Enhancement of catalytic efficiency by the combination of site-specific mutations in a carbonic anhydrase-related protein.

A single mutation, involving the replacement of an arginine residue with histidine to reconstruct a zinc-binding site, suffices to change a catalytically inactive murine carbonic anhydrase-related protein (CARP) to an active carbonic anhydrase with a CO2-hydration turnover number of 1.2 x 104 s-1. Further mutations, leading to a more 'carbonic anhydrase-like' active-site cavity, results in increased activity. A quintuple mutant having His94, Gln92, Val121, Val143, and Thr200 (human carbonic anhydrase I numbering system) shows kcat = 4 x 104 s-1 and kcat/Km = 2 x 107 M-1.s-1, greatly exceeding the corresponding values for carbonic anhydrase isozyme III and approaching those characterizing carbonic anhydrase I. In addition, a buffer change from 50 mM Taps/NaOH to 50 mM 1, 2-dimethylimidazole/H2SO4 at pH 9 results in a 14-fold increase in kcat for this quintuple mutant. The CO2-hydrating activity of a double mutant with His94 and Gln92 shows complex pH-dependence, but the other mutants investigated behave as if the activity (kcat/Km) is controlled by the basic form of a single group with pKa near 7.7. In a similar way to human carbonic anhydrase II, the buffer behaves formally as a second substrate in a ping-pong pattern, suggesting that proton transfer between a zinc-bound water molecule and buffer limits the maximal rate of catalysis in both systems at low buffer concentrations. However, the results of isotope-exchange kinetic studies suggest that proton shuttling via His64 is insignificant in the CARP mutant in contrast with carbonic anhydrase II. The replacement of Ile residues with Val in positions 121 or 143 results in measurable 4-nitrophenyl acetate hydrolase activity. The pH-rate profile for this activity has a similar shape to those of carbonic anhydrase I and II. CD spectra of the double mutant with His94 and Gln92 are variable, indicating an equilibrium between a compact form of the protein and a 'molten globule'-like form. The introduction of Thr200 seems to stabilize the protein.     

Directed evolution of the promiscuous esterase activity of carbonic anhydrase II

A promiscuous activity of an existing enzyme can confer an evolutionary advantage by providing an immediate response to a new selection pressure and a starting point for the divergence of a new enzyme. This work seeks to examine how this process might take place. Human carbonic anhydrase II (hCAII) is an enzyme that evolved to catalyze the reversible hydration of CO(2) and performs this task at a remarkable rate (k(cat) approximately 10(6) s(-)(1)). hCAII also exhibits promiscuous activity toward highly activated esters such as 4-nitrophenyl acetate. We describe a much weaker esterase activity of hCAII toward the bulkier and much less activated ester substrate 2-naphthyl acetate (2NA). Directed evolution of hCAII produced a variant with 40-fold higher rates toward 2NA, owing to two mutations: one within the active site (Ala65Val) and one at its mouth (Thr200Ala). Structure-activity studies suggest that these mutations led to adaptation of the active site for bulkier substrates and for the catalysis of nonactivated esters. The mutations did not, however, significantly alter the native activity of hCAII. Our results support the notion that the evolution of a new function can be driven by mutations that increase a promiscuous function (which serves as the starting point for the evolutionary process) but do not harm the native function.     

Structural and functional differences between carbonic anhydrase isoenzymes I and II as studied by site-directed mutagenesis

Site-specific mutagenesis has been used to replace amino acid residues in the active site of human carbonic anhydrase II with residues characterizing carbonic anhydrases I. Previous studies of [Thr200----His]isoenzyme II [Behravan, G., Jonsson, B.-H. & Lindskog, S. (1990) Eur. J. Biochem. 190, 351-357] showed that His200 is important for the specific catalytic properties of isoenzymes I. In this paper some properties of two single mutants, Asn62----Val and Asn67----His, as well as a double mutant, Asn67----His/Thr200----His, are described. The results show that neither Val62 nor His67 give rise to isoenzyme-I-like properties, while the double mutant behaves like the single mutant with His200. At pH 8.9, the variant with Val62 has a higher value of kcat/Km for CO2 hydration than unmodified isoenzyme II, whereas the variant with His67 has an enhanced kcat value. The replacement of Asn62 with Val results in a 20% increase of the 4-nitrophenyl acetate hydrolase activity. For the double mutant, the esterase activity is quite close to that calculated on the assumption that the effects of the two single mutations on the free energy of activation are additive.     

