The 2.0 A crystal structure and substrate specificity of the KDEL-tailed cysteine endopeptidase functioning in programmed cell death of Ricinus communis endosperm

In the senescing endosperm of germinating castor bean (Ricinus communis) a special organelle (the ricinosome) releases a papain-type cysteine endopeptidase (CysEP) during the final stages of cellular disintegration. Protein cleavage sites for the Ricinus CysEP were determined with fluorogenic peptides (Abz-Xaa-Arg-/-Gln-Gln-Tyr(NO2)-Asp). The highest kcat/Km values were obtained with neutral amino acid residues with large aliphatic and non-polar (Leu, Val, Ile, Met) or aromatic (Phe, Tyr, Trp) side-chains. A second series (Abz-Leu-Xaa-/Gln-Pro-Tyr(NO2)-Asp) was evaluated. Based on these results, the covalent binding inhibitor H-D-Val-Leu-Lys-chloromethylketone (CMK) was chosen as substrate analogue for replacement in the catalytic site. Unusually, CysEP cleaved beta-casein N and C-terminal to the amino acid proline. CysEP was crystallized, its structure was solved by molecular replacement at 2.0 A resolution and refined to a R-factor of 18.1% (Rfree=22.6%). The polypeptide chain folds as in papain into two domains divided by the active site cleft, an elongated surface depression harboring the active site. The non-primed specificity subsites of the proteinase are clearly defined by the H-D-Val-Leu-Lys-CMK-inhibitor covalently bound to the active site. The absence of the occluding loop, which blocks the active site of exopeptidases at the C-terminal side of the scissile bond, identifies CysEP as an endopeptidase. The more open pocket of the Ricinus CysEP correlates with the extended variety of substrate amino acid residues accommodated by this enzyme, including even proline at the P1 and P1' positions. This may allow the enzyme to attack a greater variety of proteins during programmed cell death.     

Increase in bioluminescence intensity of firefly luciferase using genetic modification

Firefly luciferase is widely used for enzymatic measurement of ATP, and its gene is used as a reporter for gene expression experiments. From our mutant library, we selected novel mutations in Photinus pyralis luciferase with higher luminescence intensity. These included mutations at Ile423, Asp436, and Leu530. Luciferase is structurally composed of a large N-terminal active site domain (residues 1-436), a flexible linker (residues 436-440) peptide, and a small C-terminal domain (residues 440-550) facing the N domain. Thus, the mutations are located at the junction of the N-terminal domain and the flexible linker, in the flexible linker peptide, and in the tip of the C-terminal domain, respectively. Substitution of Asp436 with a nonbulky amino acid such as Gly remarkably increased the substrate affinity for ATP and d-luciferin. Substitution of Ile423 with a hydrophobic amino acid such as Leu and that of Leu530 with a positively charged amino acid such as Arg increased the substrate affinity and the turnover rate. Combining these mutations, we obtained luciferases that generate more than 10-fold higher luminescence intensity than the wild-type enzyme.     

Deletion of the four C-terminal residues of PepC converts an aminopeptidase into an oligopeptidase.

The aminopeptidase PepC is a cysteine peptidase isolated from lactic acid bacteria. Its structural and enzymatic properties closely resembles those of the bleomycin hydrolases, a group of cytoplasmic enzymes isolated from eukaryotes. Previous biochemical and structural data have shown that the C-terminal end of PepC partially occupies the active site cleft. In this work the substrate specificity of PepC was engineered by deletion of the four C-terminal residues. The mutant PepCDelta432-435 cleaved peptide substrates as an oligopeptidase while the aminopeptidase specificity was totally abolished. The substrate size dependency indicated that PepCDelta432-435 possesses an extended binding site able to accommodate four residues of the substrate on both sides of the cleaved bond. The activity of PepCDelta432-435 towards tryptic fragments of casein revealed a preference for peptides with hydrophobic amino acids at positions P2 and P3 and for Gly, Asn and Gln at position P1. PepCDelta432-435 was shown to be highly sensitive to the thiol peptidase inhibitors leupeptin or E64 which are inefficient towards the wild-type PepC. In conclusion, deletion of the four C-terminal residues in PepC produces a new enzyme with properties resembling those of an endopeptidase from the papain family.     

