On subunit II of bovine procarboxypeptidase A. Properties after alkaline dissociation

Complex Formation of Human Proelastases with Procarboxypeptidases A1 and A2

The pancreas secretes digestive proenzymes typically in their monomeric form. A notable exception is the ternary complex formed by proproteinase E, chymotrypsinogen C, and procarboxypeptidase A (proCPA) in cattle and other ruminants. In the human and pig pancreas binary complexes of proCPA with proelastases were found. To characterize complex formation among human pancreatic protease zymogens in a systematic manner, we performed binding experiments using recombinant proelastases CELA2A, CELA3A, and CELA3B; chymotrypsinogens CTRB1, CTRB2, CTRC, and CTRL1; and procarboxypeptidases CPA1, CPA2, and CPB1. We found that proCELA3B bound not only to proCPA1 (KD 43 nm) but even more tightly to proCPA2 (KD 18 nm), whereas proCELA2A bound weakly to proCPA1 only (KD 152 nm). Surprisingly, proCELA3A, which shares 92% identity with proCELA3B, did not form stable complexes due to the evolutionary replacement of Ala(241) with Gly. The polymorphic nature of position 241 in both CELA3A (∼4% Ala(241) alleles) and CELA3B (∼2% Gly(241) alleles) points to individual variations in complex formation. The functional effect of complex formation was delayed procarboxypeptidase activation due to increased affinity of the inhibitory activation peptide, whereas proelastase activation was unchanged. We conclude that complex formation among human pancreatic protease zymogens is limited to a subset of proelastases and procarboxypeptidases. Complex formation stabilizes the inhibitory activation peptide of procarboxypeptidases and thereby increases zymogen stability and controls activation.

Purification and partial characterization of camel anionic chymotrypsin

An anionic chymotrypsin-like enzyme was isolated from a crude extract of camel pancreas by a three-step procedure consisting of anion-exchange chromatography, gel filtration, and hydrophobic interaction chromatography. The purified enzyme was homogeneous on native and SDS gel electrophoresis and on gel isoelectric focusing. Its molecular mass was estimated as 28.5 kDa and its isoelectric point was found to be 4.4. The enzyme differed markedly from bovine chymotrypsin A in its substrate specificity, showing considerably lower values of the specificity constant for its action on tyrosine, tryptophan, and phenylalanine esters. Its pH optimum was found to be 7.8. It showed lower kininase activity and was more susceptible to inhibition by a number of inhibitors than the bovine cationic chymotrypsin. On the other hand, the camel enzyme showed a much greater hydrolytic activity than the bovine enzyme toward a leucine ester. In terms of its size, charge, and substrate specificity the camel enzyme was very similar to anionic chymotrypsins that have been isolated from other species and thus appears to be a camel anionic chymotrypsin.

The activation peptide of pancreatic procarboxypeptidase A is the keystone of the bovine procarboxypeptidase A-S6 ternary complex

In some ruminant species, pancreatic procarboxypeptidase A is the central element of a ternary complex involving two other components, a C-type chymotrypsinogen and an inactive protease E. Although the complex is devoted to protein digestion, the fate of this system upon activation of its constituent subunits has, as yet, not been clearly established. In this paper, the activation peptide of procarboxypeptidase A is shown to play a key role in the association of the three subunits and a model is proposed for the in vivo function of the complex.

Cloning and nucleotide sequence of a bovine pancreatic preprocarboxypeptidase A cDNA

A full-length cDNA clone encoding bovine pancreatic preprocarboxypeptidase A was isolated and sequenced. The 1405-base pair insert contains a 26-nucleotide 5'-noncoding region, a 1260-nucleotide open reading frame and a 76-nucleotide 3'-noncoding fragment plus a poly(A) tail of at least 43 nucleotides. The open reading frame encodes a protein of 419 amino acids, including the 16 amino acid signal peptide. The mature enzyme (309 residues) has two additional C-terminal amino acids, as compared with the amino acid sequence of the protein which was reported more than 20 years ago. In addition, four residues deduced from the nucleotide sequence differed from those identified in the reported amino acid sequence from their net charge: Asp-89, Asp-114, Gln-122, and Asp-185 instead of Asn-89, Asn-114, Glu-122, and Asn-185, respectively. A high degree of identity exists between the nucleotide sequences (81.3%), on the one hand, and the amino acid sequences (78.3%), on the other hand, of bovine preprocarboxypeptidase A and rat preprocarboxypeptidase A1.

