Purification and partial characterization of a lysine-specific protease of Porphyromonas gingivalis

Abstract A lysine-specific protease hydrolysing peptide bonds at the carboxyl side of lysine residues in Porphyromonas gingivalis was purified from culture supernatant by a combination of ion-exchange chromatography, gel filtration, and affinity chromatography. The molecular mass was 48 kDa and the p I value was 7.3. The enzyme hydrolysed the peptide bonds at the carboxyl side of lysine residues in synthetic substrates and natural proteins.     

A Novel Type of Substrate Specificity of Rice BAPAase (Benzoyl-L-arginine p-nitroanilide Hydrolase) with Mixed Endopeptidase and Carboxypeptidase

The substrate specificity of rice embryo benzoyl-L-argininep-nitroanilide hydrolase (BAPAase) was examined. No endopeptidaseactivity toward protein substrates was detectable. Small peptides(less than 8 residues) and amide, ester substrates, however,were hydrolyzed very well at the carboxyl side of the lysineor arginine residue. No other peptide bond was hydrolyzed. TheN-terminal arginine of the substrates was released very slowly.Peptides with lysine or arginine penultimate to the C-terminalposition were hydrolyzed well and released an amino acid. Theoxidized insulin B chain (30 residues) was cleaved very slowlyat the C-terminal Lys-Ala bond, whereas an Arg-Gly bond at aninner position was not cleaved. The hydrolytic rate increasedafter the chain length was shortened by chymotryptic digestion.These results show that the rice embryo BAPAase is a novel enzymewhich has mixed endopeptidase-carboxypeptidase activity towardthe Arg-X and Lys-X bonds of small peptides, a characteristicintermediate between trypsin and serine carboxypeptidase. Thisenzyme may act in the breakdown of small peptides that havephysiological functions. (Received May 26, 1984; Accepted August 29, 1984)     

The twin arginine consensus motif of Tat signal peptides is involved in Sec-independent protein targeting in Escherichia coli

In Escherichia coli a subset of periplasmic proteins is exported through the Tat pathway to which substrates are directed by an NH(2)-terminal signal peptide containing a consensus SRRXFLK "twin arginine" motif. The importance of the individual amino acids of the consensus motif for in vivo Tat transport has been assessed by site-directed mutagenesis of the signal peptide of the Tat substrate pre-SufI. Although the invariant arginine residues are crucial for efficient export, we find that slow transport of SufI is still possible if a single arginine is conservatively substituted by a lysine residue. Thus, in at least one signal peptide context there is no absolute dependence of Tat transport on the arginine pair. The consensus phenylalanine residue was found to be a critical determinant for efficient export but could be functionally substituted by leucine, another amino acid with a highly hydrophobic side chain. Unexpectedly, the consensus lysine residue was found to retard Tat transport. These observations and others suggest that the sequence conservation of the Tat consensus motif is a reflection of the functional importance of the consensus residues. Tat signal peptides characteristically have positively charged carboxyl-terminal regions. However, changing the sign of this charge does not affect export of SufI.     

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.     

Specificity of Proteinase K from Tritirachium album Limber for Synthetic Peptides

The specificity of proteinase K from Tritirachium album Limber was determined using various synthetic peptide substrates. The esterase activity against N-acylated amino acid esters indicated that the enzyme is primarily specific against aromatic or hydrophobic amino acid residues at the carboxyl side of the splitting point. Secondary interaction for hydrolysis was also studied using peptide esters or others, which showed that the enzyme activity is markedly promoted by elongating the peptide chain to the N-terminal from the splitting point. Thus, peptide chloromethyl ketone derivatives such as Cbz-Ala-Gly-PheCH₂Cl inactivated the enzyme activity markedly.     