Peptide substrate specificity of the membrane-bound metalloprotease of Leishmania

The promastigote surface protease (PSP) of Leishmania is a neutral membrane-bound zinc enzyme. The protease has no exopeptidase activity and does not cleave a large selection of substrates with chromogenic and fluorogenic leaving groups at the P1' site. The substrate specificity of the enzyme was studied by using natural and synthetic peptides of known amino acid sequence. The identification of 11 cleavage sites indicates that the enzyme preferentially cleaves peptides at the amino side when hydrophobic residues are in the P1' site and basic amino acid residues in the P2' and P3' sites. In addition, tyrosine residues are commonly found at the P1 site. Hydrolysis is not, however, restricted to these residues. These results have allowed the synthesis of a model peptide, H2N-L-I-A-Y-L-K-K-A-T-COOH, which is cleaved by PSP between the tyrosine and leucine residues with a kcat/Km ratio of 1.8 X 10(6) M-1 s-1. Furthermore, a synthetic nonapeptide overlapping the last four amino acids of the prosequence and the first five residues of mature PSP was found to be cleaved by the protease at the expected site to release the mature enzyme. This result suggests a possible autocatalytic mechanism for the activation of the protease. Finally, the hydroxamate-derivatized dipeptide Cbz-Tyr-Leu-NHOH was shown to inhibit PSP competitively with a KI of 17 microM.     

The specificity of carboxypeptidase Y may be altered by changing the hydrophobicity of the S'1 binding pocket.

The S'1 binding pocket of carboxypeptidase Y is hydrophobic, spacious, and open to solvent, and the enzyme exhibits a preference for hydrophobic P'1 amino acid residues. Leu272 and Ser297, situated at the rim of the pocket, and Leu267, slightly further away, have been substituted by site-directed mutagenesis. The mutant enzymes have been characterized kinetically with respect to their P'1 substrate preferences using the substrate series FA-Ala-Xaa-OH (Xaa = Leu, Glu, Lys, or Arg) and FA-Phe-Xaa-OH (Xaa = Ala, Val, or Leu). The results reveal that hydrophobic P'1 residues bind in the vicinity of residue 272 while positively charged P'1 residues interact with Ser297. Introduction of Asp or Glu at position 267 greatly reduced the activity toward hydrophobic P'1 residues (Leu) and increased the activity two- to three-fold for the hydrolysis of substrates with Lys or Arg in P'1. Negatively charged substituents at position 272 reduced the activity toward hydrophobic P'1 residues even more, but without increasing the activity toward positively charged P'1 residues. The mutant enzyme L267D + L272D was found to have a preference for substrates with C-terminal basic amino acid residues. The opposite situation, where the positively charged Lys or Arg were introduced at one of the positions 267, 272, or 297, did not increase the rather low activity toward substrates with Glu in the P'1 position but greatly reduced the activity toward substrates with C-terminal Lys or Arg due to electrostatic repulsion. The characterized mutant enzymes exhibit various specificities, which may be useful in C-terminal amino acid sequence determinations.     

