Proteolysis of factor Va by factor Xa and activated protein C

Bovine Factor Va, produced by selective proteolytic cleavage of Factor V by thrombin, consists of a heavy chain (D chain) of Mr = 94,000 and a light chain (E chain) of Mr = 74,000. These peptides are noncovalently associated in the presence of divalent metal ion(s). Each chain is susceptible to proteolysis by activated protein C and by Factor Xa. Sodium dodecyl sulfate electrophoretic analysis indicates that cleavage of the E chain by either activated protein C or Factor Xa yields two major fragments: Mr = 30,000 and Mr = 48,000. Amino acid sequence analysis indicates that the Mr = 30,000 fragments have identical NH2-terminal sequences and that this sequence corresponds to that of intact E chain. The Mr = 48,000 fragments also have identical NH2-terminal sequences, indicating that activated protein C and Factor Xa cleave the E chain at the same position. Sodium dodecyl sulfate electrophoretic analysis indicates that activated protein C cleavage of the D chain yields two products: Mr = 70,000 and Mr = 24,000. Amino acid sequence analysis indicates that the Mr = 70,000 fragment has the same NH2-terminal sequence as intact D chain, whereas the Mr = 24,000 fragment does not. Factor Xa cleavage of the D chain also yields two products: Mr = 56,000 and Mr = 45,000. The Mr = 56,000 fragment corresponds to the NH2-terminal end of the D chain and Factor V. Functional studies have shown that both chains of Factor Va may be entirely cleaved to products by Factor Xa without loss of activity, whereas activated protein C cleavage results in loss of activity. Since activated protein C and Factor Xa cleave the E chain at the same position, the cleavage of the D chain by activated protein C is responsible for the inactivation of Factor Va.     

Mechanism-based fragmentation of coenzyme A transferase. Comparison of alpha 2-macroglobulin and coenzyme A transferase thiol ester reactions

The plasma proteins, alpha 2-macroglobulin and complement components 3 and 4, contain an internal thiol ester involving a glutamyl and cysteinyl residue. The thiol ester is susceptible to cyclization at greater than 37 degrees C and forms an unstable 5-oxyproline intermediate. The latter can be hydrolyzed to produce two peptide fragments. We propose that enzymes having activated glutamyl residues as part of their catalytic mechanisms may undergo an analogous cyclization and peptidyl cleavage. As a model, we have investigated pig heart succinyl-CoA:3-keto acid transferase. When the CoA-enzyme thiolester intermediate is heated at pH 7.4 and 70 degrees C for 1 h, approximately 60% of the Mr = 60,000 subunits are cleaved to give Mr = 40,000 and 20,000 fragments. We have shown that formation of the enzyme thiolester is an obligate precursor for the protein fragmentation. However, the reaction was incomplete with a maximum of approximately 65% cleavage at times greater than 60 min. These results suggest that there is a competing, deactivation reaction; namely, the thiol ester and oxyproline intermediates are hydrolyzed to regenerate the active site glutamic acid. Although the maximum rate of cleavage is at 70 degrees C, approximately 15% autolysis also occurs at 37 degrees C. The Mr = 40,000 fragment had the same amino terminal sequence as the Mr = 60,000 subunit, (Trp-Lys-Phe-Tyr-Thr-Asp-Ala-Val-Glu-Ala-). No amino terminal could be detected for the Mr = 20,000 fragment, even after digesting the fragment with pyroglutaminase. Peptide maps of the fragments and the uncleaved subunit indicate that the fragments are generated in parallel. The size of the fragments puts the active site about two-thirds of the way from the amino terminal of the protein.     