Isolation and properties of a capillary injury-related protease from lung lymph

Lung microvascular injury induced in sheep by intravenous infusion of Escherichia coli endotoxin, oleic acid, or air emboli caused the appearance in lung lymph of high levels of a protease with trypsin-like activity. The enzyme was isolated as an apparently homogeneous protein from pooled samples of active lung lymph, after an almost 9000-fold purification by affinity chromatography on columns of Reactive Blue 2-agarose, aprotinin-agarose, and p-aminobenzamidine-agarose, and chromatography on a column of Sephadex G-100. A molecular weight of about 70,000 to 75,000 was determined from mobility in polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The pH optimum was between 7.3 and 7.6. The isolated enzyme was quite labile, rapidly losing activity at both 37 and 25 degrees C. Addition of albumin to enzyme solutions protected against inactivation. Inhibition by diisopropylfluorophosphate and phenylmethanesulfonyl fluoride indicated that the enzyme belongs to the class of serine proteases. The enzyme cleaved peptide bonds on the carboxyl side of arginine residues and showed a relatively high affinity toward peptides containing several basic amino acid residues. Bonds involving the carboxyl group of lysine were cleaved at a much slower rate. The enzyme showed no plasminogen activator activity and its substrate specificity was quite different from that of several proteases of the clotting cascade. Its appearance in lymph was not influenced by lymph clotting and the isolated enzyme was not capable of correcting the clotting defect of plasmas deficient in factors XII, XI, IX, VII, and X.     

Characterizations of acylagmatine amidohydrolase and carboxypeptidase from Fusarium anguioides.

Previously an enzyme, named acylagmatine amidohydrolase, hydrolyzing bleomycin B2 to bleomycinic acid and agmatine was found in the mycelia of Fusarium anguioides Sherbakoff. In this work the enzyme was purified further, but not completely. The crude enzyme preparation hydrolyzed various acylagmatines and also peptidyl arginine, but the latter activity could be separated from acylagmatine amidohydrolase activity by gel filtration on Sephadex G-100. The enzyme was inhibited by PCMB and its molecular weight was estimated as 65,000 by gel filtration. It showed substrate specificity with respect to the alkyl-chain length of the amine moiety. The other hydrolase fraction with activity toward Bz-Gly-Arg was found to be of a sort of carboxypeptidase, which preferentially hydrolyzed peptides with arginine or lysine at the carboxyl terminus, including bradykinin, but liberated neutral amino acids as well from the terminus when the penultimate residue of the substrates was phenylalanine. With Bz-Gly-Arg as substrate Fusarium carboxypeptidase was sensitive to chelating agents but not to diisopropyfluorophosphate, and its molecular weight was estimated to be 145,000.     

Substrate preference of transglutaminase 2 revealed by logistic regression analysis and intrinsic disorder examination

Tissue transglutaminase (TG2) catalyzes the Ca²⁺-dependent posttranslational modification of proteins via formation of isopeptide bonds between their glutamine and lysine residues. Although substrate specificity of TG2 has been studied repeatedly at the sequence level, no clear consensus sequences have been determined so far. With the use of the extensive structural information on TG2 substrate proteins listed in TRANSDAB Wiki database†, a slight preference of TG2 for glutamine and lysine residues situated in turns could be observed. When the spatial environment of the favored glutamine and lysine residues was analyzed with logistic regression, the presence of specific amino acid patterns was identified. By using the occurrence of the predictor amino acids as selection criteria, several polypeptides were predicted and later identified as novel in vitro substrates for TG2. By studying the sequence of TG2 substrate proteins lacking available crystal structure, the strong favorable influence on substrate selection of the presence of substrate glutamine and lysine residues in intrinsically disordered regions could also be revealed. The collected structural data have provided novel understanding of how this versatile enzyme selects its substrates in various cell compartments and tissues.     

