The specificity of the S1 subsite of papain

The specificity of the S(1)' subsite of the proteolytic enzyme papain was investigated by studying the effect of l-alpha-amino acid amides on the enzyme-catalysed hydrolysis of N-benzyloxycarbonylglycine p-nitrophenyl ester and by determining the kinetic parameters for the enzyme-catalysed hydrolysis of some N-benzyloxycarbonylglycyl-l-amino acid amides. These studies showed that the S(1)' subsite has a predilection for hydrophobic residues, in particular l-leucine and l-tryptophan. The specificity for these residues is manifest in both the binding and acylation steps. N-Benzyloxycarbonylglycine amide is not hydrolysed under comparable conditions, indicating that the amide group adjacent to and on the C-terminal side of the peptide bond about to be cleaved makes an important contribution to the rate of the papain-catalysed hydrolysis of peptides.     

Role of the S1' subsite glutamine 215 in activity and specificity of stromelysin-3 by site-directed mutagenesis.

The influence of Gln215 in stromelysin-3 (MMP-11), a residue located in the S1' subsite, was determined by producing three single mutants of this position. As compared to wild-type stromelysin-3, the kinetic parameters K(M) and k(cat) for the degradation of the fluorogenic substrate Dns-Pro-Leu-Ala-Leu-Trp-Ala-Arg-NH(2) (Dns-Leu) by these mutants indicated that the Gln/Leu substitution led to a 4-fold decrease in catalytic efficiency, whereas the mutations Gln/Tyr and Gln/Arg increased this parameter by a factor 10. The cleavage of alpha1-protease inhibitor (alpha1-PI), a natural substrate of stromelysin-3, by these mutants was also determined. Their relative activities for the degradation of alpha1-PI correspond to those observed with the synthetic substrate Dns-Leu. The catalytic efficiency of wild-type stromelysin-3 and its mutants to cleave the P1' analogue of Dns-Leu, containing the unusual amino acid Cys(OMeBn) (Dns-Cys(OMeBn)), was also determined. The values of the specificity factor, calculated as the ratio (k(cat)/K(M))Dns-Cys(OMeBn))/(k(cat)/K(M))Dns-Leu, were observed to vary from 26 for the wild-type stromelysin-3 to 120 for the Gln/Leu mutant and 25 for the Gln/Arg mutant. The Gln/Tyr mutant did not cleave the substrate when its P1' position is substituted by the unusual amino acid Cys(OMeBn). Altogether these observations established that both the catalytic activity and the specificity of stromelysin-3 are dependent on the nature of the residue in position 215. Finally, the cleavage efficiency of the Dns substrates by three representative matrixins, namely, MMP-14 (215 = Leu), MMP-1 (215 = Arg), and MMP-7 (215 = Tyr), was determined. Interestingly, the trends observed for these enzymes were similar to those established for the three mutants of stromelysin-3, pointing out the influence of position 215 toward the selectivity in this family of enzymes.     

Peptide synthesis by proteases in organic solvents: medium effect on substrate specificity.

The substrate specificities of alpha-chymotrypsin and subtilisins for peptide synthesis in hydrophilic organic solvents were investigated. Chymotrypsin exhibited high specificity to aromatic amino acids as acyl donors, while subtilisin Carlsberg and subtilisin BPN' were specific to aromatic and neutral aliphatic amino acids, in accordance with the S1 specificities of the enzymes for peptide hydrolysis in aqueous solutions. On the contrary, chymotrypsin exhibited higher specificities to hydrophilic amino acid amides as acyl acceptors (nucleophiles) for peptide synthesis with N-acetyl-L-tyrosine ethyl ester, in contrast to the S1' specificity for peptide hydrolysis and peptide synthesis in aqueous solutions. Furthermore, nucleophile specificity changed with the change in water-organic solvent composition; the increase in water content led to increase in relative reactivity of leucinamide to that of alaninamide. It was also found that protection of the carboxyl group of alanine by amidation is much preferable to protection by esterification in terms of reactivity as nucleophiles.     

Structural basis of substrate specificity in the serine proteases.

Structure-based mutational analysis of serine protease specificity has produced a large database of information useful in addressing biological function and in establishing a basis for targeted design efforts. Critical issues examined include the function of water molecules in providing strength and specificity of binding, the extent to which binding subsites are interdependent, and the roles of polypeptide chain flexibility and distal structural elements in contributing to specificity profiles. The studies also provide a foundation for exploring why specificity modification can be either straightforward or complex, depending on the particular system.     