The amino acid sequence of Escherichia coli cyanase

The amino acid sequence of the enzyme cyanase (cyanate hydrolase) from Escherichia coli has been determined by automatic Edman degradation of the intact protein and of its component peptides. The primary peptides used in the sequencing were produced by cyanogen bromide cleavage at the methionine residues, yielding 4 peptides plus free homoserine from the NH2-terminal methionine, and by trypsin cleavage at the 7 arginine residues after acetylation of the lysines. Secondary peptides required for overlaps and COOH-terminal sequences were produced by chymotrypsin or clostripain cleavage of some of the larger peptides. The complete sequence of the cyanase subunit consists of 156 amino acid residues (Mr 16,350). Based on the observation that the cysteine-containing peptide is obtained as a disulfide-linked dimer, it is proposed that the covalent structure of cyanase is made up of two subunits linked by a disulfide bond between the single cystine residue in each subunit. The native enzyme (Mr 150,000) then appears to be a complex of four or five such subunit dimers.     

Escherichia coli heat-labile enterotoxin. Nucleotide sequence of the A subunit gene

We report the complete DNA sequence of the Escherichia coli elt A gene, which codes for the A subunit of the heat-labile enterotoxin, LT. The amino acid sequence of the LT A subunit has been deduced from the DNA sequence of elt A. The LT A subunit starts with methionine, ends with leucine, and comprises 254 amino acids. The computed molecular weight of LT A is 29,673. The A subunit of cholera toxin (CT A) has been shown to be structurally and functionally related to the LT A subunit. Comparison of the primary structure of LT A with the known partial amino acid sequence of CT A indicates that the 2 polypeptides share considerable homology throughout their sequences. The NH2-terminal regions exhibit the highest degree of homology (91%), while the COOH-terminal region, containing the sole cystine residue in each toxin is less conserved (approximately 52%). Alignment of homologous residues in the COOH-terminal regions of LT A and CT A indicates that a likely site for proteolytic cleavage of LT A is after Arg residue 188. The resulting A2 polypeptide would be 46 amino acids long, would contain a single cysteine residue, and have Mr = 5261. The elt A nucleotide sequence further predicts that the LT A protein is synthesized in a precursor form, possessing an 18-amino acid signal sequence at its NH2 terminus.     

The role of subunit autolysis in activation of smooth muscle Ca2+-dependent proteases

Ca2+-dependent proteases isolated from chicken gizzard and bovine aortic smooth muscle were compared with respect to subunit autolysis and the role of autolysis in modulating enzyme activity. The protease isolated from chicken gizzard was a heterodimer consisting of 80,000- and 30,000-dalton subunits. The protease isolated under identical conditions from bovine aorta consisted of 75,000- and 30,000-dalton subunits. In the presence of Ca2+, both enzymes underwent autolysis of their 30,000-dalton subunits with conversion to an 18,000-dalton species. In addition, the 80,000-dalton subunit of the gizzard protease was degraded to a 76,000-dalton form. The Ca2+ concentrations required for autolysis of the 30,000-dalton subunits were different for the two enzymes (i.e. gizzard: K0.5 Ca2+ = 335 microM; aortic: K0.5 Ca2+ = 1,250 microM) although in both cases, stimulation of autolysis by Ca2+ exhibited positive cooperativity. When compared with respect to kinetics of substrate degradation, the native forms of the smooth muscle Ca2+-dependent proteases (gizzard, GIIa = 80,000/30,000-dalton heterodimer; bovine aortic, IIa = 75,000/30,000-dalton heterodimer) exhibited a lag phase in product appearance. On the other hand, the autolyzed forms (gizzard, GIIb = 76,000/18,000-dalton heterodimer; bovine aortic, IIb = 75,000/18,000-dalton heterodimer) exhibited linear rates of substrate degradation. These results were analyzed in terms of autolysis of the 30,000-dalton subunits as determined by the conversion of this subunit to its 18,000 dalton form. For both enzymes, the time course for the autolytic transition, 30,000----18,000 daltons, and Ca2+-dependence of the apparent rate constants for this transition were found to correlate well with the lag phase in enzymatic activity. No such correlation could be established for the 80,000----76,000 dalton autolytic transition of the high molecular mass subunit of the gizzard protease. Our results suggest that catalytic activity of the Ca2+-dependent proteases isolated from gizzard and bovine aortic smooth muscle requires autolysis of the 30,000-dalton subunit. The native or unautolyzed forms of these enzymes appear to be proenzymes that can be activated by autolysis.     

