Specificity Profiling of Dual Specificity Phosphatase Vaccinia VH1-related (VHR) Reveals Two Distinct Substrate Binding Modes

Vaccinia VH1-related (VHR) is a dual specificity phosphatase that consists of only a single catalytic domain. Although several protein substrates have been identified for VHR, the elements that control the in vivo substrate specificity of this enzyme remain unclear. In this work, the in vitro substrate specificity of VHR was systematically profiled by screening combinatorial peptide libraries. VHR exhibits more stringent substrate specificity than classical protein-tyrosine phosphatases and recognizes two distinct classes of Tyr(P) peptides. The class I substrates are similar to the Tyr(P) motifs derived from the VHR protein substrates, having sequences of (D/E/φ)(D/S/N/T/E)(P/I/M/S/A/V)pY(G/A/S/Q) or (D/E/φ)(T/S)(D/E)pY(G/A/S/Q) (where φ is a hydrophobic amino acid and pY is phosphotyrosine). The class II substrates have the consensus sequence of (V/A)P(I/L/M/V/F)X_1–6pY (where X is any amino acid) with V/A preferably at the N terminus of the peptide. Site-directed mutagenesis and molecular modeling studies suggest that the class II peptides bind to VHR in an opposite orientation relative to the canonical binding mode of the class I substrates. In this alternative binding mode, the Tyr(P) side chain binds to the active site pocket, but the N terminus of the peptide interacts with the carboxylate side chain of Asp¹⁶⁴, which normally interacts with the Tyr(P) + 3 residue of a class I substrate. Proteins containing the class II motifs are efficient VHR substrates in vitro, suggesting that VHR may act on a novel class of yet unidentified Tyr(P) proteins in vivo.     

Probing the activity of NTHL1 orthologs by targeting conserved amino acid residues

The base excision repair DNA glycosylases, EcoNth and hNTHL1, are homologous, with reported overlapping yet different substrate specificities. The catalytic amino acid residues are known and are identical between the two enzymes although the exact structures of the substrate binding pockets remain to be determined. We sought to explore the sequence basis of substrate differences using a phylogeny-based design of site-directed mutations. Mutations were made for each enzyme in the vicinity of the active site and we examined these variants for glycosylase and lyase activity. Single turnover kinetics were done on a subgroup of these, comparing activity on two lesions, 5,6-dihydrouracil and 5,6-dihydrothymine, with different opposite bases. We report that wild type hNTHL1 and EcoNth are remarkably alike with respect to the specificity of the glycosylase reaction, and although hNTHL1 is a much slower enzyme than EcoNth, the tighter binding of hNTHL1 compensates, resulting in similar k_cat/K_d values for both enzymes with each of the substrates tested. For the hNTHL1 variant Gln287Ala, the specificity for substrates positioned opposite G is lost, but not that of substrates positioned opposite A, suggesting a discrimination role for this residue. The EcoNth Thr121 residue influences enzyme binding to DNA, as binding is significantly reduced with the Thr121Ala variant. Finally, we present evidence that hNTHL1 Asp144, unlike the analogous EcoNth residue Asp44, may be involved in resolving the glycosylase transition state.     

The Acetylation Motif in AMP-Forming Acyl Coenzyme A Synthetases Contains Residues Critical for Acetylation and Recognition by the Protein Acetyltransferase Pat of Rhodopseudomonas palustris

The AMP-forming acyl coenzyme A (acyl-CoA) synthetases are a large class of enzymes found in both anabolic and catabolic pathways that activate fatty acids to acyl-CoA molecules. The protein acetyltransferase (Pat) from Rhodopseudomonas palustris (RpPat) inactivates AMP-forming acyl-CoA synthetases by acetylating the ε-amino group of a conserved, catalytic lysine residue. In all of the previously described RpPat substrates, this lysine residue is located within a PX₄GK motif that has been proposed to be a recognition motif for RpPat. Here, we report five new substrates for RpPat, all of which are also AMP-forming acyl-CoA synthetases. This finding supports the idea that Pat enzymes may have evolved to control the activity of this family of enzymes. Notably, RpPat did not acetylate the wild-type long-chain acyl-CoA synthetase B (RpLcsB; formerly Rpa2714) enzyme of this bacterium. However, a single amino acid change two residues upstream of the acetylation site was sufficient to convert RpLcsB into an RpPat substrate. The results of mutational and functional analyses of RpLcsB and RpPimA variants led us to propose PK/RTXS/T/V/NGKX₂K/R as a substrate recognition motif. The underlined positions within this motif are particularly important for acetylation by RpPat. The first residue, threonine, is located 4 amino acids upstream of the acetylation site. The second residue can be S/T/V/N and is located two positions upstream of the acetylation site. Analysis of published crystal structures suggests that the side chains of these two residues are very close to the acetylated lysine residue, indicating that they may directly interact with RpPat.     