The bovine pro-carboxypeptidase A-S6 ternary complex: a rare case of a secreted protein complex

Up to now, a non-covalent ternary complex in which the pro-carboxypeptidase A (subunit I) is associated to two functionally different proteins (subunits II and III) has only been found in the pancreas of ruminant species. In the other species studied so far, the pro-carboxypeptidase A is secreted either as a monomer or as a binary association with a functionally different protein. Subunit I is the immediate precursor of carboxypeptidase A. Subunit II is a chymotrypsinogen of the C-type, involved, like subunit I, in the degradation of proteins and peptides. Although closely related to the pancreatic serine endopeptidases, subunit III appears to be devoid of any specific enzymatic activity. Information about the spatial organization of the subunits in the ternary complex has been deduced from the sequential dissociation of the complex. In contrast to the mechanism of activation of subunits I and II, which is independent of their aggregation state, the catalytic properties of the resulting enzymes are sensitive to their aggregation state. Moreover, the structural basis of inactivity of subunit III as well as the physiological role of the ternary complex are also discussed in this review.

Further studies on the activation of bovine pancreatic procarboxypeptidase A by trypsin

Unlike the pancreatic endopeptidase zymogens, procarboxypeptidase A is activated very slowly in vitro. The activation proceeds through the removal of about 100 amino acids away from the N-terminus of the chain. The cleavage of the susceptible bond(s) in monomeric and aggregated forms of bovine procarboxypeptidase A by catalytic amounts of trypsin was found to be very fast. However, as in the case of the porcine zymogen, the expression of the carboxypeptidase activity was considerably delayed by the inhibitory effect of the activation peptide which remains bound to the enzyme molecule after the trypsin treatment of the zymogen. alpha-Carboxypeptidase A was mainly formed under the relatively mild conditions used, indicating that the Arg-1-Ala+1 bond is probably the first to be cleaved during in vitro activation. The bovine carboxypeptidase activity was immediately and reversibly expressed upon dimethylmaleylation of the activation mixtures. This expression does not require full dissociation of the enzyme-peptide complex but merely a suitable change in its quaternary structure resulting from a modification of some electrostatic interactions upon dimethylmaleylation. Separation of bovine carboxypeptidase A from its activation peptide was only achieved upon filtration of the dimethylmaleylated mixtures in the presence of 6 M urea. The bovine activation peptide contains at least 93 amino acids compared to the 94 amino acids found by other authors for the rat and porcine peptides and sequencing of the first 53 amino acids showed a 75-85% homology with the latter two peptides.

The inactive subunit of ruminant procarboxypeptidase A-S6 complexes. Structural basis of inactivity and physiological role

Subunit III has so far been found only in the pancreas of ruminants in a non-covalent association (procarboxypeptidase A-S6) with two different proteins: the procarboxypeptidase A itself (subunit I) and a C-type chymotrypsinogen (subunit II). In contrast with these latter two proteins, which are zymogens of pancreatic proteases, subunit III seems to be devoid of any activity towards specific substrates of pancreatic proteases. However, it possesses a weakly functional active site which allows it to hydrolyze a non-specific ester, p-nitrophenyl acetate, and to react with several active-site titrants. The binding of proflavin to subunit III shows that this protein owns a non-polar binding site with a very high Kd compared to that of chymotrypsin. The comparison of the amino acid sequences of subunit III and some serine proteases showed that subunit III is closely related to an elastase. Models of the tertiary structure of subunit III suggest a conformational modification that affects the substrate binding and could explain the lack of specific enzymatic activity. The presence of subunit III in the ternary complex is not related to an enzymatic function. This protein does not participate in the activation process of subunit I but prevents the denaturation of this subunit at low pH. This may represent its biological role in the acidic environment of the duodenum in ruminants.

Amino acid sequence and disulfide bridges of subunit III, a defective endopeptidase present in the bovine pancreatic 6 S procarboxypeptidase A complex

The sequence of the 240 amino acids and the position of the five S-S bridges of subunit III of the bovine pancreatic 6 S procarboxypeptidase A complex have been determined thus confirming its phylogenetic filiation with the pancreatic serine endopeptidase group. The subunit contains at equivalent positions all the elements of the catalytic site of these enzymes. The elements of a binding pocket very similar to that of porcine elastase I are also present in the protein thus accounting for its zymogen-like activity. The most obvious difference is the absence in the subunit of the two strongly hydrophobic amino acids (16 and 17 in the chymotrypsinogen numbering), which are known to participate in the stabilization of a fully functional binding pocket in active endopeptidases. Four of the five disulfide bridges of subunit III are homologous with those common to all pancreatic endopeptidases. In contrast the fifth bridge forms a very small loop of only four amino acids, which is not encountered in active endopeptidases. Other potentially lethal modifications in the structure of the subunit are not excluded.

