Identification of a procarboxypeptidase A-truncated protease E binary complex in human pancreatic juice

The characterization, in human pancreatic juice, of a binary complex associating procarboxypeptidase A with a 32 kDa inactive glycoprotein (G32) is reported in this paper. Free G32 was isolated after dissociation of the binary complex. N-terminal sequence analysis revealed a complete homology between this protein and human protease E (HPE 1), except for the two strongly hydrophobic N-terminal residues (Val-Val) which are missing in G32. This protein might be a truncated protease E highly analogous to the subunit III of the ruminant procarboxypeptidase A-S6 ternary complex. The analogy with bovine subunit III is further supported by interspecies reassociation experiments showing that bovine procarboxypeptidase A can specifically bind human G32.     

Crystal structure of bovine procarboxypeptidase A-S6 subunit III, a highly structured truncated zymogen E.

Subunit III, a defective serine endopeptidase lacking the typical N-terminal hydrophobic dipeptide is secreted by the pancreas of ruminant species as part of the bovine ternary complex procarboxypeptidase A-S6. Two monoclinic crystal forms were obtained and subsequently used to solve its X-ray structure. The highest resolution model of subunit III was refined at 1.7 A resolution to a crystallographic R-factor of 18.4%, with r.m.s. bond deviations from ideality of 0.012 A. About 80% of the model presents the characteristic architecture of trypsin-like proteases. The remaining zones, however, have well-defined, unique conformations. The regions from residues 70 to 80 and from 140 to 155 present maximum distances of 16 and 18 A relative to serine proteases and zymogens. Comparisons with the structures of porcine elastase 1 and chymotrypsinogen A indicate that the specific binding pocket of subunit III adopts a zymogen-like conformation and thus provide a basis for its inactivity. In general, the structural analysis of subunit III strongly suggests that it corresponds to a truncated version of a new class of highly structured elastase-like zymogen molecules. Based on the structures of subunit III and elastase 1, it is concluded that large concerted movements are necessary for the activation of zymogen E.     

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 reagant. 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.     

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.     

Autolysis of proproteinase E in bovine procarboxypeptidase A ternary complex gives rise to subunit III

Extracts of bovine pancreatic tissue are shown by HPLC to contain two distinct ternary complexes of procarboxypeptidase A (subunit I), chymotrypsinogen C (subunit II) and either proproteinase E or subunit III. It is shown that proproteinase E in the complex generates subunit III by removal of 13 N-terminal residues when the former is allowed to autolyze in solution or when catalytic amounts of isolated active proteinase E are added to it. Autolysis of proproteinase E was accompanied by the loss of potential activity towards specific synthetic substrates and occurred at a higher rate in pancreatic juice than in pancreatic tissue extracts, even when both were processed in the presence of serine protease inhibitors. We conclude that subunit III (also called truncated protease E) is an autolytic product of proproteinase E and not an ab initio component of the native ternary complex.     

Morphology of the procarboxypeptidase A-S6 complex

Bovine pancreatic procarboxypeptidase A is secreted as a non-covalent association of three different proteins (pro CPA-S6). The free native subunits can be obtained by dissociation of the complex by dimethylmaleylation. Moreover, two specific binary complexes resulting from the high affinity of procarboxypeptidase A (subunit I) for its other two partners (subunits II and III) can also be obtained.In order to better understand the function of the association, an investigation of the morphology of the ternary complex by solution X-ray scattering has been carried out. The radii of gyration of all the molecular species have been obtained and the experimental results have been interpreted in terms of compact objects of simple shape. The various components correspond to globular particles as shown by the value of the ratio Rg/M^1/3. This is confirmed by the moderate anisotropy of the simple geometric shapes determined using an assumed value of 0.3 g H₂O/g protein for the hydration. The distances between the centres of gravity of pairs of species strongly suggest that the components are in the closest distance configuration or close to it. However, the binary complex I–III appears to be more open than the complex I–II. Finally, a model of the interaction between carboxpeptidase A and its activation peptide has been constructed by comparing the hypothetical geometric model of subunit I to the crystallographically determined structure of carboxypeptidase A.Abbreviations pro CPA procarboxypeptidase A - pro CPA-S6 (or T.C.) ternary complex with a sedimentation coefficient of 6S - CPA carboxypeptidase A     

Generation of a subunit III-like protein by autolysis of human and porcine proproteinase e in a binary complex with procarboxypeptidase A

Tryptic treatment of human and porcine proproteinase E, procarboxypeptidase A binary complexes gave rise to active proteinase E after removal of an 11-residue N-terminal activation peptide. By contrast, upon treatment of either complex with active proteinase E, not only was the activation peptide released but also the hydrophobic dipeptide Val12-Val13 of the corresponding enzyme. No serine protease activity on specific synthetic peptide substrates could be detected. The structural homology of inactive proteinase E with subunit III of ruminant procarboxypeptidase A was strengthened by the existence of a functional homology since truncated proteinase E still possessed a weakly functional active site. Thus, subunit III-like proteins are generated by proteinase E-catalyzed limited proteolysis of proproteinase E.     