Importance of secondary enzyme-substrate interactions in human cathepsin G and chymotrypsin II catalysis

The active center of human leukocyte cathepsin G, human pancreatic chymotrypsin II, and bovine α-chymotrypsin has been investigated with a series of substrates of general formula succinyl-(l-alanine)_n-phenylalanine-p-nitroanilide (n = 0 to 3). The three proteinases have an extended substrate binding site which includes at least six subsites. Secondary interactions are very important for their catalytic power since the longest substrate is hydrolyzed 600 to 1100 times faster than the shortest one. The regulatory subsite is S₄ for bovine α-chymotrypsin and human cathepsin G whereas it is S₅ for human chymotrypsin II. Cathepsin G is a poor catalyst compared to the two other enzymes.     

The catalytic properties of Thermus thermophilus SG0.5JP17-16 laccase were regulated by the conformational dynamics of pocket loop 6

BackgroundLaccase is one member of the blue multicopper oxidase family. It can catalyze the oxidation of various substrates. The Thermus thermophilus SG0.5JP17-16 laccase (lacTT) is thermostable, pH-stable, and high tolerance to halides, and can decolorize the synthetic dyes. In lacTT, the function of the loop 6 constructing the substrate-binding pocket wasn't clear.MethodsThe residues Asp394 and Asp396 located in loop 6, and were used to probe how the loop 6 influenced catalytic properties of the laccase. Site-directed mutagenesis was performed for two amino acids. Kinetic assay was utilized to characterize the catalytic efficiency of mutants. Mutants with different catalytic activities were used to decolorize the synthetic dyes to clarify the relationship between the catalytic efficiency and dye decolorization. Redox potential, structural and spectral analyses were performed to explain the differences in laccase activity between wild type and mutant enzymes.ResultsD394M, D394E and D394R mutants with the lower laccase activity displayed a decreased decolorization efficiency, while D396A, D396M and D396E mutant enzymes with higher catalytic efficiency decolorized the synthetic dye more efficiently than the wild type enzyme.ConclusionsThe pocket loop 6 might experience a conformational dynamics. The D394 residue controlled this conformation change by amino acid interaction networks containing the D396 residue at the entrance of substrate channel.General significancesThese studies may provide clues to improve the activity of the laccase for the better use in industrial applications, and/or contribute to further understanding the mechanism of laccase oxidation on the substrate.     

Penicillin acylase mutants with altered site-directed activity from Kluyvera citrophila

Summary Oligonucleotide-directed mutagenesis has been used to obtain specific changes in the penicillin acylase gene from Kluyvera citrophila. Wild-type and mutant proteins were purified and the kinetic constants for different substrates were determined. Mutations in Met168 highly decreased the specificity constant of the enzyme for penicillin G, penicillin V and phenylacetyl-4-aminobenzoic acid and the catalytic constant k _cat for phenylacetyl-4-aminobenzoic acid. Likewise, the phenylmethylsulphonyl-fluoride sensitivity was significantly decreased. It is concluded that the 168 residue is involved in binding by interaction with the acid moiety of the substrate. A putative penicillin-binding domain was located in penicillin acylase by sequence homology with other penicillin-recognizing enzymes. Lys374 and His481, the conserved amino acid residues that are essential for catalysis in these enzymes, can be changed in penicillin acylase with no changes to the k _cat and phenylmethylsulphonyl fluoride reactivity, but change the K _m.The likelihood of the existence of this proposed penicillin binding site is discussed. The reported results might be used to alter the substrate specificity of penicillin acylase in order to hydrolyse substrates of industrial significance other than penicillins. Offprint requests to: I. Prieto     