Membrane bound pituitary metalloendopeptidase: Apparent identity to enkephalinase

A membrane bound zinc-metalloendopeptidase from bovine pituitaries with a specificity toward bonds on the amino side of hydrophobic amino acids, cleaves Met- and Leu-enkephalin at the Gly-Phe bond, releasing Phe-Met and Phe-Leu respectively. The enzyme also hydrolyzes bonds on the amino side of hydrophobic amino acids in oxytocin, bradykinin, neurotensin and several synthetic substrates. A free carboxyl group on a dipeptide C-terminal to the hydrolyzed bond is not a requirement for activity. The enzyme is also present in brain membrane fractions. The regional distribution of this enzyme in brain, its specificity toward natural and synthetic substrates, and its sensitivity to inhibitors, suggest that the enzyme is identical to an activity referred to as “enkephalinase”, which has been described as dipeptidyl carboxypeptidase. The data show that the enzyme is an endopeptidase with a specificity similar to that of a group of microbial proteases, one of which is thermolysin.     

Comparative specificity of microbial acid proteinases for synthetic peptides. Primary specificity with Z-tetrapeptides

The substrates Z-X

Leu-(Ala)₂ and

Z-Phe X-(Ala)₂ (Z = benzyloxycarbonyl, X = various amino acid residues) were synthesized in order to investigate the primary specificity of acid proteinases from molds and yeasts. Since these peptides are mainly susceptible to cleavage by the enzymes at the peptide bonds shown by the arrows, it was possible to determine the specificity with respect to the amino acid residues on both sides of the splitting point. Pepsin was used for comparison. The results indicated that the microbial acid proteinases exhibit specificity for aromatic or hydrophobic amino acid residues on both sides of splitting point in peptide substrates, as does pepsin. However, the microbial enzymes showed somewhat broader specificity than pepsin. The former enzymes, which possess trypsinogen-activating ability, show specificity for a lysine residue, while pepsin or Mucor rennin-like enzyme does not. Although pepsin is very specific for a tyrosine residue on the imino side of the splitting point, the microbial enzymes do not show such stringency.     

Substrate specificity of collagenolytic proteases from the hepatopancreas of the of the Kamchatka crab]

The substrate specificity of two isozymes of collagenolytic protease of the crab (Paralithodes camtschatica) was studied. It was found that both proteases can effectively hydrolyze type I and III collagens, as well as gelatin, the set of products yielded by enzymatic hydrolysis being different for isozymes A and C. Hydrolysis of some well-known peptides revealed that isozyme A predominantly cleaves the peptide bonds containing arginine and lysine residues, whereas isozyme C predominantly hydrolyzes bonds containing hydrophobic amino acids. The catalytic constants for the hydrolysis of several low molecular weight substrates in the presence of P. camtschatica proteases were determined, which allowed to attribute isozyme A to trypsin-like, and isozyme C to chymotrypsin-like proteinases. The peptide substrates of collagenase, Pz-Pro-Leu-Gly-Pro-D-Arg and Z-Gly-Pro-Ala-Gly-Pro-Ala are not hydrolyzed isozymes of crab collagenolytic protease.     

Assessment of amino-acid substitutions at tryptophan 16 in alpha-galactosidase.

The tryptophan residue at position 16 of coffee bean alpha-galactosidase has previously been shown to be essential for enzyme activity. The potential role of this residue in the catalytic mechanism has been further studied by using site-directed mutagenesis to substitute every other amino acid for tryptophan at that site. Mutant enzymes were expressed in Pichia pastoris, a methylotrophic yeast strain, and their kinetic parameters were calculated. Only amino acids containing aromatic rings (phenylalanine and tyrosine) were able to support a significant amount of enzyme activity, but the kinetics and pH profiles of these mutants differed from wild-type. Substitution of arginine, lysine, methionine, or cysteine at position 16 allowed a small amount of enzyme activity with the optimal pH shifted towards more acidic. All other residues abolished enzyme activity. Our data support the hypothesis that tryptophan 16 is affecting the pKa of a carboxyl group at the active site that participates in catalysis. We also describe an assay for continuously measuring enzyme kinetics using fluorogenic 4-methylumbelliferyl substrates. This is useful in screening enzymes from colonies and determining the enzyme kinetics when the enzyme concentration is not known.     