Fine tuning of the catalytic properties of human carbonic anhydrase II. Effects of varying active-site residue 200

The active-site residue Thr200 in human carbonic anhydrase II has been replaced by several different amino acids by site-directed mutagenesis. The CO2 hydration and 4-nitrophenyl acetate hydrolase activities of these variants have been measured, as well as inhibition by the monovalent anion, SCN-. The results show that the replacement of Thr200 with Ser or Ala has no significant effect on the catalyzed rates of CO2 hydration. Also, variants with Asn200 and Gly200 have high activities, whereas the activities of variants with Val, Ile or Arg at position 200 are reduced by factors of 2-3 compared to the unmodified enzyme. The variant with Asp200 has a very low activity in both reactions studied, while most of the other variants have enhanced esterase activities, Thr200----Arg isoenzyme II as much as sevenfold. The Asp200 variant has a low affinity for SCN- as well as for a sulfonamide inhibitor, whereas all the other variants bind SCN- more strongly than unmodified enzyme. While His200 characterizes carbonic anhydrases I, the presence of Arg, Val or Ile as well as His at position 200 in human isoenzyme II seems to result in isoenzyme-I-like functional properties.     

Converting human carbonic anhydrase II into a benzoate ester hydrolase through rational redesign

Enzymes capable of benzoate ester hydrolysis have several potential medical and industrial applications. A variant of human carbonic anhydrase II (HCAII) was constructed, by rational design, that is capable of hydrolysing para-nitrophenyl benzoate (pNPBenzo) with an efficiency comparable to some naturally occurring esterases. The design was based on a previously developed strategy [G. H?st, L.G. M?rtensson, B.H. Jonsson, Redesign of human carbonic anhydrase II for increased esterase activity and specificity towards esters with long acyl chains, Biochim. Biophys. Acta 1764 (2006) 1601-1606.], in which docking of a transition state analogue (TSA) to the active site of HCAII was used to predict mutations that would allow the reaction. A triple mutant, V121A/V143A/T200A, was thus constructed and shown to hydrolyze pNPBenzo with k(cat)/K(M)=625 (+/- 38) M(-1) s(-1). It is highly active with other ester substrates as well, and hydrolyzes para-nitrophenyl acetate with k(cat)/K(M)=101,700 (+/- 4800) M(-1) s(-1), which is the highest esterase efficiency so far for any CA variant. A parent mutant (V121A/V143A) has measurable K(M) values for para-nitrophenyl butyrate (pNPB) and valerate (pNPV), but for V121A/V143A/T200A no K(M) could be determined, showing that the additional T200A mutation has caused a decreased substrate binding. However, k(cat)/K(M) is higher with both substrates for the triple mutant, indicating that binding energy has been diverted from substrate binding to transition state stabilization.     

Mutational analysis of protein substrate presentation in the post-translational attachment of biotin to biotin domains

Biotinylation in vivo is an extremely selective post-translational event where the enzyme biotin protein ligase (BPL) catalyzes the covalent attachment of biotin to one specific and conserved lysine residue of biotin-dependent enzymes. The biotin-accepting lysine, present in a conserved Met-Lys-Met motif, resides in a structured domain that functions as the BPL substrate. We have employed phage display coupled with a genetic selection to identify determinants of the biotin domain (yPC-104) of yeast pyruvate carboxylase 1 (residues 1075-1178) required for interaction with BPL. Mutants isolated using this strategy were analyzed by in vivo biotinylation assays performed at both 30 degrees C and 37 degrees C. The temperature-sensitive substrates were reasoned to have structural mutations, leading to compromised conformations at the higher temperature. This interpretation was supplemented by molecular modeling of yPC-104, since these mutants mapped to residues involved in defining the structure of the biotin domain. In contrast, substitution of the Met residue N-terminal to the target lysine with either Val or Thr produced mutations that were temperature-insensitive in the in vivo assay. Furthermore, these two mutant proteins and wild-type yPC-104 showed identical susceptibility to trypsin, consistent with these substitutions having no structural effect. Kinetic analysis of enzymatic biotinylation using purified Met --> Thr/Val mutant proteins with both yeast and Escherichia coli BPLs revealed that these substitutions had a strong effect upon K(m) values but not k(cat). The Met --> Thr mutant was a poor substrate for both BPLs, whereas the Met --> Val substitution was a poor substrate for bacterial BPL but had only a 2-fold lower affinity for yeast BPL than the wild-type peptide. Our data suggest that substitution of Thr or Val for the Met N-terminal of the biotinyl-Lys results in mutants specifically compromised in their interaction with BPL.     