Thermostability improvement of maltogenic amylase MAUS149 by error prone PCR

The thermostability of maltogenic amylase from Bacillus sp. US149 (MAUS149) was improved by random mutagenesis using error prone PCR. The library constructed for the mutants obtained was subjected to screening, leading to the selection of a thermostable mutant enzyme named MA-A27. The latter was noted to contain four single mutations, namely D46V, P78L, V145A, and K548E. The half-life times recorded for MA-A27 at 50 °C and 55 °C were 70 min and 25 min, compared to 30 min and 13 min for the wild type, respectively. The results from molecular modeling attributed the increase in thermostability observed for MA-A27 to P78L and K548E substitutions that led to new hydrogen bond and salt bridge formations. Further site-directed mutagenesis studies showed that the P78L and K548E single mutations underwent an increase in thermostability, thus confirming the joint contribution of both substitutions to the increase in thermostability observed for MA-A27.     

Processivity, Substrate Binding, and Mechanism of Cellulose Hydrolysis by Thermobifida fusca Cel9A

Thermobifida fusca Cel9A-90 is a processive endoglucanase consisting of a family 9 catalytic domain (CD), a family 3c cellulose binding module (CBM3c), a fibronectin III-like domain, and a family 2 CBM. This enzyme has the highest activity of any individual T. fusca enzyme on crystalline substrates, particularly bacterial cellulose (BC). Mutations were introduced into the CD or the CBM3c of Cel9A-68 using site-directed mutagenesis. The mutant enzymes were expressed in Escherichia coli; purified; and tested for activity on four substrates, ligand binding, and processivity. The results show that H125 and Y206 play an important role in activity by forming a hydrogen bonding network with the catalytic base, D58; another important supporting residue, D55; and Glc(−1) O1. R378, a residue interacting with Glc(+1), plays an important role in processivity. Several enzymes with mutations in the subsites Glc(−2) to Glc(−4) had less than 15% activity on BC and markedly reduced processivity. Mutant enzymes with severalfold-higher activity on carboxymethyl cellulose (CMC) were found in the subsites from Glc(−2) to Glc(−4). The CBM3c mutant enzymes, Y520A, R557A/E559A, and R563A, had decreased activity on BC but had wild-type or improved processivity. Mutation of D513, a conserved residue at the end of the CBM, increased activity on crystalline cellulose. Previous work showed that deletion of the CBM3c abolished crystalline activity and processivity. This study shows that it is residues in the catalytic cleft that control processivity while the CBM3c is important for loose binding of the enzyme to the crystalline cellulose substrate.     

Substitution of the amino acid at position 102 with polar and aromatic residues influences substrate specificity of lactate dehydrogenase

The Gin residue at amino acid position 102 ofBacillus stearothermophilus lactate dehydrogenase was replaced with Ser, Thr, Tyr, or Phe to investigate the effect on substrate recognition. The Q102S and Q102T mutant enzymes were found to have a broader range of substrate specificity (measured byk _cat/K _m) than the wild-type enzyme. However, it is evident that either Ser or Thr at position 102 are of a size able to accommodate a wide variety of substrates in the active site and substrate specificity appears to rely largely on size discrimination in these mutants. The Q102F and Q102Y mutant enzymes have low catalytic efficiency and do not show this relaxed substrate specificity. However, their activities are restored by the presence of an aromatic substrate. All of the enzymes have a very low catalytic efficiency with branched chain aliphatic substrates.Abbreviations used BSLDH Bacillus stearothermophilus lactate dehydrogenase - FBP fructose-1,6-bisphosphate - HP hydroxypyruvate - KB ketobutyrate - KC ketocaproate - KV ketovalerate - MDH malate dehydrogenase - PP phenylpyruvate - PYR pyruvate - RBE relative binding energy     

Crystal structures of SULT1A2 and SULT1A1∗3: Insights into the substrate inhibition and the role of Tyr149 in SULT1A2