Monoclonal antibodies as structural probes of surface residues in the regulatory subunit of cAMP-dependent protein kinase II from porcine heart

Two murine monoclonal antibodies (H5 and B6) generated against bovine heart type II regulatory subunit of cAMP-dependent protein kinase were shown to cross-react equally well with the homologous subunit from porcine heart. The antibodies demonstrated specificity for only the type II regulatory subunit and showed negligible cross-reactivity with the type I regulatory subunit, the catalytic subunit, and cGMP-dependent protein kinase. Following limited proteolysis of type II regulatory subunit with chymotrypsin, the H5 monoclonal antibody was shown to cross-react with the Mr = 37,000 cAMP-binding domain corresponding to the COOH-terminal region of the polypeptide chain. To more specifically localize the antigenic sites, the porcine type II regulatory subunit was carboxymethylated and cleaved with cyanogen bromide. Both monoclonal antibodies cross-reacted with the NH2-terminal CNBr peptide, and this peptide demonstrated affinities similar to native bovine type II regulatory subunit in competitive displacement radioimmunoassays. Tryptic cleavage of this CNBr fragment destroyed all antigenicity for both monoclonal antibodies, whereas antigenicity was retained following chymotryptic digestion. A single major immunoreactive chymotryptic fragment that cross-reacted with H5 was isolated by gel filtration and reverse phase high performance liquid chromatography. this peptide retained the complete antigenic site and had the following sequence: Asn-Pro-Asp-Glu-Glu-Glu-Glu-Asp-Thr-Asp-Pro-Arg-Val-Ile-His-Pro-Lys-Thr-Asp-Gl n. This antigenic site was localized just beyond the major site of autophosphorylation, approximately a third of the distance from the NH2-terminal end of the polypeptide chain.     

Two-stage autolysis of the catalytic subunit initiates activation of calpain I

Calcium-induced autolysis of bovine erythrocyte calpain I occurs in multiple stages. Initially, a 14 amino acid segment is cleaved from the N-terminus of the native 80 kDa catalytic subunit, yielding a 78 kDa form of the subunit. Then, an additional 12 amino acid segment is cleaved from the N-terminus, forming a 76 kDa subunit. The 76 kDa enzyme is the active form of the catalytic subunit that is able to proteolyze the 30 kDa regulatory subunit as well as exogenous substrates. While the initial autolytic step requires high calcium, the 76 kDa enzyme form is active in microM calcium and can cleave the amino termini of native 80 kDa and intermediate 78 kDa enzyme forms at low calcium. Both intramolecular and intermolecular proteolysis of the catalytic subunit appear to yield the same products.     

Location of a dicyclohexylcarbodiimide-reactive glutamate residue in the Neurospora crassa plasma membrane H+-ATPase

The proton pump (H+-ATPase) found in the plasma membrane of the fungus Neurospora crassa is inactivated by dicyclohexylcarbodiimide (DCCD). Kinetic and labeling experiments have suggested that inactivation at 0 degrees C results from the covalent attachment of DCCD to a single site in the Mr = 100,000 catalytic subunit (Sussman, M. R., and Slayman, C. W. (1983) J. Biol. Chem. 258, 1839-1843). In the present study, when [14C]DCCD-labeled enzyme was treated with the cleavage reagent, N-bromosuccinimide, a single major radioactive peptide fragment migrating at about Mr = 5,300 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis was produced. The fragment was coupled to glass beads and partially sequenced by automated solid-phase Edman degradation at the amino terminus and at an internal tryptic cleavage site. By comparison to the DNA-derived amino acid sequence for the entire Mr = 100,000 polypeptide (Hager, K., and Slayman, C. W. (1986) Proc. Natl. Acad. Sci. U. S. A. 83, 7693-7697), the fragment has been identified as arising by cleavage at tyrosine 100 and tryptophan 141. Covalently incorporated [14C]DCCD was released at a position corresponding to glutamate 129. The DCCD-reactive glutamate is located in the middle of the first of eight predicted transmembrane sequences. When the sequence surrounding the DCCD site is compared to that surrounding the DCCD-reactive residue of two other proton pumps, the F0F1-ATPase and cytochrome c oxidase, no homology is apparent apart from an abundance of hydrophobic amino acids.     