The roles of substrate thermal stability and P2 and P1' subsite identity on matrix metalloproteinase triple-helical peptidase activity and collagen specificity

The hydrolysis of collagen (collagenolysis) is one of the committed steps in extracellular matrix turnover. Within the matrix metalloproteinase (MMP) family distinct preferences for collagen types are seen. The substrate determinants that may guide these specificities are unknown. In this study, we have utilized 12 triple-helical substrates in combination with 10 MMPs to better define the contributions of substrate sequence and thermal stability toward triple helicase activity and collagen specificity. In general, MMP-13 was found to be distinct from MMP-8 and MT1-MMP(Delta279-523), in that enhanced substrate thermal stability has only a modest effect on activity, regardless of sequence. This result correlates to the unique collagen specificity of MMP-13 compared with MMP-8 and MT1-MMP, in that MMP-13 hydrolyzes type II collagen efficiently, whereas MMP-8 and MT1-MMP are similar in their preference for type I collagen. In turn, MMP-1 was the least efficient of the collagenolytic MMPs at processing increasingly thermal stable triple helices and thus favors type III collagen, which has a relatively flexible cleavage site. Gelatinases (MMP-2 and MMP-9(Delta444-707)) appear incapable of processing more stable helices and are thus mechanistically distinct from collagenolytic MMPs. The collagen specificity of MMPs appears to be based on a combination of substrate sequence and thermal stability. Analysis of the hydrolysis of triple-helical peptides by an MMP mutant indicated that Tyr(210) functions in triple helix binding and hydrolysis, but not in processing triple helices of increasing thermal stabilities. Further exploration of MMP active sites and exosites, in combination with substrate conformation, may prove valuable for additional dissection of collagenolysis and yield information useful in the design of more selective MMP inhibitors.     

Human mesotrypsin exhibits restricted S1' subsite specificity with a strong preference for small polar side chains

Mesotrypsin, an inhibitor-resistant human trypsin isoform, does not activate or degrade pancreatic protease zymogens at a significant rate. These observations led to the proposal that mesotrypsin is a defective digestive protease on protein substrates. Surprisingly, the studies reported here with alpha1-antitrypsin (alpha1AT) revealed that, even though mesotrypsin was completely resistant to this serpin-type inhibitor, it selectively cleaved the Lys10-Thr11 peptide bond at the N-terminus. Analyzing a library of alpha1AT mutants in which Thr11 was mutated to various amino acids, we found that mesotrypsin hydrolyzed lysyl peptide bonds containing Thr or Ser at the P1' position with relatively high specificity (kcat/KM approximately 10(5) m(-1) x s(-1)). Compared with Thr or Ser, P1' Gly or Met inhibited cleavage 13- and 25-fold, respectively, whereas P1' Asn, Asp, Ile, Phe or Tyr resulted in 100-200-fold diminished rates of proteolysis, and Pro abolished cleavage completely. Consistent with the Ser/Thr P1' preference, mesotrypsin cleaved the Arg358-Ser359 reactive-site peptide bond of alpha1AT Pittsburgh and was rapidly inactivated by the serpin mechanism (ka approximately 10(6) m(-1) s(-1)). Taken together, the results indicate that mesotrypsin is not a defective protease on polypeptide substrates in general, but exhibits a relatively high specificity for Lys/Arg-Ser/Thr peptide bonds. This restricted, thrombin-like subsite specificity explains why mesotrypsin cannot activate pancreatic zymogens, but might activate certain proteinase-activated receptors. The observations also identify alpha1AT Pittsburgh as an effective mesotrypsin inhibitor and the serpin mechanism as a viable stratagem to overcome the inhibitor-resistance of mesotrypsin.     

Cdk1: A kinase with changing substrate specificity

Comment on: Kõivomägi M, et al. Mol Cell 2011; 42:610-23.     

Significance of hydrogen bonding at the S(1)' subsite of calpain I.

alpha-Ketohydroxamates were synthesized as bioisosteres of alpha-ketoamides. The alpha-ketohydroxamates were generally more potent than the corresponding alpha-ketoamides. The potency of the compounds suggests that hydrogen bonding and steric bulk of substituents on the nitrogen atom of the ketoamide moiety influence calpain inhibition.     

Thiol-based angiotensin-converting enzyme 2 inhibitors: P1' modifications for the exploration of the S1' subsite

Explorations of the S(1') subsite of ACE2 via modifications of the P(1') methylene biphenyl moiety of thiol-based metalloprotease inhibitors led to improvements in ACE2 selectivity versus ACE and NEP, while maintaining potent ACE2 inhibition.     