The primary structure of the mitochondrial energy-linked nicotinamide nucleotide transhydrogenase deduced from the sequence of cDNA clones

The amino acid sequence of the bovine mitochondrial nicotinamide nucleotide transhydrogenase, which catalyzes hydride ion transfer between NAD(H) and NADP(H) coupled to proton translocation across the mitochondrial inner membrane, has been deduced from the corresponding cDNA. Two clones were isolated by screening a bovine lambda gt10 cDNA library, using two synthetic oligonucleotides and a cDNA restriction fragment as probes. The inserts together covered 3,105 base pairs of coding sequence, corresponding to 1.035 amino acid residues. However, the reading frame at the 5' end was still open. N-terminal sequence analysis of the isolated enzyme indicated the presence of 8 additional residues. Thus, the mature transhydrogenase appeared to have 1,043 amino acid residues and a calculated molecular weight of 109,212. The deduced amino acid sequence of the transhydrogenase contained the sequences of four tryptic peptides that had been isolated from the enzyme. Two of these were the peptides that had been used for construction of the oligonucleotide probes. The other two were tryptic peptides isolated after labeling the NAD-binding site of the transhydrogenase once with [3H]p-fluorosulfonylbenzoyl-5'-adenosine (FSBA), and another time with [14C]N,N'-dicyclohexylcarbodiimide. The FSBA-labeled peptide was found to be located immediately upstream of the [14C]N,N'-dicyclohexylcarbodiimide-labeled peptide, about 230 residues from the N terminus. One of the tryptic peptides used for oligonucleotide probe construction was the same as that labeled with [3H]FSBA when the NAD-binding site was protected from FSBA attack. This peptide, which might be at the NADP-binding site of the transhydrogenase, was located very near the C terminus of the enzyme. The central region of the transhydrogenase (residues 420-850) is highly hydrophobic and appears to comprise about 14 membrane-spanning segments. By comparison, the N- and the C-terminal regions of the enzyme, which contain the NAD- and the putative NADP-binding sites, respectively, are relatively hydrophilic and are probably located outside the mitochondrial inner membrane on the matrix side. There is considerable homology between the bovine enzyme and the Escherichia coli transhydrogenase (two subunits, alpha with Mr = 54,000 and beta with Mr = 48,700), whose amino acid sequence has been determined from the genes (Clarke, D.M., Loo, T.W., Gillam, S., and Bragg, P.D. (1986) Eur. J. Biochem. 158, 647-653).     

Large peptides of bovine and guinea pig myelin basic proteins produced by limited peptic hydrolysis.

Bovine and guinea pig myelin basic proteins were cleaved with pepsin at pH 3.0 or pH 6.0 (enzyme/substrate, 1:500, w/w), and the peptides were isolated and identified. At pH 3.0 cleavage of the bovine protein occurred principally at three sites: Phe-Phe (88-89), Phe-Phe (42-43), and Leu-Asp (36-37). Minor cleavages occurred at Leu-Ser (110-111), Phe-Ser (113-114), and Ile-Phe (152-153). A study of the time course of the hydrolysis showed that the reaction was biphasic; nearly all of the protein was cleaved at Phe-Phe (88-89) before significant cleavages at other sites occurred. At pH 6.0 cleavage of the bovine protein occurred almost exclusively at a single site, the Phe-Phe bond at position 88-89, resulting in bisection of the protein. Treatment of the guinea pig protein with pepsin under the same conditions resulted in the production of peptides which were identical with those of the bovine protein in chromatographic and electrophoretic properties and in N-terminal and C-terminal residues but which differed slightly in amino acid composition.     

Mapping of human plasma kallikrein active site by design of peptides based on modifications of a Kazal-type inhibitor reactive site

Human plasma kallikrein (huPK) is a proteinase that participates in several biological processes. Although various inhibitors control its activity, members of the Kazal family have not been identified as huPK inhibitors. In order to map the enzyme active site, we synthesized peptides based on the reactive site (PRILSPV) of a natural Kazal-type inhibitor found in Cayman plasma, which is not an huPK inhibitor. As expected, the leader peptide (Abz-SAPRILSPVQ-EDDnp) was not cleaved by huPK. Modifications to the leader peptide at P'1, P'3 and P'4 positions were made according to the sequence of a phage display-generated recombinant Kazal inhibitor (PYTLKWV) that presented huPK-binding ability. Novel peptides were identified as substrates for huPK and related enzymes. Both porcine pancreatic and human plasma kallikreins cleaved peptides at Arg or Lys bonds, whereas human pancreatic kallikrein cleaved bonds involving Arg or a pair of hydrophobic amino acid residues. Peptide hydrolysis by pancreatic kallikrein was not significantly altered by amino acid replacements. The peptide Abz-SAPRILSWVQ-EDDnp was the best substrate and a competitive inhibitor for huPK, indicating that Trp residue at the P'4 position is important for enzyme action.     