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.     

Spectrofluorimetric investigation of the interactions between the subunits of bovine pancreatic procarboxypeptidase A-S6

A spectrofluorimetric investigation of the interactions between the subunits of the pancreatic bovine procarboxypeptidase A ternary complex was carried out after covalent insertion of a fluorescent probe at the active center of one of the constituent subunits. The specific insertion of an anthraniloyl group at the active center of subunit II free or bound to subunit I, after its conversion into chymotrypsin II, allowed us to determine the value of the dissociation constant between subunit I and anthraniloyl-chymotrypsin II (Kd = 0.7 +/- 0.1 x 10(-7) M) and between subunit III and the binary complex subunit I-anthraniloyl-chymotrypsin II (Kd = 1.6 +/- 0.3 x 10(-7) M). Moreover, the influence of the association on the flexibility of the active center of chymotrypsin II was deduced from fluorescence polarization measurements and rotational correlation time determination of anthraniloyl-chymotrypsin II free or bound to subunit I. The anthraniloyl group has no motion independently of the whole chymotrypsin II molecule and the binding of subunit I to anthraniloyl-chymotrypsin II results in an increase of the rigidity of the active site in the latter protein.     

Subunit III of ruminant procarboxypeptidase A-S6 complexes and pancreatic proteases E. A new family of pancreatic serine endopeptidases?

Subunit III (BSIII) of the bovine ternary complex of procarboxypeptidase A-S6 (PCPA-S6), a defective serine endopeptidase-like protein, actively synthesized by the pancreas of some ruminant species, is highly homologous to human protease E (HPE). Both proteins possess the same atypical disulfide bridge in position 98-99b. They are structurally related to porcine elastase 1 and human elastase 2 (about 56% identity). However, in contrast to those two enzymes which have an overall positive net charge, BSIII and HPE are negatively charged. Three-dimensional models of BSIII and HPE have been constructed from the crystallographic structure of porcine pancreatic elastase 1. The inhibitor-binding site for TFAI in these three proteins seems to be very similar; the atypical disulfide bridge does not seem to be involved in this binding site. The specific structural features of BSIII and HPE strongly support the assumption that BSIII is a truncated protease E and that both proteins belong to a separate serine endopeptidase family.     

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.     

Subunit III of bovine procarboxypeptidase A: its relationship to human pancreatic elastase 1

This paper is a continuation of our study of various animal pancreatic enzymes which are related to human pancreatic elastase 1 (Sziegoleit, A. & Linder, D. (1986) Biol. Chem. Hoppe-Seyler, 367, 527-531). The isolation and immunological analysis of the related protein from bovine pancreas disclosed that the third subunit of the procarboxypeptidase A complex is the antibody-binding component. The similarity of this subunit to elastase 1 is affirmed by comparison of their primary structures. While the complete amino-acid sequence of bovine subunit III recently has been published (Venot, N., Sciaky, M., Puigserver, A., Desnuelle, P. & Laurent, G. (1986) Eur. J. Biochem. 157, 91-99), we here present the amino-acid sequence of the carboxy-terminal tryptic peptide of human pancreatic elastase 1 showing a high degree of homology.     

Reconstitution of bovine procarboxypeptidase A-S6 from the free subunits

The three subunits I, II, and III of bovine procarboxypeptidase A separated by reversible dimethylmaleylation can reassociate to form the reconstituted complexes I + II, I + III, and I + II + III. Since the association II + III is not possible, subunit I appears to play a central role in the formation of the complex. It is suggested that subunit I possesses two independent and specific sites for the recognition of subunits II and III. The liberation of subunit I from any of the complexes was observed to increase its activability, although to a lesser extent than predicted by assays carried out with the succinylated protein. By contrast, the bound form of subunit II was activated faster than the free form. The potential activity of the bound form and the activity of the preformed endopentidase were also higher, suggesting a conformational change induced by association. This suggestion was fully supported by the observed modifications of the heat stability and intrinsic fluorescence spectrum of the subunit resulting form association.     

Complex mitochondrial DNA in Drosophila.

The larval mtDNA isolated from D. virilis, D. simulans and D. melanogaster exists in complex molecular forms in addition to the simple monomeric circular form. The frequency of circular dimers and oligomers is highly elevated in apparently normal larval tissues. These complex forms of mtDNA are separable on agarose gels. Hind III restriction endonuclease and electron microscopic analyses used in the present study have revealed that circular dimers are simply the circular concatemers of two monomeric circles which are arranged in a head-to-tail structure with no detectable heterologous regions such as insertions or deletions. The electrophoretic patterns of Hind III digested mtDNAs of D. simulans and D. melanogaster (sibling species) are identical and distinguishable from that of distantly related species, D. virilis.     