Active forms of chymotrypsin C isolated from autolyzed porcine pancreas glands

Four active forms of chymotrypsin C (C1, C2A, C2B, and C3) were isolated from the autolyzed porcine pancreas glands. Their molecular weights were estimated by SDS-polyacrylamide gel electrophoresis to be 29 100 for C1, 26 300 for C2A and C3, and 25 500 for C2B. The kinetic analyses of esterase activity of the enzymes toward Ac-LLeu-OEt and Ac-LPhe-OEt showed that chymotrypsin C1 hydrolyzed the two substrates more efficiently than did chymotrypsin C3. Chymotrypsin C1 consisted of chain A (H-Cys-...-Asn-OH, Mr 886) and chain BC (H-Val-...-Lys-OH, Mr 28 200). Chymotrypsin C3 consisted of the two components of C3L and C3S that could be dissociated in the presence of 2.3% SDS. C3L consisted of the chain A and the chain C (H-Ser-...-Lys-OH, Mr 13 600). C3S was the chain B (H-Val-...-Lys-OH, Mr 11 800). These kinetic and chemical analyses show that chymotrypsins C1 and C3 correspond to chymotrypsin A delta and A alpha, respectively.

Existence of ternary complexes of procarboxypeptidase A in the pancreas of some ruminant species

The existence of procarboxypeptidase A, in the form of a non-covalent ternary complex containing the apparently inactive serine protease (subunit III), has so far been observed only in the ox pancreas. Evidence, obtained in the present study, shows that a ternary complex of procarboxypeptidase A, with a subunit III highly homologous with that of the bovine complex, is also present in two other ruminant species, sheep and goat. The biological significance of these complex forms of procarboxypeptidase A and the consistently high biosynthesis level of the apparently inactive subunit III in all three ruminant species is still unknown. Yet the synthesis of subunit III is not related to the animal diet since in the horse, which is a non-ruminant herbivorous animal, the procarboxypeptidase A is monomeric. Reassociation assays between either bovine subunits II or III and monomeric as well as binary forms of procarboxypeptidase A from various species show that, unlike subunit II, the recognition site for subunit III is highly conserved in all the procarboxypeptidases A and that bovine subunit II is different from porcine chymotrypsinogen C with regard to association.

Two-step dissociation of bovine 6S procarboxypeptidase A by dimethylmaleylation

Reversible condensation of the ternary complex form of bovine pancreatic procarboxypeptidase A with 2,3-dimethyl maleic anhydride was investigated at pH 9.0 and low concentration of reagent over the acylable amino groups. After subsequent modification of only a few lysyl residues, subunit III was found to have been released from the quaternary structure leading to the separation of an apparently native protein devoid of any contaminating subunit II, while dissociation of the remaining binary complex occurred upon further addition of the anhydride. This observation suggests that the electrostatic interactions existing between subunits I and III are more rapidly weakened than those between subunits I and II, probably because fewer lysyl residues are involved and/or there is greater accessibility to the chemical reagent . Although completely inactive on the specific substrates of trypsin, chymotrypsin and elastase, subunit III hydrolyzed p-nitrophenyl acetate at a rate similar to that of chymotrypsin but without any burst of p-nitrophenol, which indicates that the weakly functional active site of the subunit is not quite comparable to that of serine protease zymogens. Subunit III already has some of the functional characteristics of the corresponding active enzymes.

Isolation and re-association of the subunits from the pro-(carboxypeptidase A)-pro-(proteinase E) binary complex from pgi pancreas

The component subunits of the pro-(carboxypeptidase A)-pro-(proteinase E) binary complex from pig pancreas were separated with a high recovery (80-95%) of their original potential activity. The isolated subunits and the reconstituted complex have properties similar to those of the corresponding natural species. The tryptic activation course of the pro-(carboxypeptidase A) subunit is substantially modified when bound to pro-(proteinase E), whereas the activation of pro-(proteinase E) is not dependent on this association.

Further characterization of subunit III of bovine procarboxypeptidase A-S6 as a non activatable zymogen

The homology of Subunit III of bovine procarboxypeptidase A-S6 (EC 3.4.12.-) with Subunit II (bovine chymotrypsinogen C) of the same complex, already reported in a previous publication (Puigserver, A. and Desnuelle, P. (1975) Proc. Natl. Acad. Sci. U.S. 72, 2442-2445) has been extended to the position of the single methionine of the chains. The sequence linked by 4 disulfide bridges out of 5 are also probably homologous in the 2 proteins. The last bridge is displaced in Subunit III as a consequence of the deletion of the N-terminal half-cystine. Subunit II, which is not activatable by trypsin, due to the loss of essential residues in the N-terminal region, has conserved a weakly functional active site reacting with concentrated diisopropylfluorophosphate at exactly the same rate as that of Subunit II.