Substrate specificity of carboxypeptidase from Watermelon.

The substrate specificity of carboxypeptidase (F-II) purified from watermelon for various synthetic peptides and esters was examined kinetically. The enzyme showed a broad substrate specificity against various carbobenzoxy- and benzyl-dipeptides. Peptides containing glycine or proline were hydrolyzed slowly by the enzyme. Peptides containing hydrophobic amino acids were hydrolyzed rapidly. The presence of hydrophobic amino acid residues, not only at the C-terminal position but also at the second position and probably the third position from the C-terminal resulted in an increase in the rate of hydrolysis. Inhibition studies with diisopropyl flurophosphate and diastereomers of carbobenzoxy-Phe-Ala demonstrated that the peptidase and esterase activities of the enzyme are both catalyzed by the same site of the enzyme molecule, but the binding sites for peptides and esters seem not to be the same. The enzyme also had amidase activity, which was optimal at pH 7.0.     

Degradation of a signal peptide by protease IV and oligopeptidase A.

The degradation of the prolipoprotein signal peptide in vitro by membranes, cytoplasmic fraction, and two purified major signal peptide peptidases from Escherichia coli was followed by reverse-phase liquid chromatography (RPLC). The cytoplasmic fraction hydrolyzed the signal peptide completely into amino acids. In contrast, many peptide fragments accumulated as final products during the cleavage by a membrane fraction. Most of the peptides were similar to the peptides formed during the cleavage of the signal peptide by the purified membrane-bound signal peptide peptidase, protease IV. Peptide fragments generated during the cleavage of the signal peptide by protease IV and a cytoplasmic enzyme, oligopeptidase A, were identified from their amino acid compositions, their retention times during RPLC, and knowledge of the amino acid sequence of the signal peptide. Both enzymes were endopeptidases, as neither dipeptides nor free amino acids were formed during the cleavage reactions. Protease IV cleaved the signal peptide predominantly in the hydrophobic segment (residues 7 to 14). Protease IV required substrates with hydrophobic amino acids at the primary and the adjacent substrate-binding sites, with a minimum of three amino acids on either side of the scissile bond. Oligopeptidase A cleaved peptides (minimally five residues) that had either alanine or glycine at the P'1 (primary binding site) or at the P1 (preceding P'1) site of the substrate. These results support the hypothesis that protease IV is the major signal peptide peptidase in membranes that initiates the degradation of the signal peptide by making endoproteolytic cuts; oligopeptidase A and other cytoplasmic enzymes further degrade the partially degraded portions of the signal peptide that may be diffused or transported back into the cytoplasm from the membranes.     

Peptidyl dipeptidases (Ance and Acer) of Drosophila melanogaster: major differences in the substrate specificity of two homologs of human angiotensin I-converting enzyme