Comparison of the substrate specificity of two potyvirus proteases

The substrate specificity of the nuclear inclusion protein a (NIa) proteolytic enzymes from two potyviruses, the tobacco etch virus (TEV) and tobacco vein mottling virus (TVMV), was compared using oligopeptide substrates. Mutations were introduced into TEV protease in an effort to identify key determinants of substrate specificity. The specificity of the mutant enzymes was assessed by using peptides with complementary substitutions. The crystal structure of TEV protease and a homology model of TVMV protease were used to interpret the kinetic data. A comparison of the two structures and the experimental data suggested that the differences in the specificity of the two enzymes may be mainly due to the variation in their S4 and S3 binding subsites. Two key residues predicted to be important for these differences were replaced in TEV protease with the corresponding residues of TVMV protease. Kinetic analyses of the mutants confirmed that these residues play a role in the specificity of the two enzymes. Additional residues in the substrate-binding subsites of TEV protease were also mutated in an effort to alter the specificity of the enzyme.     

Structural and energetic determinants of the S1-site specificity in serine proteases.

In recent years the number of determined three-dimensional structures of serine proteases that are accompanied by detailed mutational studies has grown rapidly. In particular, spatial structures have been described for enzymes involved in processes of critical medical significance, often related to severe pathophysiological diseases. There has also been significant progress in the understanding of the structural grounds for the substrate specificity of serine proteases. This review is concerned mainly with primary structural determinants of the S1 specificity, the crucial component of substrate selectivity, often in relation to more distant specificity elements, which cooperatively influence the S1 site.     

Amino acid preferences for a critical substrate binding subsite of retroviral proteases in type 1 cleavage sites

The specificities of the proteases of 11 retroviruses representing each of the seven genera of the family Retroviridae were studied using a series of oligopeptides with amino acid substitutions in the P2 position of a naturally occurring type 1 cleavage site (Val-Ser-Gln-Asn-Tyr Pro-Ile-Val-Gln; the arrow indicates the site of cleavage) in human immunodeficiency virus type 1 (HIV-1). This position was previously found to be one of the most critical in determining the substrate specificity differences of retroviral proteases. Specificities at this position were compared for HIV-1, HIV-2, equine infectious anemia virus, avian myeloblastosis virus, Mason-Pfizer monkey virus, mouse mammary tumor virus, Moloney murine leukemia virus, human T-cell leukemia virus type 1, bovine leukemia virus, human foamy virus, and walleye dermal sarcoma virus proteases. Three types of P2 preferences were observed: a subgroup of proteases preferred small hydrophobic side chains (Ala and Cys), and another subgroup preferred large hydrophobic residues (Ile and Leu), while the protease of HIV-1 preferred an Asn residue. The specificity distinctions among the proteases correlated well with the phylogenetic tree of retroviruses prepared solely based on the protease sequences. Molecular models for all of the proteases studied were built, and they were used to interpret the results. While size complementarities appear to be the main specificity-determining features of the S2 subsite of retroviral proteases, electrostatic contributions may play a role only in the case of HIV proteases. In most cases the P2 residues of naturally occurring type 1 cleavage site sequences of the studied proteases agreed well with the observed P2 preferences.     

Allosteric properties, substrate specificity, and subsite affinities of honeybee alpha-glucosidase I

The substrate specificity of honeybee alpha-glucosidase I, a monomeric enzyme was kinetically investigated. Unusual kinetic features were observed in the cleavage reactions of sucrose, maltose, p-nitrophenyl alpha-glucoside, phenyl alpha-glucoside, turanose, and maltodextrin (DP = 13). At relatively high substrate concentrations, the velocities of liberation of fructose from sucrose, glucose from maltose, p-nitrophenol from p-nitrophenyl alpha-glucoside, and phenol from phenyl alpha-glucoside were accelerated, and so the Lineweaver-Burk plots were convex, indicating negative kinetic cooperativity: the Hill coefficients were calculated to be 0.50, 0.64, 0.50, and 0.67 for sucrose, maltose, p-nitrophenyl alpha-glucoside, and phenyl alpha-glucoside, respectively. For the degradation of turanose and maltodextrin, the enzyme showed a sigmoidal curve in v versus s plots and thus catalyzed the reaction with positive kinetic cooperativity. The Lineweaver-Burk plots were concave and the Hill coefficients were 1.2 and 1.5 for turanose and maltodextrin, respectively. These unique properties cannot be interpreted by the reaction mechanism that Huber and Thompson proposed: (1973) Biochemistry 12, 4011-4020. The rate parameters for the hydrolysis of sucrose, maltose, p-nitrophenyl alpha-glucoside and phenyl alpha-glucoside were estimated by extrapolating the linear part of the Lineweaver-Burk plots at low substrate concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)     