The cytosolic sulfotransferases (SULTs) in vertebrates catalyze the sulfonation of endogenous thyroid/steroid hormones and catecholamine neurotransmitters, as well as a variety of xenobiotics, using 3′-phosphoadenosine 5′-phosphosulfate (PAPS) as the sulfonate donor. In this study, we determined the structures of SULT1A2 and an allozyme of SULT1A1, SULT1A1∗3, bound with 3′-phosphoadenosine 5′-phosphate (PAP), at 2.4 and 2.3 Å resolution, respectively. The conformational differences between the two structures revealed a plastic substrate-binding pocket with two channels and a switch-like substrate selectivity residue Phe247, providing clearly a structural basis for the substrate inhibition. In SULT1A2, Tyr149 extends approximately 2.1 Å further to the inside of the substrate-binding pocket, compared with the corresponding His149 residue in SULT1A1∗3. Site-directed mutagenesis study showed that, compared with the wild-type SULT1A2, mutant Tyr149Phe SULT1A2 exhibited a 40 times higher K_m and two times lower V_max with p-nitrophenol as substrate. These latter data imply a significant role of Tyr149 in the catalytic mechanism of SULT1A2.     

Engineering the Substrate Specificity of a Thermophilic Penicillin Acylase from Thermus thermophilus

A homologue of the Escherichia coli penicillin acylase is encoded in the genomes of several thermophiles, including in different Thermus thermophilus strains. Although the natural substrate of this enzyme is not known, this acylase shows a marked preference for penicillin K over penicillin G. Three-dimensional models were created in which the catalytic residues and the substrate binding pocket were identified. Through rational redesign, residues were replaced to mimic the aromatic binding site of the E. coli penicillin G acylase. A set of enzyme variants containing between one and four amino acid replacements was generated, with altered catalytic properties in the hydrolyses of penicillins K and G. The introduction of a single phenylalanine residue in position α188, α189, or β24 improved the K_m for penicillin G between 9- and 12-fold, and the catalytic efficiency of these variants for penicillin G was improved up to 6.6-fold. Structural models, as well as docking analyses, can predict the positioning of penicillins G and K for catalysis and can demonstrate how binding in a productive pose is compromised when more than one bulky phenylalanine residue is introduced into the active site.     

Substitution of Asp-210 in HAP1 (APE/Ref-1) eliminates endonuclease activity but stabilises substrate binding

HAP1, also known as APE/Ref-1, is the major apurinic/apyrimidinic (AP) endonuclease in human cells. Previous structural studies have suggested a possible role for the Asp-210 residue of HAP1 in the enzymatic function of this enzyme. Here, we demonstrate that substitution of Asp-210 by Asn or Ala eliminates the AP endonuclease activity of HAP1, while substitution by Glu reduces specific activity ~500-fold. Nevertheless, these mutant proteins still bind efficiently to oligonucleotides containing either AP sites or the chemically unrelated bulky p-benzoquinone (pBQ) derivatives of dC, dA and dG, all of which are substrates for HAP1. These results indicate that Asp-210 is required for catalysis, but not substrate recognition, consistent with enzyme kinetic data indicating that the HAP1–D210E protein has a 3000-fold reduced K_cat for AP site cleavage, but an unchanged K_m. Through analysis of the binding of Asp-210 substitution mutants to oligonucleotides containing either an AP site or a pBQ adduct, we conclude that the absence of Asp-210 allows the formation of a stable HAP1–substrate complex that exists only transiently during the catalytic cycle of wild-type HAP1 protein. We interpret these data in the context of the structure of the HAP1 active site and the recently determined co-crystal structure of HAP1 bound to DNA substrates.     

Virtual screening of mandelate racemase mutants with enhanced activity based on binding energy in the transition state