Arginine kinase from Nautilus pompilius, a living fossil. Site-directed mutagenesis studies on the role of amino acid residues in the Guanidino specificity region

Arginine kinases were isolated from the cephalopods Nautilus pompilius, Octopus vulgaris, and Sepioteuthis lessoniana, and the cDNA-derived amino acid sequences have been determined. Although the origin and evolution of cephalopods have long been obscure, this work provides the first molecular evidence for the phylogenetic position of Cephalopoda in molluscan evolution. A crystal structure for Limulus arginine kinase showed that four amino acid residues (Ser(63), Gly(64), Val(65), and Tyr(68)) are hydrogen-bonded with the substrate arginine. We introduced three independent mutations, Ser(63) --> Gly, Ser(63) --> Thr, and Tyr(68) --> Ser, in Nautilus arginine kinase. One of the mutants had a considerably reduced substrate affinity, accompanied by a decreased V(max). In other mutants, the activity was lost almost completely. It is known that substantial conformational changes take place upon substrate binding in arginine kinase. We hypothesize that the hydrogen bond between Asp(62) and Arg(193) stabilizes the closed, substrate-bound state. Site-directed mutagenesis studies strongly support this hypothesis. The mutant (Asp(62) --> Gly or Arg(193) --> Gly), which destabilizes the maintenance of the closed state and/or perhaps disrupts the unique topology of the catalytic pocket, showed only a very weak activity (0.6-1.5% to the wild-type).     

Recognition site for the side chain of 2-ketoacid substrate in d-lactate dehydrogenase

Replacement of Tyr52 with Val or Ala in Lactobacillus pentosus d-lactate dehydrogenase induced high activity and preference for large aliphatic 2-ketoacids and phenylpyruvate. On the other hand, replacements with Arg, Thr or Asp severely reduced the enzyme activity, and the Tyr52Arg enzyme, the only one that exhibited significant enzyme activity, showed a similar substrate preference to the Tyr52Val and Tyr52Ala enzymes. Replacement of Phe299 with Gly or Ser greatly reduced the enzyme activity with less marked change in the substrate preference. Except for the Phe299Ser enzyme, these mutant enzymes with low catalytic activity consistently stimulated NADH oxidation in the absence of 2-ketoacid substrates. However, the double mutant enzymes, Tyr52Arg/Phe299Gly and Tyr52Thr/Phe299Ser, did not exhibit synergically decreased enzyme activity or the substrate-independent NADH oxidation, but rather increased activities toward certain 2-ketoacid substrates. These results indicate that the coordinative combination of amino acid residues at two positions is pivotal in both the functional recognition of the 2-ketoacid side chain and the protection of the bound NADH molecule from the solvent. Multiplicity in such combinations appears to provide d-LDH-related 2-hydroxyacid dehydrogenases with a great variety of catalytic and physiological functions.     