Drosophila melanogaster angiotensin converting enzyme (Ance) and angiotensin converting enzyme related (Acer) are single domain homologs of mammalian peptidyl dipeptidase A (angiotensin I-converting enzyme) whose physiological substrates have not as yet been identified. We have investigated the in vitro substrate specificities of the two peptidases towards a variety of insect and mammalian peptides. Ance was generally much better than Acer at hydrolyzing peptides of 5-13 amino acids in length. Only two of the peptides, [Leu(5)]enkephalinamide and leucokinin-I were cleaved faster by Acer. Increasing NaCl concentration had opposite affects on the cleavage of [Leu(5)]enkephalin and [Leu(5)]enkephalinamide by Acer, decreasing the activity towards [Leu(5)]enkephalin but increasing the activity towards [Leu(5)]enkephalinamide. Of the insect peptides tested, the tachykinin-related peptide, Lom TK-1, proved to be the best substrate for Ance with a k(cat)/K(m) ratio of 0.122s(-1) microM(-1). However, in comparison, the D. melanogaster tachykinins, DTK-1, DTK-2, DTK-3 and DTK-4 were poor Ance substrates. DTK-5 was the best substrate of this family, but the apparent high K(m) for hydrolysis by Ance suggested that this peptide would not be a natural Ance substrate. This low affinity for DTK-5 is the likely reason why the peptide was not rapidly degraded in D. melanogaster hemolymph, where Ance was shown to be a major peptide-degrading activity.     

The His-Pro-Phe motif of angiotensinogen is a crucial determinant of the substrate specificity of renin

The amino acid sequence His-Pro-Phe as N-terminal residues 6-8 of the natural renin substrate, angiotensinogen, is conserved among species. We investigated whether this His-Pro-Phe motif functions as the determinant of the substrate specificity of renin. Mutant angiotensinogens in which the Ile-His-Pro-Phe-His-Leu sequence at positions 5-10 of wild-type angiotensinogen was replaced by either His-Pro-Phe-His-Leu-Leu or Ala-Ile-His-Pro-Phe-His were cleaved by renin at the C-terminal side of residues 9 and 11, respectively, while wild-type angiotensinogen was cleaved at residue 10. A triple Ala substitution for the His-Pro-Phe motif of angiotensinogen prevented its cleavage by renin. In contrast, triple Ala substitution for residues 9-11, including the natural site of cleavage by renin, allowed cleavage between the two Ala residues at positions 10 and 11. Furthermore, the 33-residue C-terminal peptide of human megsin, which carries a naturally occurring His-Pro-Phe sequence, was cleaved by renin at the C-terminal side of the His-Pro-Phe-Leu-Phe sequence. These results indicate that the His-Pro-Phe motif of angiotensinogen is a crucial determinant of the substrate specificity of renin. By binding to a corresponding pocket on renin, the His-Pro-Phe motif may act as a molecular anchor to recruit the scissile peptide bond to a favorable site for catalysis.     

Complete Amino Acid Sequence of Neutral Protease from Bacillus subtilis var. amylosacchariticus

The neutral protease of Bacillus subtilis var. amylosacchariticus was cleaved chemically or digested with proteolytic enzymes, and the resultant peptides were separated and purified by high performance liquid chromatography. The sequence analyses of these peptides by the manual Edman procedure established the complete amino acid sequence of the enzyme. The neutral protease consisted of 300 amino acid residues with Ala and Leu as its amino- and carboxyl-termini, respectively, and the molecular weight was calculated to be 32,633. The sequence was found to be identical to that of B. subtilis 1A72 neutral protease, which was deduced from nucleotide sequencing. Comparison of the sequence with those of other Bacillus proteases revealed that the putative active site amino acid residues, Zn-binding ligands, and two Ca-binding sites were well conserved among them, as compared with those of thermolysin.     

Substrate specificities of cathepsin A,L and A,S from pig kidney

The substrate specificities of two different molecular sizes of cathepsin A, A,L (large form) and A,S (small form), for synthetic substrates were examined kinetically. Both enzymes showed a similar broad substrate specificity against various acyl dipeptides, amino acid esters, and amino acid amides. Z-Phe-Ala and Ac-Phe-OEt were good substrates. Peptides containing hydrophobic amino acids were hydrolyzed rapidly. The presence of hydrophobic amino acid residues, not only at the C-terminal position but also at the second position and probably the third position from the C-terminal, resulted in an increase in the rate of hydrolysis. Peptides containing glycine and proline were hydrolyzed slowly. Inhibition studies with Z-D-Phe-D-Ala and Z-Phe suggested that the peptidase and esterase activities of the enzymes are both catalyzed by the same site of the enzyme molecule, but it remains to be elucidated whether or not the binding sites for peptides and esters are the same.     