Mandelate racemase (MR) is a promising candidate for the dynamic kinetic resolution of racemates. However, the poor activity of MR towards most of its non-natural substrates limits its widespread application. In this work, a virtual screening method based on the binding energy in the transition state was established to assist in the screening of MR mutants with enhanced catalytic efficiency. Using R-3-chloromandelic acid as a model substrate, a total of 53 mutants were constructed based on rational design in the two rounds of screening. The number of mutants for experimental validation was brought down to 17 by the virtual screening method, among which 14 variants turned out to possess improved catalytic efficiency. The variant V26I/Y54V showed 5.2-fold higher catalytic efficiency (k_cat/K_m) towards R-3-chloromandelic acid than that observed for the wild-type enzyme. Using this strategy, mutants were successfully obtained for two other substrates, R-mandelamide and R-2-naphthylglycolate (V26I and V29L, respectively), both with a 2-fold improvement in catalytic efficiency. These results demonstrated that this method could effectively predict the trend of mutational effects on catalysis. Analysis from the energetic and structural assays indicated that the enhanced interactions between the active sites and the substrate in the transition state led to improved catalytic efficiency. It was concluded that this virtual screening method based on the binding energy in the transition state was beneficial in enzyme rational redesign and helped to better understand the catalytic properties of the enzyme.     

Changes in the Catalytic Properties of Pyrococcus furiosus Thermostable Amylase by Mutagenesis of the Substrate Binding Sites

Pyrococcus furiosus thermostable amylase (TA) is a cyclodextrin (CD)-degrading enzyme with a high preference for CDs over maltooligosaccharides. In this study, we investigated the roles of four residues (His414, Gly415, Met439, and Asp440) in the function of P. furiosus TA by using site-directed mutagenesis and kinetic analysis. A variant form of P. furiosus TA containing two mutations (H414N and G415E) exhibited strongly enhanced α-(1,4)-transglycosylation activity, resulting in the production of a series of maltooligosaccharides that were longer than the initial substrates. In contrast, the variant enzymes with single mutations (H414N or G415E) showed a substrate preference similar to that of the wild-type enzyme. Other mutations (M439W and D440H) reversed the substrate preference of P. furiosus TA from CDs to maltooligosaccharides. Relative substrate preferences for maltoheptaose over β-CD, calculated by comparing k_cat/K_m ratios, of 1, 8, and 26 for wild-type P. furiosus TA, P. furiosus TA with D440H, and P. furiosus TA with M439W and D440H, respectively, were found. Our results suggest that His414, Gly415, Met439, and Asp440 play important roles in substrate recognition and transglycosylation. Therefore, this study provides information useful in engineering glycoside hydrolase family 13 enzymes.     

Substrate specificities of family 1 UGTs gained by domain swapping

Family 1 glycosyltransferases are a group of enzymes known to embrace a large range of different substrates. This study devises a method to enhance the range of substrates even further by combining domains from different glycosyltransferases to gain improved substrate specificity and catalytic efficiency. Chimeric glycosyltransferases were made by combining domains from seven different family 1 glycosyltransferases, UGT71C1, UGT71C2, UGT71E1, UGT85C1, UGT85B1, UGT88B1 and UGT94B1. Twenty different chimeric glycosyltransferases were formed of which twelve were shown to be catalytically active. The chimeric enzymes of Arabidopsis thaliana UGT71C1 and UGT71C2 showed major changes in acceptor substrate specificity and were able to glycosylate etoposide significantly better than the parental UGT71C1 and UGT71C2 enzymes, with K_cat and efficiency coefficients 3.0 and 2.6 times higher, respectively. Chimeric glycosyltransferases of UGT71C1 combined with Stevia rebaudiana UGT71E1, also afforded enzymes with high catalytic efficiency, even though the two enzymes only display 38% amino acid sequence identity. These chimeras show a significantly altered regiospecificity towards especially trans-resveratrol, enabling the production of trans-resveratrol-β-4′-O-glucoside (resveratroloside). The study demonstrates that it is possible to obtain improved catalytic properties by combining domains from both closely as well as more distantly related glycosyltransferases. The substrate specificity gained by the chimeras is difficult to predict because factors determining the acceptor specificity reside in the N- terminal as well as the C-terminal domains.     