Substrate specificity at the P1' site of Escherichia coli OmpT under denaturing conditions

Though OmpT has been reported to mainly cleave the peptide bond between consecutive basic amino acids, we identified more precise substrate specificity by using a series of modified substrates, termed PRX fusion proteins, consisting of 184 residues. The cleavage site of the substrate PRR was Arg140-Arg141 and the modified substrates PRX substituted all 19 natural amino acids at the P1' site instead of Arg141. OmpT under denaturing conditions (in the presence of 4 M urea) cleaved not only between two consecutive basic amino acids but also at the carboxyl side of Arg140 except for the Arg140-Asp141, -Glu141, and -Pro141 pairs. In addition to Arg140 at the P1 site, similar results were obtained when Lys140 was substituted into the P1 site. In the absence of urea, an aspartic acid residue at the P1' site was unfavorable for OmpT cleavage of synthetic decapeptides, the enzyme showed a preference for a dibasic site.     

The enzyme stability of dehydro-enkephalins

Dehydro-enkephalins [ΔAla²]-, [ΔAla³]-, [ΔPhe⁴]-, and [ΔLeu⁵]enkephalins, were examined for their stability to enzymatic hydrolysis by carboxypeptidase Y [EC 3.4.16.1]. The successively liberated amino acids were determined quantitatively by amino acid analyses. The saturated leucine-enkephalin was rapidly hydrolyzed from the COOH-terminus. However, peptide linkages with ,β-dehydroamino acid residues placed in the enkephalin molecule were strongly resistant to the enzyme at the carboxyl side and completely resistant at the amino side of the dehydro residue.     

Biosynthesis of the cyanobacterial reserve polymer multi-L-arginyl-poly-L-aspartic acid (cyanophycin): mechanism of the cyanophycin synthetase reaction studied with synthetic primers.

Biosynthesis of the cyanobacterial nitrogen reserve cyanophycin (multi-L-arginyl-poly-L-aspartic acid) is catalysed by cyanophycin synthetase, an enzyme that consists of a single kind of polypeptide. Efficient synthesis of the polymer requires ATP, the constituent amino acids aspartic acid and arginine, and a primer like cyanophycin. Using synthetic peptide primers, the course of the biosynthetic reaction was studied. The following results were obtained: (a) sequence analysis suggests that cyanophycin synthetase has two ATP-binding sites and hence probably two active sites; (b) the enzyme catalyses the formation of cyanophycin-like polymers of 25-30 kDa apparent molecular mass in vitro; (c) primers are elongated at their C-terminus; (d) the constituent amino acids are incorporated stepwise, in the order aspartic acid followed by arginine, into the growing polymer. A mechanism for the cyanophycin synthetase reaction is proposed; (e) the specificity of the enzyme for its amino-acid substrates was also studied. Glutamic acid cannot replace aspartic acid as the acidic amino acid, whereas lysine can replace arginine but is incorporated into cyanophycin at a much lower rate.     

Streptomyces rimosus extracellular proteases 3. Isolation and characterization of leucine aminopeptidase

Summary A leucine aminopeptidase was purified to homogeneity fromStreptomyces rimosus culture filtrates, which are waste broth of oxytetracycline bioproduction process. Purification procedure includes ultrafiltration and chromatography on CM-Sephadex, AH-Sepharose and FPLC Mono S column. The enzyme is a monomer with molecular weight of 27,500 Daltons and pI of 7.3, stable in broad pH range and up to 70°C. It is a metallo enzyme dependent on Ca²⁺ ions for its full activity. By its specificity it is a true aminopeptidase active on amino acid amide, arylamide, peptide and ester bonds. The hydrolysing activity shows preference for leucine at the N-terminal position of substrates, also acts on aromatic acids and methionine, but does not release glycine, proline, acidic amino acids orD-amino acid residues.     