GroEL/S substrate specificity based on substrate unfolding propensity

Phage P22 wild-type (WT) coat protein does not require GroEL/S to fold but temperature-sensitive-folding (tsf) coat proteins need the chaperone complex for correct folding. WT coat protein and all variants absolutely require P22 scaffolding protein, an assembly chaperone, to assemble into precursor structures termed procapsids. Previously, we showed that a global suppressor (su) substitution, T1661, which rescues several tsf coat protein variants, functioned by inducing GroEL/S. This led to an increased formation of tsf:T1661 coat protein:GroEL complexes compared with the tsf parents. The increased concentration of complexes resulted in more assembly-competent coat proteins because of a shift in the chaperone-driven kinetic partitioning between aggregation-prone intermediates toward correct folding and assembly. We have now investigated the folding and assembly of coat protein variants that carry a different global su substitution, F170L. By monitoring levels of phage production in the presence of a dysfunctional GroEL we found that tsf:F170L proteins demonstrate a less stringent requirement for GroEL. Tsf:F170L proteins also did not cause induction of the chaperones. Circular dichroism and tryptophan fluorescence indicate that the native state of the tsf: F170L coat proteins is restored to WT-like values. In addition, native acrylamide gel electrophoresis shows a stabilized native state for tsf:F170L coat proteins. The F170L su substitution also increases procapsid production compared with their tsf parents. We propose that the F170L su substitution has a decreased requirement for the chaperones GroEL and GroES as a result of restoring the tsf coat proteins to a WT-like state. Our data also suggest that GroEL/S can be induced by increasing the population of unfolding intermediates.     

New thiol inhibitor of Achromobacter iophagus collagenase. Specificity of the enzyme's S3' subsite

New synthetic mercaptotripeptides (HS-CH2-CH2-CO-Pro-Yaa) which inhibit Achromobacter iophagus collagenase were produced in order to obtain more powerful bacterial collagenase inhibitors than currently available, and to investigate the specificity of the S3' subsite of the enzyme. Since similar binding constants were found for inhibitors carrying uncharged residues of various sizes in the P3' position (Yaa = Ala, Leu, Phe, Pro, Hyp) steric hindrance at the collagenase S3' appears relatively limited. The compound (HS-CH2-CH2-CO-Pro-Arg), which carries an arginine residue in the position P3' and had the highest inhibition constant of the series tested (Ki = 0.5 microM), proved to be the strongest inhibitor so far reported in the literature. The weakest in the present series was the compound (HS-CH2-CH2-CO-Pro-Asp) which carries an aspartic residue in position P3' and had a Ki = 70 microM. The present work revealed that the charged groups in the P3' position play a key role in the interaction of the inhibitors with the enzyme.     

Reduced-bond tight-binding inhibitors of HIV-1 protease. Fine tuning of the enzyme subsite specificity.

Truncation of a peptide substrate in the N-terminus and replacement of its scissile amide bond with a non-cleavable reduced bond results in a potent inhibitor of HIV-1 protease. A series of such inhibitors has been synthesized, and S2-S3' subsites of the protease binding cleft mapped. The S2 pocket requires bulky Boc or PIV groups, large aromatic Phe residues are preferred in P1 and P1' and Glu in P2'. The S3' pocket prefers Phe over small Ala or Val. Introduction of a Glu residue into the P2' position yields a tight-binding inhibitor of HIV-1 protease, Boc-Phe-[CH2-NH]-Phe-Glu-Phe-OMe, with a subnanomolar inhibition constant. The relevant peptide derived from the same amino acid sequence binds to the protease with a Ki of 110 nM, thus still demonstrating a good fit of the amino acid residues into the protease binding pockets and also the importance of the flexibility of P1-P1' linkage for proper binding. A new type of peptide bond mimetic, N-hydroxylamine -CH2-N(OH)-, has been synthesized. Binding of hydroxylamino inhibitor of HIV-1 protease is further improved with respect to reduced-bond inhibitor.     