Alteration of Chain Length Substrate Specificity of Aeromonas caviae R-Enantiomer-Specific Enoyl-Coenzyme A Hydratase through Site-Directed Mutagenesis

Aeromonas caviae R-specific enoyl-coenzyme A (enoyl-CoA) hydratase (PhaJ_Ac) is capable of providing (R)-3-hydroxyacyl-CoA with a chain length of four to six carbon atoms from the fatty acid β-oxidation pathway for polyhydroxyalkanoate (PHA) synthesis. In this study, amino acid substitutions were introduced into PhaJ_Ac by site-directed mutagenesis to investigate the feasibility of altering the specificity for the acyl chain length of the substrate. A crystallographic structure analysis of PhaJ_Ac revealed that Ser-62, Leu-65, and Val-130 define the width and depth of the acyl-chain-binding pocket. Accordingly, we targeted these three residues for amino acid substitution. Nine single-mutation enzymes and two double-mutation enzymes were generated, and their hydratase activities were assayed in vitro by using trans-2-octenoyl-CoA (C₈) as a substrate. Three of these mutant enzymes, L65A, L65G, and V130G, exhibited significantly high activities toward octenoyl-CoA than the wild-type enzyme exhibited. PHA formation from dodecanoate (C₁₂) was examined by using the mutated PhaJ_Ac as a monomer supplier in recombinant Escherichia coli LS5218 harboring a PHA synthase gene from Pseudomonas sp. strain 61-3 (phaC1_Ps). When L65A, L65G, or V130G was used individually, increased molar fractions of 3-hydroxyoctanoate (C₈) and 3-hydroxydecanoate (C₁₀) units were incorporated into PHA. These results revealed that Leu-65 and Val-130 affect the acyl chain length substrate specificity. Furthermore, comparative kinetic analyses of the wild-type enzyme and the L65A and V130G mutants were performed, and the mechanisms underlying changes in substrate specificity are discussed.     

Structural Basis of the Stereospecificity of Bacterial B12-dependent 2-Hydroxyisobutyryl-CoA Mutase

Bacterial coenzyme B₁₂-dependent 2-hydroxyisobutyryl-CoA mutase (HCM) is a radical enzyme catalyzing the stereospecific interconversion of (S)-3-hydroxybutyryl- and 2-hydroxyisobutyryl-CoA. It consists of two subunits, HcmA and HcmB. To characterize the determinants of substrate specificity, we have analyzed the crystal structure of HCM from Aquincola tertiaricarbonis in complex with coenzyme B₁₂ and the substrates (S)-3-hydroxybutyryl- and 2-hydroxyisobutyryl-CoA in alternative binding. When compared with the well studied structure of bacterial and mitochondrial B₁₂-dependent methylmalonyl-CoA mutase (MCM), HCM has a highly conserved domain architecture. However, inspection of the substrate binding site identified amino acid residues not present in MCM, namely HcmA Ile^A90 and Asp^A117. Asp^A117 determines the orientation of the hydroxyl group of the acyl-CoA esters by H-bond formation, thus determining stereospecificity of catalysis. Accordingly, HcmA D117A and D117V mutations resulted in significantly increased activity toward (R)-3-hydroxybutyryl-CoA. Besides interconversion of hydroxylated acyl-CoA esters, wild-type HCM as well as HcmA I90V and I90A mutant enzymes could also isomerize pivalyl- and isovaleryl-CoA, albeit at >10 times lower rates than the favorite substrate (S)-3-hydroxybutyryl-CoA. The nonconservative mutation HcmA D117V, however, resulted in an enzyme showing high activity toward pivalyl-CoA. Structural requirements for binding and isomerization of highly branched acyl-CoA substrates such as 2-hydroxyisobutyryl- and pivalyl-CoA, possessing tertiary and quaternary carbon atoms, respectively, are discussed.     

Characterization of Substrates That Have a Differential Effect on Saccharomyces cerevisiae Protein Kinase A Holoenzyme Activation