Substrate recognition of isopeptidase: specific cleavage of the epsilon-(alpha-glycyl)lysine linkage in ubiquitin-protein conjugates

The structural chromatin protein A24 (uH2A) is a conjugate of histone H2A and a non-histone protein, ubiquitin. Eukaryotic cells contain an enzyme, generically termed isopeptidase, which can cleave A24 stoichiometrically into H2A and ubiquitin in vitro. Isopeptidase, free of proteinase activity, has been partially purified from calf thymus by ion-exchange chromatography, gel filtration and affinity chromatography, and analyzed for its substate specificity. There are three major types of isopeptide bonds besides the epsilon-(alpha-glycyl)lysine bond between H2A and ubiquitin; namely, the disulfide bridge, the aldol and aldimide bonds and the epsilon-(gamma-glutamyl)lysine crosslink. Under conditions where A24 was completely cleaved into H2A and ubiquitin, none of these naturally occurring isopeptide bonds was cleaved by isopeptidase. Furthermore, the bonds formed in vitro by transglutaminase reaction between casein and putrescine, through the gamma-NH2 of glutamine residue and the NH2 of putrescine, were not cleaved by the enzyme. The enzyme also failed to cleave the glycyl-lysyl and other orthodox peptide linkages within proteins. Among various proteins examined, the substrates for isopeptidase reaction were confined to conjugates between ubiquitin and other proteins, formed through epsilon-(alpha-glycyl)lysine bonds. Since ubiquitin released by isopeptidase is re-usable for an ATP-dependent conjugation with other proteins, its carboxyl terminal -Gly-Gly-COOH most likely is preserved intact, and is not blocked. These results suggest that isopeptidase specifically recognizes and cleaves the epsilon-(alpha-glycyl)lysine bond. A possible biological significance of this enzyme is discussed.     

Studies on Mold Proteases

The substrate specificity of the crystalline acid protease obtained from Rhizopus chinensis was determined using B-chain of oxidized beef insulin and numerous synthetic peptides, comparing with that of several acid proteases from various sources. The peptide bonds susceptible to the action of Rhiz. acid protease were found to be mainly those involving the amino group of bulky amino acids. The enzyme split the B-chain of oxidized insulin at twelve sites of the peptide linkages and a certain similarity in the specificity was observed among the three acid proteases, Rhiz. protease, rennin and pepsin, all of which were known to show potent milk clotting activities.     

Key sites residues involved in interacting with chemicals of pheromone‐binding proteins from Lymantria dispar

Pheromone‐binding proteins (PBPs) are distributed widely on the antennae of insects, and they are believed to be involved in the process of chemical signal transduction, but their interaction with chemicals is largely unknown. Here, we present our findings on the key amino acid residues of PBPs in the gypsy moth, Lymantria dispar. Potential key residues were screened with the Calculate Mutation Energy program and molecular docking methods. Mutated proteins were obtained by mutating residues to alanine via site‐directed mutagenesis. Circular dichroism (CD) spectroscopy showed that the mutated proteins formed α‐helix, and the stability of protein structure was influenced due to mutations. Fluorescence binding assays were further conducted with the mutated proteins, sex pheromones and analogues. Results showed that to PBP 1, tyrosine at position 41 and phenylalanine at position 76 could be the key amino acid residues influencing the stability of structure; in addition, phenylalanine at 36 and lysine at position 94 could be key amino acid residues interacting with chemicals. To PBP 2, glycine at position 49, phenylalanine at position 76 and lysine at position 121 could be the key amino acid residues in the structural stability. These results shed light on the relationship between the specific amino acids and functions of PBPs in transmitting the chemical signals.     

Amino acid requirements for growth of the rabbit blastocyst in vitro

Ten amino acids, namely, arginine, histidine, lysine, tryptophane, methionine, phenylalanine, leucine, valine, threonine and serine were indispensable for growth of rabbit blastocysts in vitro; others were nonessential. Of all the essential amino acids, arginine and lysine were required in relatively high concentrations, 10^?2 M and 10^?3 M, respectively, for optimum growth. Complete omission of the non-essential amino acids from the medium markedly reduced blastocyst growth. Interaction between serine and glycine demonstrated a partial sparing action on serine by glycine, similar to that observed between methionine and cysteine. The amino acid composition of a culture medium capable of providing continuous and consistent growth of rabbit blastocysts in vitro is described.