Carboxypeptidase activity

Figure 6.1 Characterization of impaired prohormone processing in mice lacking functional active carboxypeptidase E (Cpe mice) by peptidomics.

An example of direct difference counting, in a situation where the overall titration curve is not known, is provided by Fig. 7. It shows the difference between the titration curves of active carboxypeptidase A, which contains Zn++, and the inactive zinc-free protein, as determined by Coleman and Vallee (1961). The measurements were made by the pH-stat method, and confined to a relatively narrow pH range. The figure shows a difference of two groups per bound Zn++ ion, with pK values of 7.7 and 9.1. The two groups involved lose their protons when Zn++ is bound. In the absence of a complete titration curve a completely unequivocal interpretation... 

The smaller peptides formed by the action of trypsin, chymotrypsin, and elastase are attacked by exopeptidases, which are proteases that cleave one amino acid at a time from the end of the chain. Procarboxypeptidases, zymogens prodnced by the pancreas, are converted by trypsin to the active carboxypeptidases. These exopeptidases remove amino acids from the carboxyl ends of peptide chains. Carboxypeptidase A preferentially releases hydrophobic amino acids, whereas car-boxypeptidase B releases basic amino acids (arginine and lysine). 

Carboxypeptidaae. Carboxypeptidase occurs in extracts of pancreas. The pancreas contains an inactive precursor of the enzyme, a zymogen. In the case of carboxypeptidase the precursor has been partially purified. The accumulation of zymogens seems to be characteristic for those proteolytic enzymes that are secreted. In neutral solutions procarboxypeptidase is converted to active carboxypeptidase by the action of other enzymes present in the crude extracts. The mechanism of this activation is not completely known, although it appears that the reaction involves splitting of peptide bonds by other proteolytic enzymes. 

Serine carboxypeptidases Cleave amino acids from C-terminal, serine in the active Carboxypeptidase C, cathepsin A... 

Dhariwal 6e McCann, unpublished data, 1966). This observation indicates that intact peptide bonds are required for their activity. Carboxypeptidase failed to inactivate the FRF in one experiment. Thioglycollate splits the disulfide bridge in oxytocin and vasopressin, thus inactivating the molecules, but this treatment is without influence on LRF or hypothalamic CRF (16). Consequently, it appears likely that the chemical structures of LRF and CRF, at least with respect to the disulfide bridge, are dissimilar from that of the known neuroh3q)ophysial pol3q)eptides. 

The shape of a large protein is influenced by many factors including of course Its primary and secondary structure The disulfide bond shown m Figure 27 18 links Cys 138 of carboxypeptidase A to Cys 161 and contributes to the tertiary structure Car boxypeptidase A contains a Zn " ion which is essential to the catalytic activity of the enzyme and its presence influences the tertiary structure The Zn ion lies near the cen ter of the enzyme where it is coordinated to the imidazole nitrogens of two histidine residues (His 69 His 196) and to the carboxylate side chain of Glu 72... 

FIGURE 27 19 Proposed mechanism of hydrolysis of a peptide catalyzed by carboxypeptidase A The peptide is bound at the active site by an ionic bond between its C terminal ammo acid and the positively charged side chain of arginine 145 Coordination of Zn to oxygen makes the carbon of the carbonyl group more positive and increases the rate of nucleophilic attack by water... 

Living systems contain thousands of different enzymes As we have seen all are structurally quite complex and no sweeping generalizations can be made to include all aspects of enzymic catalysis The case of carboxypeptidase A illustrates one mode of enzyme action the bringing together of reactants and catalytically active functions at the active site... 

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... 

Enzymes Degrading Macromolecules. Enzymes that degrade macromolecules such as membrane polysaccharides, stmctural and functional proteins, or nucleic acids, have all shown oncolytic activity. Treatment strategies include the treatment of inoperable tumors with pepsin (1) antitumor activity of carboxypeptidase (44) cytotoxicity of ribonudease (45—47) oncolytic activity of neuraminidase (48—52) therapy with neuraminidase of patients with acute myeloid leukemia (53) antitumor activity of proteases (54) and hyaluronidase treatment in the management of human soHd tumors (55). 

Figure 4.19 Schematic and topological diagrams for the structure of the enzyme carboxypeptidase. The central region of the mixed p sheet contains four adjacent parallel p strands (numbers 8, 5, 3, and 4), where the strand order is reversed between strands 5 and 3. The active-site zinc atom (yellow circle) is bound to side chains in the loop regions outside the carboxy ends of these two p strands. The first part of the polypeptide chain is red, followed by green, blue, and brown. (Adapted from J. Richardson.)...