The specificity in phosphorylation by kinases is determined by the molecular recognition of the peptide target sequence. In Saccharomyces cerevisiae, the protein kinase A (PKA) specificity determinants are less studied than in mammalian PKA. The catalytic turnover numbers of the catalytic subunits isoforms Tpk1 and Tpk2 were determined, and both enzymes are shown to have the same value of 3 s⁻¹. We analyze the substrate behavior and sequence determinants around the phosphorylation site of three protein substrates, Pyk1, Pyk2, and Nth1. Nth1 protein is a better substrate than Pyk1 protein, and both are phosphorylated by either Tpk1 or Tpk2. Both enzymes also have the same selectivity toward the protein substrates and the peptides derived from them. The three substrates contain one or more Arg-Arg-X-Ser consensus motif, but not all of them are phosphorylated. The determinants for specificity were studied using the peptide arrays. Acidic residues in the position P+1 or in the N-terminal flank are deleterious, and positive residues present beyond P-2 and P-3 favor the catalytic reaction. A bulky hydrophobic residue in position P+1 is not critical. The best substrate has in position P+4 an acidic residue, equivalent to the one in the inhibitory sequence of Bcy1, the yeast regulatory subunit of PKA. The substrate effect in the holoenzyme activation was analyzed, and we demonstrate that peptides and protein substrates sensitized the holoenzyme to activation by cAMP in different degrees, depending on their sequences. The results also suggest that protein substrates are better co-activators than peptide substrates.     

Substrate specificities of Cl- -activated arginine aminopeptidases from human and rat origin

The substrate specificities of four Cl^?-activated arginine aminopeptidases purified from the livers and inflammatory exudates of the rat, human fetal livers, and human erythrocytes were studied using peptides and N-l-aminoacyl-2-naphthylamides as substrates. With 2-naphthylamide substrates, these aminopeptidases showed similar substrate specificity; only the derivatives of Arg and Lys were measurably hydrolyzed. Di- and tripeptides with Arg or Lys as the N-terminal residue were readily split by the enzymes from the livers and inflammatory exudates of the rat and human fetal livers but oligopeptides were not hydrolyzed. Arg- and Lys-peptides were also hydrolyzed by the erythrocyte enzyme but this enzyme additionally split several other peptides, oligopeptides being hydrolyzed at internal bonds. The following properties were similar for all four arginine aminopeptidases: Dipeptides were preferred over tripeptides both in substrate binding and catalysis. The rat and human liver, rat exudate, and human erythrocyte enzymes revealed similar K_m values for the best substrates, the values increasing in the following order: ArgPhe, ArgTrp, ArgLys < ArgVal, ArgGly, Arg-2-naphthylamide < ArgGlyGly. The k_cat values were also similar for the four arginine aminopeptidases. Arg-2-naphthylamide was by far the most rapidly hydrolyzed substrate by all enzymes followed by ArgPhe and ArgTrp. With peptide substrates the highest Cl^? activation (10–20%) was found with ArgPhe and ArgTrp. With Arg-2-naphthylamide, however, the activating effect of 0.2 m Cl^? was severalfold. The hydrophobicity of the C-terminal residue of the substrate seemed to play an important role both in the Cl^? effect and substrate catalysis. Substrate binding, however, also depended on the charged groups of the substrate. Evidently Arg-2-naphthylamide and the peptides were hydrolyzed at the same active center but the mechanisms involved in the hydrolyses of chromogenic substrates and peptides may be different. It was also concluded that the less specific Cl^?-activated enzyme from human erythrocytes does not belong to the same group of Cl^?-activated arginine aminopeptidases that show a narrow substrate specificity.     

Factorizing the role of a critical leucine residue in the binding of substrate to human 20α-hydroxysteroid dehydrogenase (AKR1C1): Molecular modeling and kinetic studies of the Leu308Val mutant enzyme

A comparison of the structures and kinetic properties of human 20α-hydroxysteroid dehydrogenase (AKR1C1) and its mutant enzymes (Leu308Val and Leu308Ala) indicates that Leu308 is a selectivity determinant for substrate binding. While the Leu308Val mutation improved the catalytic efficiency (k_cat/K_m) of AKR1C1 towards the two substrates 5α-pregnane-3α,20α-diol (PregA) and 5β-pregnan-3α-ol-20-one (PregB), the Leu308Ala mutation rendered the enzyme inactive. In the docked model of PregA the conformation of the steroid molecule was similar to that of 20α-hydroxyprogesterone in the crystal structure of the AKR1C1 complex where the steroid did not interact with the catalytic residues Tyr55 and His117. In the case of PregB the steroid interacted with the catalytic residue His117 and formed close contacts with Leu308, suggesting that the binding mechanism of 3α-hydroxysteroids in the active site of AKR1C1 is different from that of 20α-hydroxysteroids.