The role of the S1 domain in exoribonucleolytic activity: substrate specificity and multimerization

RNase II is a 3'-5' exoribonuclease that processively hydrolyzes single-stranded RNA generating 5' mononucleotides. This enzyme contains a catalytic core that is surrounded by three RNA-binding domains. At its C terminus, there is a typical S1 domain that has been shown to be critical for RNA binding. The S1 domain is also present in the other major 3'-5' exoribonucleases from Escherichia coli: RNase R and polynucleotide phosphorylase (PNPase). In this report, we examined the involvement of the S1 domain in the different abilities of these three enzymes to overcome RNA secondary structures during degradation. Hybrid proteins were constructed by replacing the S1 domain of RNase II for the S1 from RNase R and PNPase, and their exonucleolytic activity and RNA-binding ability were examined. The results revealed that both the S1 domains of RNase R and PNPase are able to partially reverse the drop of RNA-binding ability and exonucleolytic activity resulting from removal of the S1 domain of RNase II. Moreover, the S1 domains investigated are not equivalent. Furthermore, we demonstrate that S1 is neither responsible for the ability to overcome secondary structures during RNA degradation, nor is it related to the size of the final product generated by each enzyme. In addition, we show that the S1 domain from PNPase is able to induce the trimerization of the RNaseII-PNP hybrid protein, indicating that this domain can have a role in the biogenesis of multimers.     

The mechanism of salivary amylase hydrolysis: role of residues at subsite S2'

Hydrolysis of starch or oligosaccharides by mammalian amylases, in general, results in maltose as the leaving group. The active site of these amylases harbors three aromatic residues Trp59, Tyr62, and Tyr151, which provide stacking interactions to the bound glucose moieties. We hypothesized that Tyr151, located at the S2' subsite, may influence the size of the leaving group. Therefore, using a baculovirus expression system, we generated a mutant Y151M in which the tyrosine at position 151 of human salivary amylase is replaced by a methionine. The specific activity, K(m), rate of hydrolysis, and the product distribution for Y151M were distinctly different from those of the wild-type enzyme using starch and oligosaccharides as substrates. The mutant enzyme Y151M consistently produced glucose as the minimal leaving group and exhibited a twofold increase in K(m). These results suggest that the stacking interaction at subsite S2' in the wild type plays a role in hydrolysis.     

The synthesis, purification, and evaluation of a chromophoric substrate for pepsin and other aspartyl proteases: design of a substrate based on subsite preferences

A convenient chromophoric assay for porcine pepsin has been developed using a new synthetic substrate. The sequence of this substrate was chosen based on the known subsite preferences for this enzyme. The peptide contains a phenylalanyl-p-nitrophenylalanine sequence at the reactive site. Cleavage of this bond yields a change in absorbance at 310 nm of between 1700 and 2000 per mole. This allows kinetic data to be obtained readily and accurately. The products of cleavage have been identified by isolation of a peptide fragment by high-performance liquid chromatography. Values of kcat, Km, and kcat/Km of 94 +/- 6 s-1, 0.13 +/- .04 mM, and 815 +/- 210 s-1/mM-1 were obtained at pH 3.0 and 37 degrees C. The peptide is soluble over the pH range from 2 to 7, thus facilitating determination of the pH dependence of the kinetic parameters. The substrate is also valuable in studying the inhibition of pepsin.     

The role of hydrophobic active-site residues in substrate specificity and acyl transfer activity of penicillin acylase.

Penicillin acylase of Escherichia coli catalyses the hydrolysis and synthesis of beta-lactam antibiotics. To study the role of hydrophobic residues in these reactions, we have mutated three active-site phenylalanines. Mutation of alphaF146, betaF24 and betaF57 to Tyr, Trp, Ala or Leu yielded mutants that were still capable of hydrolysing the chromogenic substrate 2-nitro-5-[(phenylacetyl)amino]-benzoic acid. Mutations on positions alphaF146 and betaF24 influenced both the hydrolytic and acyl transfer activity. This caused changes in the transferase/hydrolase ratios, ranging from a 40-fold decrease for alphaF146Y and alphaF146W to a threefold increase for alphaF146L and betaF24A, using 6-aminopenicillanic acid as the nucleophile. Further analysis of the betaF24A mutant showed that it had specificity constants (kcat/Km) for p-hydroxyphenylglycine methyl ester and phenylglycine methyl ester that were similar to the wild-type values, whereas the specificity constants for p-hydroxyphenylglycine amide and phenylglycine amide had decreased 10-fold, due to a decreased kcat value. A low amidase activity was also observed for the semisynthetic penicillins amoxicillin and ampicillin and the cephalosporins cefadroxil and cephalexin, for which the kcat values were fivefold to 10-fold lower than the wild-type values. The reduced specificity for the product and the high initial transferase/hydrolase ratio of betaF24A resulted in high yields in acyl transfer reactions.