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.     

Sequential homologies between procarboxypeptidases A and B from porcine pancreas

Automated Edman degradation of monomeric procarboxypeptidases A and B from porcine pancreas shows that their N-terminal regions (from residue 1 to 34-37) present a high degree of sequential homology to each other as well as to other related procarboxypeptidases. Conformational predictions based on these sequences confirm their structural homology and indicate the probable existence of two beta-turns, one beta-chain and a long alpha-helix in them. On the other hand, tryptic peptide maps on a reverse-phase column indicate great sequential similarities (if not identity) between monomeric procarboxypeptidase A and the procarboxypeptidase A subunit isolated from its binary complex with proproteinase E.     

The three-dimensional structure of the native ternary complex of bovine pancreatic procarboxypeptidase A with proproteinase E and chymotrypsinogen C.

The metalloexozymogen procarboxypeptidase A is mainly secreted in ruminants as a ternary complex with zymogens of two serine endoproteinases, chymotrypsinogen C and proproteinase E. The bovine complex has been crystallized, and its molecular structure analysed and refined at 2.6 A resolution to an R factor of 0.198. In this heterotrimer, the activation segment of procarboxypeptidase A essentially clamps the other two subunits, which shield the activation sites of the former from tryptic attack. In contrast, the propeptides of both serine proproteinases are freely accessible to trypsin. This arrangement explains the sequential and delayed activation of the constituent zymogens. Procarboxypeptidase A is virtually identical to the homologous monomeric porcine form. Chymotrypsinogen C displays structural features characteristic for chymotrypsins as well as elastases, except for its activation domain; similar to bovine chymotrypsinogen A, its binding site is not properly formed, while its surface located activation segment is disordered. The proproteinase E structure is fully ordered and strikingly similar to active porcine elastase; its specificity pocket is occluded, while the activation segment is fixed to the molecular surface. This first structure of a native zymogen from the proteinase E/elastase family does not fundamentally differ from the serine proproteinases known so far.     

Crystallization and preliminary X-ray study of subunit III of the bovine pancreatic procarboxypeptidase A-S6 ternary complex

Subunit III of the bovine pancreatic procarboxypeptidase A-S6 ternary complex was dissociated from the complex, purified and crystallized using the hanging- or sitting-drop method of vapour diffusion, with ammonium sulphate as the precipitant. The assays were carried out at pH 4.2 (20 mM-acetate buffer). An X-ray examination of the crystals shows that they are monoclinic, with a space group P21 and cell dimensions a = 47.9 A, b = 61.3 A, c = 39.0 A and beta = 95.0 degrees. The asymmetric unit contains one molecule of 25,800 Mr. The crystals are suitable for structure determination to at least 2.8 A resolution.     

Comparison between the monomeric and binary-complex forms of procarboxypeptidase A from whole pig pancreas.

Two different forms of procarboxypeptidase A (I and II) were obtained from pig pancreas extracts. The Mr values, the pattern found on polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate, and the sedimentation coefficients indicate that form I is a binary complex formed by two different subunits, whereas form II is a monomer. The carboxypeptidase A-precursor subunit of form I and the form II monomer are very similar with respect to Mr value, amino acid composition and fragmentation by CNBr and iodosobenzoic acid. The activation process of both forms is unspecific with respect to the activating enzyme, the peptide released during activation is unusually long (Mr approx.sor subunit of form I and the form II monomer are very similar with respect to Mr value, amino acid composition and fragmentation by CNBr and iodosobenzoic acid. The activation process of both forms is unspecific with respect to the activating enzyme, the peptide released during activation is unusually long (Mr approx.sor subunit of form I and the form II monomer are very similar with respect to Mr value, amino acid composition and fragmentation by CNBr and iodosobenzoic acid. The activation process of both forms is unspecific with respect to the activating enzyme, the peptide released during activation is unusually long (Mr approx. 12500) and, in the case of the binary complex, the activation with trypsin follows a rather complex pattern, suggesting that the accompanying subunit of form I might play a modulating role in the activation process. Although the appearance of enzymic activity is rather slow, a protein with an Mr equivalent to that of active carboxypeptidase A is found very early in the activation process. Both zymogens are glycoproteins (so far no carbohydrate has been reported in any procarboxypeptidase A) and both contain two strongly bound Zn2+ ions/molecule. Other chemical and physical properties were also determined.     

The subunit composition of Portunus trituberculatus hemocyanin polymers

The subunit composition of isolated polymeric forms of Portunus trituberculatus hemocyanin were analysed by immunological techniques. The dodecamers contain four monomeric subunits corresponding to subunits I, II, III and IV, whereas the hexamers are devoid of subunit IV. These results suggest that subunit IV is required as a joining piece for the assembly of dodecamers.