Substrate specificity of cucumisin on synthetic peptides

The substrate specificity of cucumisin [EC 3.4.21.25] was identified by the use of the synthetic peptide substrates Leu(m)-Pro-Glu-Ala-Leu(n) (m = 0-4, n = 0-3). Neither Pro-Glu-Ala-Leu (m = 0) nor Leu-Pro-Glu-Ala (n = 0) was cleaved by cucumisin, however other analogus peptides were cleaved between Glu-Ala. The hydrolysis rates of Leu(m)-Pro-Glu-Ala-Leu increased with the increase of m = 1 to 2 and 3, but was however, essentially same with the increase of m = 3 to 4. Similarly, the hydrolysis rates of Leu-Leu-Pro-Glu-Ala-Leu(n) increased with the increase of n = 0 to 1 and 2, but was essentially same with the increase of n = 2 to 3. Then, it was concluded that cucumisin has a S5-S3' subsite length. In order to identify the substrate specificity at P1 position, Leu-Leu-Pro-X-Ala-Leu (X; Gly, Ala, Val, Leu, Ile, Pro, Asp, Glu, Lys, Arg, Asn, Gln, Phe, Tyr, Ser, Thr, Met, Trp, His) were synthesized and digested by cucumisin. Cucumisin showed broad specificity at the P1 position. However, cucumisin did not cleave the C-terminal side of Gly, Ile, Pro, and preferred Leu, Asn, Gln, Thr, and Met, especially Met. Moreover, the substrates, Leu-Leu-Pro-Glu-Y-Leu (Y; Gly, Ala, Ser, Leu, Val, Glu, Lys, Phe) were synthesized and digested by cucumisin. Cucumisin did not cleave the N-terminal side of Val but preferred Gly, Ser, Ala, and Lys especially Ser. The specificity of cucumisin for naturally occurring peptides does not agree strictly with the specificity obtained by synthetic peptides at the P1 or P1' position alone, but it becomes clear that the most of the cleavage sites on naturally occurring peptides by cucumisin contain suitable amino acid residues at P1 and (or) P1' positions. Moreover, cucumisin prefers Pro than Leu at P2 position, indicating that the specificity at P2 position differs from that of papain.     

Directed evolution of Bacillus licheniformis lipase for improvement of thermostability

Lipases catalyze the hydrolysis of carboxylic acid esters and owing to their vast substrate specificity, they have many industrial applications. Due to the demand of thermostable lipases in industrial applications, we have enhanced the thermostability of lipase from Bacillus licheniformis RSP-09. The thermostable mutant lipases of Bacillus licheniformis RSP-09 were isolated following two rounds of directed evolution using error-prone PCR. The best mutant lipases obtained after first and second round of error-prone PCR were purified and characterized. The mutant lipases showed increased thermostability and retained catalytic function. The best mutant lipase (eP-231-51) showed 13.5-fold increase in percentage thermal stability (% remaining activity after incubation of purified enzyme at 60 °C for 1 h) than wild-type lipase. Also, this mutant lipase (ep-231-51) showed 30% improved catalytic efficiency compared with the wild-type which is due to significant decrease in K_m and marginal increase in k_cat. In addition, the thermostable mutant lipases have shown resistance to hydrophobic organic solvents. The role of mutations in the best mutant lipases of second round i.e. eP-231-51 (Asp72Gly, Asp61Gly, Tyr129His, and Thr101Pro) and eP-231-137 (Leu49Arg, Thr101Pro, Asp72Gly), that led to thermostability have been postulated after the comparison of molecular models of wild-type and mutated enzymes.     

Extended substrate specificity of rat mast cell protease 5, a rodent alpha-chymase with elastase-like primary specificity

Chymases are mast cell serine proteases with chymotrypsin-like primary substrate specificity. Amino acid sequence comparisons of alpha-chymases from different species indicated that certain rodent alpha-chymases have a restricted S1 pocket that could only accommodate small amino acids, i.e. they may, despite being classified as chymases, in fact display elastase-like substrate specificity. To explore this possibility, the alpha-chymase, rat mast cell protease 5 (rMCP-5), was produced as a proenzyme with a His6 purification tag and an enterokinase-susceptible peptide replacing the natural propeptide. After removal of the purification tag/enterokinase site by enterokinase digestion, rMCP-5 bound the serine-protease-specific inhibitor diisopropyl fluorophosphate, showing that rMCP-5 was catalytically active. The primary specificity was investigated with chromogenic substrates of the general sequence succinyl-Ala-Ala-Pro-X-p-nitroanilide, where the X was Ile, Val, Ala, Phe or Leu. The activity was highest toward substrates with Val or Ala in the P1 position, whereas low activity toward the peptide with a P1 Phe was observed, indicating that the substrate specificity of rMCP-5 indeed is elastase-like. The extended substrate specificity was examined utilizing a phage-displayed random nonapeptide library. The preferred cleavage sequence was resolved as P4-(Gly/Pro/Val), P3-(Leu/Val/Glu), P2-(Leu/Val/Thr), P1-(Val/Ala/Ile), P1'-(Xaa), and P2'-(Glu/Leu/Asp). Hence, the extended substrate specificity is similar to human chymase in most positions except for the P1 position. We conclude that the rat alpha-chymase has converted to elastase-like substrate specificity, perhaps associated with an adoption of new biological targets, separate from those of human alpha-chymase.     