Autolytic transition of mu-calpain upon activation as resolved by antibodies distinguishing between the pre- and post-autolysis forms.

A novel method to observe the autolytic activation of a mammalian cytoplasmic calcium protease, mu-calpain, was developed using a set of antipeptidic antibodies capable of distinguishing between the pre- and post-autolysis forms of the enzyme. Antibodies raised against synthetic peptides designed to match the N-terminal sequences of the pre- and post-autolysis forms of the mu-calpain large subunit reacted specifically with the corresponding form of calpain and not with the other. The antibodies were specific and sensitive enough to detect the antigens in crude cell lysates. The relevance of the immunochemical detection of calpain activation was confirmed by the observation that proteolysis of a substrate protein by purified mu-calpain paralleled autolysis at various pCa as probed by these antibodies and that autolysis preceded substrate proteolysis. We also observed calcium-dependent autolysis of calpain accompanying subsequent proteolysis of substrate in intact cells using the antibodies. The method will provide a novel approach to assess the physiological targets of the enzyme by determining the local intracellular sites of calpain activation.     

Lipopolysaccharide-sensitive serine-protease zymogen (factor C) of horseshoe crab hemocytes. Identification and alignment of proteolytic fragments produced during the activation show that it is a novel type of serine protease

The horseshoe crab clotting factor, factor C, present in the hemocytes is a serine-protease zymogen activated with lipopolysaccharide. It is a two-chain glycoprotein (Mr = 123,000) composed of a heavy chain (Mr = 80,000) and a light chain (Mr = 43,000) [T. Nakamura et al. (1986) Eur. J. Biochem. 154, 511-521]. In our continued study of this zymogen, we have now also found a single-chain form of factor C (Mr = 123,000) in the hemocyte lysate. The heavy chain had the NH2-terminal sequence of Ser-Gly-Val-Asp-, consistent with that of the single-chain factor C, indicating that the heavy chain is derived from the NH2-terminal part of the molecule. The light chain had an NH2-terminal sequence of Ser-Ser-Gln-Pro-. Incubation of the two-chain zymogen with lipopolysaccharide resulted in the cleavage of a Phe-Ile bond between residues 72 and 73 of the light chain. Concomitant with this cleavage, the A (72 amino acid residues) and B chains derived from the light chain were formed. The complete amino acid sequence of the A chain was determined by automated Edman degradation. The A chain contained a typical segment which is similar in sequence to a family of repeats in human beta 2-glycoprotein I, complement factors B, protein H, C4b-binding protein, and coagulation factor XIII b subunit. The NH2-terminal sequence of the B chain was Ile-Trp-Asn-Gly-. This chain contained the serine-active site sequence-Asp-Ala-Cys-Ser-Gly-Asp-Ser-Gly-Gly-Pro-. These results indicate that horseshoe crab factor C exists in the hemocytes in a single-chain zymogen form and is converted to an active serine protease by hydrolysis of a specific Phe-Ile peptide bond.     