The reactivity of the coordinated, deprotonated nucleophile is typically intermediate between that of the un-ionized and ionized forms of the nucleophile. Carboxypeptidase (Chapter 5) contains an active site Zn, which facilitates deprotonation of a water molecule in this manner. 

Uncovering of the three dimentional structure of catalytic groups at the active site of an enzyme allows to theorize the catalytic mechanism, and the theory accelerates the designing of model systems. Examples of such enzymes are zinc ion containing carboxypeptidase A 1-5) and carbonic anhydrase6-11. There are many other zinc enzymes with a variety of catalytic functions. For example, alcohol dehydrogenase is also a zinc enzyme and the subject of intensive model studies. However, the topics of this review will be confined to the model studies of the former hydrolytic metallo-enzymes. 

An artificial metalloenzyme (26) was designed by Breslow et al. 24). It was the first example of a complete artificial enzyme, having a substrate binding cyclodextrin cavity and a Ni2+ ion-chelated nucleophilic group for catalysis. Metalloenzyme (26) behaves a real catalyst, exhibiting turnover, and enhances the rate of hydrolysis of p-nitrophenyl acetate more than 103 fold. The catalytic group of 26 is a -Ni2+ complex which itself is active toward the substrate 1, but not toward such a substrate having no metal ion affinity at a low catalyst concentration. It is appearent that the metal ion in 26 activates the oximate anion by chelation, but not the substrate directly as believed in carboxypeptidase. 

Several model systems related to metalloenzymes such as carboxypeptidase and carbonic anhydrase have been reviewed. Breslow contributed a great deal to this field. He showed how to design precise geometries of bis- or trisimidazole derivatives as in natural enzymes. He was able to synthesize a modified cyclodextrin having both a catalytic metal ion moiety and a substrate binding cavity (26). Murakami prepared a novel macrocyclic bisimidazole compound which has also a substrate binding cavity and imidazole ligands for metal ion complexation. Yet the catalytic activities of these model systems are by no means enzymic. 

Proteins identified by their ability to bind labelled (3-lactam antibiotics in vivo and in vitro. The intrinsic activities of PBPs include transglycosylase/transpepti-dase, carboxypeptidase and endopeptidase activities required for the formation of the bacterial murein sacculus forming the bacterial cell wall. The enzymes are located in the cytoplasmic membrane. 

Similar reaction mechanisms, involving general base and metal ion catalysis, in conjunction with an OH nucleophilic attack, have been proposed for thermolysin (Ref. 12) and carboxypeptidase A (Refs. 12 and 13). Both these enzymes use Zn2+ as their catalytic metal and they also have additional positively charged active site residues (His 231 in thermolysin and... 

Figure 7-3. Two-dimensional representation of a dipeptide substrate, glycyl-tyrosine, bound within the active site of carboxypeptidase A.

The crystal structure of the HNL isolated from S. bicolor (SbHNL) was determined in a complex with the inhibitor benzoic acid." The folding pattern of SbHNL is similar to that of wheat serine carboxypeptidase (CP-WII)" and alcohol dehydrogenase." A unique two-amino acid deletion in SbHNL, however, is forcing the putative active site residues away from the hydrolase binding site toward a small hydrophobic cleft, thereby defining a completely different active site architecture where the triad of a carboxypeptidase is missing. 

The effects of various enzymes on the activity of HPLC fractions that inhibited 3H-PCP binding were investigated. As shown in table 1, pronase (0.5 pg/ml), carboxypeptidase A (0.1 unit/ml), and trypsin (3.0 g/ml ) markedly decreased the potency of 10 n units of PCP-like activity. No significant change in activity was. seen when fractions were incubated with alpha-chymotrypsin. 

Procarboxypeptidase A is activated by the removal of a peptide of some 64 residues from the N-terminus by trypsin.153 This zymogen has significant catalytic activity. As well as catalyzing the hydrolysis of small esters and peptides, procarboxypeptidase removes the C-terminal leucine from lysozyme only seven times more slowly than does carboxypeptidase. Also, the zymogen hydrolyzes Bz-Gly-L-Phe with kcsA = 3 s-1 and KM = 2.7 mM, compared with values of 120 s 1 and 1.9 mM for the reaction of the enzyme.154 In contrast to the situation in chymotrypsinogen, the binding site clearly pre-exists in procarboxypeptidase, and the catalytic apparatus must be nearly complete. 

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... 

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