Even-numbered peptides from a papain hydrolysate of silk fibroin

A protease with broad substrate specificity usually produces a complex peptide mixture. However, even-numbered peptides were obtained at high proportion upon papain hydrolysis of fibroin composed of highly repetitive Ala- and Gly-rich blocks. MALDI-TOF and ESI mass spectrometric analysis revealed that the even-numbered peptides were in the forms of di-, tetra-, hexa-, and octa-peptides with repeating units in combination of Ala–Gly, Ser–Gly, Tyr–Gly, and Val–Gly. Application of tandem mass spectrometry identified the sequences of the tetra-peptides to be in the order of Ala–Gly–X–Gly (X = Tyr or Val). Therefore, the substrate specificity of papain and the unique repetitive sequence of fibroin generated the hydrolysate composed of even number of amino acids at a high percentage. In this work, fibroin hydrolysate was investigated as an example of an end product of protein hydrolysis, which provides a clue to understand the fate of peptides in a protein hydrolysate.     

Isolation and characterization of sialate 9(4)-O-acetylesterase from influenza C virus

An esterase was isolated from influenza C virus with a specific activity from 1.7-5 U/mg protein, and its substrate specificity was tested with various naturally occurring O-acylated sialic acids, synthetic carbohydrate acetates, and other esters. The enzyme hydrolyses only acetic acid esters at significant rates. The non-natural substrates 4-methyl-umbelliferyl acetate, 4-nitrophenyl acetate, and alpha-naphthyl acetate are cleaved at highest hydrolysis rates, followed by the natural substrate N-acetyl-9-O-acetylneuraminic acid. The esterase also acts on N-glycoloyl-9-O-acetylneuraminic acid and, much slower, on N-acetyl-4-O-acetylneuraminic acid; N-acetyl-7-O-acetylneuraminic acid is not hydrolysed. 2-Deoxy-2,3-didehydro-N-acetyl-9-O-acetylneuraminic acid is also a substrate for this enzyme, however, 6-O-acetylated N-acetylmannosamine and glucose are not. Esterification of the carboxyl function of sialic acids strongly reduces or prevents esterase action on O-acetyl groups. The carboxyl ester is not hydrolysed. The relative cleavage rates also depend on the type of the non-sialic acid part of the molecule. N-Acetyl-9-O-acetylneuraminic acid as component of sialyllactose and rat serum glycoprotein shows hydrolysis rates close to the free form of this sugar, while acetyl ester groups of bovine submandibular gland mucin and rat erythrocytes are hydrolysed at slower rates. Gangliosides and 4-O-acetylated glycoproteins are no substrates for the purified enzyme. A slow hydrolysis is observed by incubation of 9-O-acetylated GD1a with intact influenza C viruses. As other natural acetyl esters (acetyl-CoA and acetylthiocholine iodide) are not hydrolysed, the enzyme can be classified as sialate 9(4)-O-acetylesterase (EC 3.1.1.53).     

Systematic exploration of active site mutations on human deoxycytidine kinase substrate specificity

Human deoxycytidine kinase (dCK) is responsible for the phosphorylation of a number of clinically important nucleoside analogue prodrugs in addition to its natural substrates, 2'-deoxycytidine, 2'-deoxyguanosine, and 2'-deoxyadenosine. To improve the low catalytic activity and tailor the substrate specificity of dCK, we have constructed libraries of mutant enzymes and tested them for thymidine kinase (tk) activity. Random mutagenesis was employed to probe for amino acid positions with an impact on substrate specificity throughout the entire enzyme structure, identifying positions Arg104 and Asp133 in the active site as key residues for substrate specificity. Kinetic analysis indicates that Arg104Gln/Asp133Gly creates a "generalist" kinase with broader specificity and elevated turnover for natural and prodrug substrates. In contrast, the substitutions of Arg104Met/Asp133Thr, obtained via site-saturation mutagenesis, yielded a mutant with reversed substrate specificity, elevating the specific constant for thymidine phosphorylation by over 1000-fold while eliminating activity for dC, dA, and dG under physiological conditions. The results illuminate the key contributions of these two amino acid positions to enzyme function by demonstrating their ability to moderate substrate specificity.     