The degradation of proparathormone and parathormone by parathyroid and liver cathepsin B.

Purified cathepsin B from porcine parathyroid glands was allowed to act upon radioactive bovine parathormone and proparathormone at various ratios of enzyme to substrate and for different times. The reaction products were isolated by ion exchange chromatography and analyzed by gel electrophoresis, amino acid composition, sequence analysis, and bioassay. The enzyme cleaved parathormone between residues 36 and 37 yielding a major carboxyl and amino fragment and appeared to cleave proparathormone at the same locus. The amino fragments were degraded further by removal of small peptides (possibly, di- or tripeptides) from their COOH termini. In contrast there was little if any degradation of the carboxyl fragment (residues 37 to 84). Despite the ease with which the enzyme cleaved the arginyl bond in the synthetic substrate benzyloxycarbonyl-Val-Lys-Lys-Arg-(4-methoxy)-2-naphthylamide, it did not remove the near homologous NH2-terminal hexapeptide extension of proparathormone (Lys-Ser-Val-Lys-Lys-Arg-R)--a reaction that would lead to the formation of parathormone from proparathormone. Purified liver cathepsin B cleaved the hormonal substrates in a fashion identical with that of the parathyroid enzyme.     

Specific transformations at the N-terminal region of phospholipase A2.

Treatment of porcine pancreatic prophospholipase A2 with methyl acetimidate converted all lysine residues into epsilon-acetimidolysine residues. Enzymatically active epsilon-amidinated phospholipase A2 (AMPA) was obtained from the epsilon-amidinated zymogen by limited tryptic proteolysis cleaving the Arg7-Ala8 bond. AMPA was used to prepare des-Ala8-, des-(Ala8,Leu9)- and des-(ALa8),Leu9,Trp10)-AMP by successive Edman degradations, and des-(A la 8-Arg13)-AMPA by selective splitting of the Arg13-Ser14 bond by trypsin. Structural analogues of AMPA with different N-terminal amino acid residues, viz., D-Ala, beta-Ala, and Gly, have been prepared by reacting des-Ala8-AMPA with the corresponding N-t-Boc-N-hydroxysuccinimide esters of these amino acids. Similarly, the only Trp10 residue has been substituted for Phe by coupling of des-(Ala8-,Leu9,Trp10)-AMPA with N-t-Boc-L-Ala-L-Leu-L-Phe-N-hydroxysuccinimide ester. The feasibility of these substitutions has been proven unambiguously by the retroconversion of des-Ala8-AMPA and of [Ala7]AMPA into AMPA having identical enzymatic activity as the starting AMPA. The single Trp10 residue in native phospholipase A2 and its zymogen was specifically sulfenylated using 0-nitrophenyl-sulfenyl chloride. The homogenous proteins were kinetically analyzed using short-chain lecithins in the monomeric and micellar region. All modified AMPA analogues, except those in which two or more of the N-terminal amino acid residues are removed, show enzymatic activities toward monermic substrate comparable to that of AMPA, indicating that the active site region is still intact. Only [Gly8]-, [beta-Ala8]-, and [Ala8,Leu9,Phe10]AMPA exhibit a dramatic increase in enzymatic activity similar to that of AMPA upon passing the critical micellar concentration (cmc) of the substrate. From these results it can be concluded that the N-terminal region of the enzyme requires a very precise architecture in order to interact with lipid-water interfaces and consequently to display its full enzymatic activity.     

