1940 carbonic anhydrase was shown to be a zinc enzyme, and in 1955 carboxypeptidase became the second recognized zinc enzyme. Since then more than 300 other zinc enzymes have been reported, and functionally they are of many kinds, including alcohol dehydrogenases, aldolases, peptidases, carboxypeptidases, proteases, phosphatases, transphosphorylases, a transcarbamylase, and DNA- and RNA-polymerases. 

It is interesting to note that there is another carboxy-peptidase. carboxypeptidase B (CPB), in the same tissue that has an ainino acid sequence homologous to that of CPA but differs in substrate specificity. Whereas CPA prefers aromatic (phenylalanine, tyrosine, and tryptophan) or hydrophobic amino acid residues (valine, leucine, and... 

Z),Z)-peptidase/carboxypeptidase). The mixture of (524)/(526) and the related monophosphonic derivative (523) were modestly active against NMCA jS-lactamase. " ... 

Pancreatic-proteinase (trypsin-type) Protaminase Amino-peptidase Carboxypeptidase Dipeptidase Prolinase Prolidase Cathepsin (papain-type) Amino -peptidase Carboxypeptidase Dipeptidase Prolinase Proteinase (papain-type) Amino-peptidase Carboxy- peptidase Dipeptidase Prolinase Proteinase (trypsin-type) Cathepsin Amino-peptidase Carboxy- peptidase Dipeptidase... 

Metabolic Functions. Zinc is essential for the function of many enzymes, either in the active site, ie, as a nondialyzable component, of numerous metahoenzymes or as a dialyzable activator in various other enzyme systems (91,92). WeU-characterized zinc metahoenzymes are the carboxypeptidases A and B, thermolysin, neutral protease, leucine amino peptidase, carbonic anhydrase, alkaline phosphatase, aldolase (yeast), alcohol... 

There are several different types of exopeptidases aminopeptidases, carboxypeptidases, dipeptidyl-peptidases, tripeptidy 1-peptidases, peptidyl-... 

The introduction of redox activity through a Co11 center in place of redox-inactive Zn11 can be revealing. Carboxypeptidase B (another Zn enzyme) and its Co-substituted derivative were oxidized by the active-site-selective m-chloroperbenzoic acid.1209 In the Co-substituted oxidized (Co111) enzyme there was a decrease in both the peptidase and the esterase activities, whereas in the zinc enzyme only the peptidase activity decreased. Oxidation of the native enzyme resulted in modification of a methionine residue instead. These studies indicate that the two metal ions impose different structural and functional properties on the active site, leading to differing reactivities of specific amino acid residues. Replacement of zinc(II) in the methyltransferase enzyme MT2-A by cobalt(II) yields an enzyme with enhanced activity, where spectroscopy also indicates coordination by two thiolates and two histidines, supported by EXAFS analysis of the zinc coordination sphere.1210... 

Identification of carboxy-terminal amino acids was also attempted. Studies by Bergmann and his associates in the 1930s (see below) had characterized various peptidases with differing specificities. One of these was carboxypeptidase which required a free carboxy terminus adjacent to the peptide bond to be hydrolyzed. The specificity of the enzyme was limited but Lens in 1949 reported alanine to be at one end of insulin. Fromageot and his colleagues (1950) and Chibnall and Rees (1951) reduced the carboxy termini to B-aminoalcohols and showed glycine as well as alanine to be carboxy-terminal. Hydrazinolysis was also attempted the dry protein was treated with hydrazine at 100 °C for 6 h so that the carboxy-terminal amino acid was released as the free... 

The evolutionary classification has a rational basis, since, to date, the catalytic mechanisms for most peptidases have been established, and the elucidation of their amino acid sequences is progressing rapidly. This classification has the major advantage of fitting well with the catalytic types, but allows no prediction about the types of reaction being catalyzed. For example, some families contain endo- and exopeptidases, e.g., SB-S8, SC-S9 and CA-Cl. Other families exhibit a single type of specificity, e.g., all families in clan MB are endopeptidases, family MC-M14 is almost exclusively composed of carboxypeptidases, and family MF-M17 is composed of aminopeptidases. Furthermore, the same enzyme specificity can sometimes be found in more than one family, e.g., D-Ala-D-Ala carboxypeptidases are found in four different families (SE-S11, SE-S12, SE-S13, and MD-M15). 

These proteolytic enzymes are all endopeptidases, which hydrolyse links in the middle of polypeptide chains. The products of the action of these proteolytic enzymes are a series of peptides of various sizes. These are degraded further by the action of several peptidases (exopeptidases) that remove terminal amino acids. Carboxypeptidases hydrolyse amino acids sequentially from the carboxyl end of peptides. They are secreted by the pancreas in proenzyme form and are each activated by the hydrolysis of one peptide bond, catalysed by trypsin. Aminopeptidases, which are secreted by the absorptive cells of the small intestine, hydrolyse amino acids sequentially from the amino end of peptides. In addition, dipeptidases, which are structurally associated with the glycocalyx of the entero-cytes, hydrolyse dipeptides into their component amino acids. 

ACE is a rather nonspecific peptidase that can cleave C-terminal dipeptides from various peptides (dipeptidyl carboxypeptidase). As kininase 11, it contributes to the inactivation of kinins, such as bradykinin. ACE is also present in blood plasma however, enzyme localized in the luminal side of vascular endothelium is primarily responsible for the formation of angiotensin 11. The lung is rich in ACE, but kidneys, heart, and other organs also contain the enzyme. 

The exopeptidases attack peptides from their termini. Peptidases that act at the N terminus are known as aminopeptidases, while those that recognize the C terminus are called carboxypeptidases. The dipeptidases only hydrolyze dipeptides. 

This enzyme [EC 3.4.16.4], also known as serine-type D-alanyl-D-alanine carboxypeptidase, catalyzes the hydrolysis of D-alanyl-D-alanine to yield two D-alanine. This enzyme comprises a group of membrane-bound, bacterial enzymes of the peptidase family Sll. They are distinct from the zinc D-alanyl-D-alanine carboxypeptidase [EC 3.4.17.14]. The enzyme also hydrolyzes the D-alanyl-D-alanine peptide bond in the polypeptide of the cell wall. In addition, the enzyme will also catalyze the transpeptidation of peptidyl-alanyl moieties that are A-acetyl-substituents of D-alanine. The protein is inhibited by j8-lactam antibiotics, which acylate the active-site seryl residue. 

This zinc-dependent enzyme [EC 3.4.15.1] (also known as dipeptidyl carboxypeptidase I, dipeptidyl-dipeptidase A, kininase II, peptidase P, and carboxycathepsin) catalyzes the release of a C-terminal dipeptide at a neutral pH. The enzyme will also act on bradykinin. The presence of prolyl residues in angiotensin I and in bradykinin results in only single dipeptides being released due to the activity of this enzyme, a protein which belongs to the peptidase M2 family. The enzyme is a glycoprotein, generally membrane-bound, that is chloride ion-dependent. 

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 enzyme [EC 3.4.17.3] (also referred to as lysine carboxypeptidase, arginine carboxypeptidase, kininase I, or anaphylatoxin inactivator) is a zinc-dependent member of peptidase family M14. The enzyme hydrolyzes the peptide bond at the C-terminus provided that the C-terminal amino acid is either arginine or lysine. The enzyme inactivates bradykinin and anaphylatoxins in blood plasma. 

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