Identification of two imidazole binding sites and key residues for substrate specificity in human primary amine oxidase AOC3

Human membrane primary amine oxidase (hAOC3; also known as vascular adhesion protein-1, VAP-1) is expressed upon inflammation in most tissues, where its enzymatic activity plays a crucial role in leukocyte trafficking. We have determined two new structures of a soluble, proteolytically cleaved form of hAOC3 (sAOC3), which was extracted from human plasma. In the 2.6 ? sAOC3 structure, an imidazole molecule is hydrogen bonded to the topaquinone (TPQ) cofactor, which is in an inactive on-copper conformation, while in the 2.95 ? structure, an imidazole molecule is covalently bound to the active off-copper conformation of TPQ. A second imidazole bound by Tyr394 and Thr212 was identified in the substrate channel. We furthermore demonstrated that imidazole has an inhibitory role at high concentrations used in crystallization. A triple mutant (Met211Val/Tyr394Asn/Leu469Gly) of hAOC3 was previously reported to change substrate preferences toward those of hAOC2, another human copper-containing monoamine oxidase. We now mutated these three residues and Thr212 individually to study their distinct role in the substrate specificity of hAOC3. Using enzyme activity assays, the effect of the four single mutations was tested with four different substrates (methylamine, benzylamine, 2-phenylethylamine, and p-tyramine), and their binding modes were predicted by docking studies. As a result, Met211 and Leu469 were shown to be key residues for substrate specificity. The native structures of sAOC3 and the mutational data presented in this study will aid the design of hAOC3 specific inhibitors.     

Human carbonic anhydrase I: Effect of specific site mutations on its function

Carbonic anhydrase I (CAI) is one out of ten CA isoenzymes that have been identified in humans. X-ray crystallographic and inhibitor complex studies of human carbonic anhydrase I (HCAI) and related studies in other CA isoenzymes identified several residues, in particular Thr199, GlulO6, Tyr7, Glull7, His l07, with likely involvement in the catalytic activity of HCAI. To further study the role of these residues, we undertook, site-directed mutagenesis of HCAI. Using a polymerase chain reaction based strategy and altered oligonucleotide primers, we modified a cloned wild type hCAI gene so as to produce mutant genes encoding proteins with single amino acid substitutions. Thrl99Val, Thrl99Cys, Thr199Ser, GlulO6Ile, Glul06Gln, Tyr7Trp, Glu.117Gln, and His 107Val mutations were thus generated and the activity of each measured by ester hydrolysis. Overproduction of the Glu117Gln and HisI07Val mutant proteins inEscherichia coli resulted in a large proportion of the enzyme forming aggregates probably due to folding defect. The mutations Thr199Val, GlulO6Ile and GlulO6Gln gave soluble protein with drastically reduced enzyme activity, while the Tyr7Trp mutation had only marginal effect on the activity, thus s.uggesting important roles for Thr199 and Glu lO6 but not for Tyr7 in the catalytic function of HCAI.     

Mutant subtilisin E with enhanced protease activity obtained by site-directed mutagenesis

The specific activity of subtilisin E, an alkaline serine protease of Bacillus subtilis, was substantially increased by optimizing the amino acid residue at position 31 (Ile in the wild-type enzyme) in the vicinity of the catalytic triad of the enzyme. Eight uncharged amino acids (Cys, Ser, Thr, Gly, Ala, Val, Leu, and Phe) were introduced at this site, which is next to catalytic Asp32, using site-directed mutagenesis. Mutant enzymes were expressed in Escherichia coli and were prepared from the periplasmic space. Only the Val and Leu substitutions gave active enzyme, and the Leu31 mutant was found to have a greatly increased activity compared to the wild-type enzyme. The other six mutant enzymes showed a marked decrease in activity. This result indicates that a branched-chain amino acid at position 31 is essential for the expression of subtilisin activity and that the level of the activity depends on side chain structure. The purified Leu31 mutant enzyme was analyzed with respect to substrate specificity, heat stability, and optimal temperature. It was found that the Leu31 replacement caused a prominent 2-6-fold increase in catalytic efficiency (kcat/Km) due to a larger kcat for peptide substrates.     