Identification and characterization of a phospholipid-binding site of bovine factor Va

Coagulation factor Va is a cofactor which combines with the serine protease factor Xa on a phospholipid surface to form the prothrombinase complex. The phospholipid-binding domain of bovine factor Va has been reported to be located on the light chain of the molecule and more precisely on a fragment of Mr = 30,000 which is obtained after digestion of factor Va light chain by factor Xa. This proteolytic fragment is located in the NH2-terminal part of factor Va light chain (residues 1564-1765). In order to further characterize the lipid-binding domain of bovine factor Va, isolated bovine light chain was preincubated with synthetic phospholipid vesicles (75% phosphatidylcholine, 25% phosphatidylserine) and digested with trypsin, chymotrypsin, and elastase. Two peptide regions protected from proteolytic cleavage were identified and characterized from each proteolytic digestion. A comparison of the NH2-terminal sequence and amino acid composition of the two tryptic peptides with the deduced sequence of human factor V indicates a match with residues 1657-1791 of the light chain of human factor V for one peptide and residues 1546-1656 for the other peptide. When chymotrypsin or elastase were used for digestion, the NH2-terminal sequence of one peptide showed a match with residues 1667-1797 of the light chain, while the other peptide presented an NH2-terminal sequence identical with the previously described for the bovine factor Va light chain. When these peptides were assayed for direct binding to phospholipid vesicles, only the tryptic and the chymotryptic peptides covering the middle region of the A3 domain of the bovine factor Va light chain demonstrated an ability to interact with phospholipid vesicles. Thus, knowing that the factor Xa cleavage site on the factor Va light chain is located between residues 1765 and 1766 of the light chain this lipid-binding region of the bovine factor Va is further localized to amino acid residues 1667-1765.     

Structure of alpha-polymer from in vitro and in vivo highly cross-linked human fibrin.

Peptides derived from plasmic and cyanogen bromide (CNBr) cleavage of highly cross-linked fibrin were isolated and characterized by sodium dodecyl sulfate-gel electrophoresis, amino acid analyses, cyanoethylation, and NH2-terminal analyses. Extended plasmic digestions of human fibrin containing four epsilon-(gamma-glutamyl)lysine cross-links per molecule produced a peptide of alpha-chain origin (Mr congruent to 21,000) which was comprised of a small donor peptide cross-linked to the acceptor site peptide from the middle of the alpha-chain. CNBr cleavage of highly cross-linked in vitro fibrin or of fibrin from a spontaneously formed in vivo arterial embolus produced about three cross-linked species of molecular weights 30,000 to 40,000, each of which contained the largest CNBr fragment (Mr = 29,000) from the alpha-chain. The predominant cross-link-containing CNBr fragments derived their donor group from the near COOH-terminal region of the alpha-chain as judged by difference amino acid compositions and NH2-terminal analyses. Additionally, cross-linked fragments of molecular weights 68,000 to 70,000 which appeared to contain two acceptor site peptides (Mr = 29,000) were detected in minor amounts in the CNBr digests of fibrin formed from whole plasma or from purified, plasminogen-free fibrinogen. No larger polymeric cross-linked CNBr fragment was generated from any of the highly cross-linked fibrin preparations examined. A model for the predominant mode of alpha-chain polymerization is proposed.     

Limited autolysis reduces the Ca2+ requirement of a smooth muscle Ca2+-activated protease

Chicken gizzard smooth muscle contains large amounts of Ca2+-activated protease activity. Approximately 15 mg of purified enzyme can be obtained from 1 kg of fresh muscle. The enzyme consists of two subunits (Mr = 80,000 and 30,000) present in a 1:1 molar ratio. In the presence of CaCl2, the 80,000/30,000-dalton heterodimer (form I) is rapidly converted by limited autolysis to a 76,000/18,000-dalton species (form II). Both the 80,000- and 30,000-dalton subunits are degraded simultaneously. Moreover, the Ca2+ dependence for autolysis (K0.5 = 300 microM) is identical for both subunits. Neither the time course nor the Ca2+ dependence of the autolytic conversion reaction is altered by 10- and 20-fold molar excesses of substrate. Limited autolysis markedly reduces the Ca2+ requirement for substrate degradation. Using N-[ethyl-2-3H]maleimide-labeled 27,000-dalton cardiac myosin light chains as substrate, the Ca2+ requirement of form I was found to be quite high (K0.5 = 150 microM). Under similar conditions, the Ca2+ requirement of form II was 30-fold lower (K0.5 = 5 microM). Limited autolysis did not alter the specific activity of the enzyme. Our results demonstrate that smooth muscle contains an abundant amount of Ca2+-activated protease. Moreover, autolysis of this enzyme may play an important regulatory role by converting the native form to a species that is fully active at physiological levels of intracellular calcium ion.     