Biochemistry of terminal deoxynucleotidyltransferase. Affinity labeling and identification of the deoxynucleoside triphosphate binding domain of terminal deoxynucleotidyltransferase

Using the technique of UV-mediated cross-linking of nucleotides to their acceptor sites (Modak, M. J., and Gillerman-Cox, E. (1982) J. Biol. Chem. 257, 15105-15109), we have labeled calf terminal deoxynucleotidyltransferase (TdT) with [32P]dTTP. The specificity of dTTP cross-linking at the substrate binding site in TdT is demonstrated by the competitive inhibition of the cross-linking reaction by other deoxynucleoside triphosphates, and ATP and its analogues, requiring concentrations consistent with their kinetic constants. Tryptic peptide mapping of the [32P]dTTP-labeled enzyme showed the presence of a single radioactive peptide fraction that contained the site of dTTP cross-linking. The amino acid composition and sequence analysis of the radioactive peptide fraction revealed it to contain two tryptic peptides, spanning residues 221-231 and 234-249. Since these two peptides were covalently linked to dTTP, the region encompassed by them constitutes a substrate binding domain in TdT. Further proteolytic digestion of the tryptic peptide-dTTP complex, using V8 protease, yielded a smaller peptide, and its analysis narrowed the substrate binding domain to 14 amino acids corresponding to residues 224-237 in the primary amino acid sequence of TdT. Furthermore, 2 cysteine residues, Cys-227 and Cys-234, within this domain were found to be involved in the cross-linking of dTTP, suggesting their participation in the process of substrate binding in TdT.     

Enzyme-substrate interactions in the hydrolysis of peptide substrates by thermitase, subtilisin BPN', and proteinase K

Peptide substrates of the general structure acetyl-Alan (n = 2-5), acetyl-Pro-Ala-Pro-Phe-Alan-NH2 (n = 0-3), and acetyl-Pro-Ala-Pro-Phe-AA-NH2 (AA = various amino acids) were synthesized and used to investigate the enzyme-substrate interactions of the microbial serine proteases thermitase, subtilisin BPN', and proteinase K on the C-terminal side of the scissile bond. The elongation of the substrate peptide chain up to the second amino acid on the C-terminal side (P'2) enhances the hydrolysis rate of thermitase and subtilisin BPN', whereas for proteinase K an additional interaction with the third amino acid (P'3) is possible. The enzyme subsite S'1 specificity of the proteases investigated is very similar. With respect to kcat/Km values small amino acid residues such as Ala and Gly are favored in this position. Bulky residues such as Phe and Leu were hydrolyzed to a lower extent. Proline in P'1 abolishes the hydrolysis of the substrates. Enzyme-substrate interactions on the C-terminal side of the scissile bond appear to affect kcat more than Km for all three enzymes.     

Cleavage specificity of a myofibril-bound serine proteinase from carp (Cyprinus carpio) muscle

Previously, we reported the purification and characterization of a myofibril-bound serine proteinase (MBP) from carp muscle (Osatomi K, Sasai H, Cao M-J, Hara K, Ishihara T. Comp Biochem Physiol 1997;116B:159–66). In the present study, the N-terminal amino acid sequence of the enzyme was determined, which showed high identity with those of other trypsin-like serine proteases. The cleavage specificity of MBP for dibasic and monobasic residues was investigated using various fluorogenic substrates and peptides. Analyses of the cleaved peptide products showed that the enzyme hydrolyzed peptides both at monobasic and dibasic amino acid residues. Monobasic amino acid residues were hydrolyzed at the carboxyl side; dibasic residues were cleaved either at the carboxyl side of the pair or between the two basic residues and the enzyme showed a cleavage preference for the Arg-Arg pair. Unexpectedly, MBP hydrolyzed lysyl-bradykinin and methionyl–lysyl–bradykinin at the carboxyl side of Gly fairly specifically and efficiently displaying a unique cleavage. Because MBP also degraded protein substrates such as casein and myofibrillar proteins, the substrate specificity of MBP appeared not to be strictly specific.