Engineering of papain: selective alteration of substrate specificity by site-directed mutagenesis

The S2 subsite specificity of the plant protease papain has been altered to resemble that of mammalian cathepsin B by site-directed mutagenesis. On the basis of amino acid sequence alignments for papain and cathepsin B, a double mutant (Val133Ala/Ser205Glu) was produced where Val133 and Ser205 are replaced by Ala and Glu, respectively, as well as a triple mutant (Val133Ala/Val157Gly/Ser205Glu), where Val157 is also replaced by Gly. Three synthetic substrates were used for the kinetic characterization of the mutants, as well as wild-type papain and cathepsin B: CBZ-Phe-Arg-MCA, CBZ-Arg-Arg-MCA, and CBZ-Cit-Arg-MCA. The ratio of kcat/KM obtained by using CBZ-Phe-Arg-MCA as substrate over that obtained with CBZ-Arg-Arg-MCA is 8.0 for the Val133Ala/Ser205Glu variant, while the equivalent values for wild-type papain and cathepsin B are 904 and 3.6, respectively. This change in specificity has been achieved by replacing only two amino acids out of a total of 212 in papain and with little loss in overall enzyme activity. However, further replacement of Val157 by Gly as in Val133Ala/Val157Gly/Ser205Glu causes an important decrease in activity, although the enzyme still displays a cathepsin B like substrate specificity. In addition, the pH dependence of activity for the Val133Ala/Ser205Glu variant compares well with that of cathepsin B. In particular, the activity toward CBZ-Arg-Arg-MCA is modulated by a group with a pKa of 5.51, a behavior that is also encountered in the case of cathepsin B but is absent with papain.(ABSTRACT TRUNCATED AT 250 WORDS)     

The modeling of interactions of the CYP2E1 isoform of human cytochrome P450 with substrates

The interactions between the substrates of the 2E1 isoform of the human cytochrome P450 and receptor were simulated. It was found that the CP4 isoform of the cytochrome of the bacterial cell is highly homologous to the 2E1 isoform of the human cytochrome P450. The orientation of the substrates of the 2E1 isoform in the CP4 isoform of the bacterial cell cytochrome was performed. A cavity in the receptor was found that is responsible for the binding of the substrate. Amino acid residues Phe87, Pro89, Val119, Thr185, Leu244, Leu245, Leu246, Val247, Gly248, Gly249, Thr252, Val295, Asp297, Cys357, Ile395, and Val396, the heme, and water molecules are involved in the formation of the cavity. The mode of the interactions of the substrate molecule with cytochrome was analyzed. Active sites of the receptor, and a part of the substrate molecule responsible for the binding to cytochrome were found. Equations for the dependence of the Michaelis constant on the structural parameters of complexes of substrates with cytochrome were derived.     

Substitutions of Glycine Residues Gly100 and Gly147 in Conservative Loops Decrease Rates of Conformational Rearrangements of <Emphasis Type="Italic">Escherichia coli</Emphasis> Inorganic Pyrophosphatase

Escherichia coli inorganic pyrophosphatase (PPase) is a one-domain globular enzyme characterized by its ability to easily undergo minor structure rearrangements involving flexible segments of the polypeptide chain. To elucidate a possible role of these segments in catalysis, catalytic properties of mutant variants of E. coli PPase Gly100Ala and Gly147Val with substitutions in the conservative loops II and III have been studied. The main result of the mutations was a sharp decrease in the rates of conformational changes required for binding of activating Mg2+ ions, whereas affinity of the enzyme for Mg2+ was not affected. The pH-independent parameters of MgPP(i) hydrolysis, kcat and kcat/Km, have been determined for the mutant PPases. The values of kcat for Gly100Ala and Gly147Val variants were 4 and 25%, respectively, of the value for the native enzyme. Parameter kcat/Km for both mutants was two orders of magnitude lower. Mutation Gly147Val increased pH-independent Km value about tenfold. The study of synthesis of pyrophosphate in the active sites of the mutant PPases has shown that the maximal level of synthesized pyrophosphate was in the case of Gly100Ala twofold, and in the case of Gly147Val fivefold, higher than for the native enzyme. The results reported in this paper demonstrate that the flexibility of the loops where the residues Gly100 and Gly147 are located is necessary at the stages of substrate binding and product release. In the case of Gly100Ala PPase, significant impairment of affinity of enzyme effector site for PP(i) was also found.