The nuclear-coded subunits of yeast cytochrome c oxidase. II. The amino acid sequence of subunit VIII and a model for its disposition in the inner mitochondrial membrane

The amino acid sequence of subunit VIII from yeast cytochrome c oxidase is reported. This 47-residue (Mr = 5364) amphiphilic polypeptide has a polar NH2 terminus, a hydrophobic central section, and a dilysine COOH terminus. An analysis of local hydrophobicity and predicted secondary structure along the peptide chain predicts that the hydrophobic central region is likely to be transmembranous. Subunit VIII from yeast cytochrome c oxidase exhibits 40.4% homology to bovine heart cytochrome c oxidase subunit VIIc , at the level of primary structure. Secondary structures and hydrophobic domains predicted from the sequences of both polypeptides are also highly conserved. From the location of hydrophobic domains and the positions of charged amino acid residues we have formulated a topological model for subunit VIII in the inner mitochondrial membrane.     

Biosynthesis of a lysosomal enzyme. Partial structure of two transient and functionally distinct NH2-terminal sequences in cathepsin D

Various biosynthetic forms of porcine spleen cathepsin D (Erickson, A. H. and Blobel, G. (1979) J. Biol. Chem. 254, 11771-11774), isolated by immunoprecipitation of in vivo- and in vitro-synthesized products, have been characterized by partial NH2-terminal sequence analysis. Two short lived and functionally distinct NH2-terminal sequence extensions, a "pre" sequence and a "pro" sequence, have been detected. Both sequence extensions are present in preprocathepsin D which is the primary translation product immunoprecipitated after translation of porcine spleen mRNA in a wheat germ cell-free system. Preprocathepsin D is not glycosylated and has an approximate Mr = 43,000. Its 20-residue pre sequence resembles the signal sequences of presecretory proteins in abundance of Leu residues (7 out of 20 residues). Addition of dog pancreatic microsomal vesicles to the translation system resulted in the cleavage of the pre sequence and yielded segregated and glycosylated procathepsin D (Mr = 46,000) that was indistinguishable from its in vivo-synthesized counterpart detected after pulse-labeling of cultured porcine kidney cells. Some of this in vivo-synthesized procathepsin D was secreted and persisted as such in the culture medium. The remainder was converted within a period of 15 min to 2 h to single chain cathepsin D (Mr = 44,000) by removal of a pro sequence which was estimated to be 44 residues. Its partial sequence showed considerable sequence homology to the 44-residue activation peptide of pepsinogen. It is possible, therefore, that the prosequence of procathepsin D serves as an activation peptide that keeps the enzyme inactive during intracellular transport to the lysosome. The enzymatically active single chain form of cathepsin D undergoes further cleavage into a light and a heavy chain (Mr = 15,000 and 30,000, respectively) over a period of 2-24 h after synthesis. The oligosaccharide moieties of procathepsin D and of the single chain and heavy chain forms of cathepsin D are cleaved by endoglycosidase H. Treatment of cells with tunicamycin arrests the biosynthetic pathway of cathepsin D at procathepsin D. The nonglycosylated procathepsin D is not proteolytically processed and its secretion is greatly inhibited.     

Regulatory domains of erythrocyte ankyrin

This report provides evidence for regulatory domains of erythrocyte ankyrin that modulate associations of this protein with the anion transporter and spectrin. Two domains have been identified that are located at opposite ends of the polypeptide chain. One domain (Mr = 20,000), which is released by calpain, is primarily involved in regulation of the association of ankyrin with the anion transporter. The Mr = 195,000 fragment remaining after calpain cleavage binds to ankyrin-depleted inside-out vesicles with a 8-fold reaction in affinity, although with a 2-fold increase in number of high affinity sites. Cleavage of ankyrin by calpain induces a reduction in the frictional ratio from 1.55 to 1.33 suggesting either that the calpain-sensitive domain is present as a tail extending from a globular domain, or that upon cleavage ankyrin undergoes a major change in conformation. The other proposed regulatory domain is missing in protein 2.2, a form of ankyrin present in human erythrocytes that has a molecular weight about 29,000 smaller than ankyrin. Protein 2.2 is distinct from the calpain fragment based on peptide maps and reaction with domain-specific antibodies. The activity of the domain deleted from protein 2.2 has been inferred by comparison of ankyrin and protein 2.2, with the assumption that differences between these proteins are due to the missing domain. Protein 2.2 is an activated form of ankyrin that has a 3-fold higher affinity for spectrin and binds to twice the number of high affinity anion transporter sites. These observations suggested that removal of terminal domains of ankyrin may have a physiological role in modulation of ankyrin activity.     

Antigenic diversity of the S-layer proteins from pathogenic strains of Aeromonas hydrophila and Aeromonas veronii biotype sobria.

The antigenic relatedness of paracrystalline surface array proteins with subunit molecular weights of approximately 52,000 from isolates of Aeromonas hydrophila and Aeromonas veronii biotype sobria belonging to a single heat-stable serogroup was examined. Enzyme-linked immunosorbent assay and immunoblotting with two different polyclonal antisera against surface exposed and non-surface-exposed epitopes of the S-layer protein from A. hydrophila TF7 showed that the S-layer proteins of the mesophilic aeromonads were antigenically diverse. NH2-terminal amino acid sequence analysis of four antigenically different proteins showed that while the proteins were structurally related, they differed in primary sequence. Absorption experiments with heterologous live cells showed that cross-reactive epitopes were in non-surface-exposed regions of the S-layer proteins, while absorption with homologous live cells showed that the immunodominant epitopes of the S-layer protein of strain TF7 were strain specific and exposed on the surface of the native, tetragonal array produced by this strain. Proteolytic digestion of the TF7 S-layer protein with trypsin, chymotrypsin, or endoproteinase Glu-C produced an amino-terminal peptide of approximate Mr 38,000 which was refractile to further proteolytic cleavage under nondenaturing conditions. This peptide carried the immunodominant surface-exposed region of the protein, and chemical cleavage with cyanogen bromide further mapped the portion of these surface-exposed epitopes to a peptide of approximate Mr 26,000, part of which maps within the Mr 38,000 protease-resistant NH2-terminal peptide.     

Structural determinants of the half-life and cleavage site preference in the autolytic inactivation of chymotrypsin.

The molecular mechanism of the autolysis of rat alpha-chymotrypsin B was investigated. In addition to the two already known autolytic sites, Tyr146 and Asn147, a new site formed by Phe114 was identified. The former two sites and the latter one are located in the autolysis and the interdomain loops, respectively. By eliminating these sites by site-directed mutagenesis, their involvement in the autolysis and autolytic inactivation processes was studied. Mutants Phe114-->Ile and Tyr146-->His/Asn147-->Ser, that had the same enzymatic activity and molecular stability as the wild-type enzyme, displayed altered routes of autolytic degradation. The Phe114-->Ile mutant also exhibited a significantly slower autolytic inactivation (its half-life was 27-fold longer in the absence and sixfold longer in the presence of Ca2+ ions) that obeyed a first order kinetics instead of the second order displayed by wild-type chymotrypsin inactivation. The comparison of autolysis and autolytic inactivation data showed that: (a) the preferential cleavage of sites followed the order of Tyr146-Asn147 --> Phe114 --> other sites; (b) the cleavage rates at sites Phe114 and Tyr146-Asn147 were independent from each other; and (c) the hydrolysis of the Phe114-Ser115 bond was the rate determining step in autolytic inactivation. Thus, it is the cleavage of the interdomain loop and not of the autolysis or other loops that determines the half-life of chymotrypsin activity.