Rational evolution of a medium chain-specific cytochrome P-450 BM-3 variant

The single mutant F87A of cytochrome P-450 BM-3 from Bacillus megaterium was engineered by rational evolution to achieve improved hydroxylation activity for medium chain length substrates (C8-C10). Rational evolution combines rational design and directed evolution to overcome the drawbacks of these methods when applied individually. Based on the X-ray structure of the enzyme, eight mutation sites (P25, V26, R47, Y51, S72, A74, L188, and M354) were identified by modeling. Sublibraries created by site-specific randomization mutagenesis of each single site were screened using a spectroscopic assay based on omega-p-nitrophenoxycarboxylic acids (pNCA). The mutants showing activity for shorter chain length substrates were combined, and these combi-libraries were screened again for mutants with even better catalytic properties. Using this approach, a P-450 BM-3 variant with five mutations (V26T, R47F, A74G, L188K, and F87A) that efficiently hydrolyzes 8-pNCA was obtained. The catalytic efficiency of this mutant towards omega-p-nitrophenoxydecanoic acid (10-pNCA) and omega-p-nitrophenoxydodecanoic acid (12-pNCA) is comparable to that of the wild-type P-450 BM-3.     

Key residues for controlling enantioselectivity of Halohydrin dehalogenase from Arthrobacter sp. strain AD2, revealed by structure-guided directed evolution

Halohydrin dehalogenase from Agrobacterium radiobacter AD1 (HheC) is a valuable tool in the preparation of R enantiomers of epoxides and β-substituted alcohols. In contrast, the halohydrin dehalogenase from Arthrobacter sp. AD2 (HheA) shows a low S enantioselectivity toward most aromatic substrates. Here, three amino acids (V136, L141, and N178) located in the two neighboring active-site loops of HheA were proposed to be the key residues for controlling enantioselectivity. They were subjected to saturation mutagenesis aimed at evolving an S-selective enzyme. This led to the selection of two outstanding mutants (the V136Y/L141G and N178A mutants). The double mutant displayed an inverted enantioselectivity (from S enantioselectivity [E(S)] = 1.7 to R enantioselectivity [E(R)] = 13) toward 2-chloro-1-phenylethanol without compromising enzyme activity. Strikingly, the N178A mutant showed a large enantioselectivity improvement (E(S) > 200) and a 5- to 6-fold-enhanced specific activity toward (S)-2-chloro-1-phenylethanol. Further analysis revealed that those mutations produced some interference for the binding of nonfavored enantiomers which could account for the observed enantioselectivities. Our work demonstrated that those three active-site residues are indeed crucial in modulating the enantioselectivity of HheA and that a semirational design strategy has great potential for rapid creation of novel industrial biocatalysts.     

Directed evolution of Thermus maltogenic amylase toward enhanced thermal resistance

The thermostability of maltogenic amylase from Thermus sp. strain IM6501 (ThMA) was improved greatly by random mutagenesis using DNA shuffling. Four rounds of DNA shuffling and subsequent recombination of the mutations produced the highly thermostable mutant enzyme ThMA-DM, which had a total of seven individual mutations. The seven amino acid substitutions in ThMA-DM were identified as R26Q, S169N, I333V, M375T, A398V, Q411L, and P453L. The optimal reaction temperature of the recombinant enzyme was 75 degrees C, which was 15 degrees C higher than that of wild-type ThMA, and the melting temperature, as determined by differential scanning calorimetry, was increased by 10.9 degrees C. The half-life of ThMA-DM was 172 min at 80 degrees C, a temperature at which wild-type ThMA was completely inactivated in less than 1 min. Six mutations that were generated during the evolutionary process did not significantly affect the specific activity of the enzyme, while the M375T mutation decreased activity to 23% of the wild-type level. The molecular interactions of the seven mutant residues that contributed to the increased thermostability of the mutant enzyme with other adjacent residues were examined by comparing the modeled tertiary structure of ThMA-DM with those of wild-type ThMA and related enzymes. The A398V and Q411L substitutions appeared to stabilize the enzyme by enhancing the interdomain hydrophobic interactions. The R26Q and P453L substitutions led potentially to the formation of genuine hydrogen bonds. M375T, which was located near the active site of ThMA, probably caused a conformational or dynamic change that enhanced thermostability but reduced the specific activity of the enzyme.     

Cloning of an epoxide hydrolase-encoding gene from Aspergillus niger M200, overexpression in E. coli, and modification of activity and enantioselectivity of the enzyme by protein engineering

The gene encoding an epoxide hydrolase from Aspergillus niger M200 has been cloned and its sequence determined. The gene is interrupted by seven introns, one exon being only nine nucleotides long. The non-coding 5'- and 3'-regions of the mRNA are composed of 47 and 76 nucleotides, respectively. Overexpression of the fungal epoxide hydrolase in E. coli TOP10 has led to a 15-fold increase in specific activity (compared to the wild-type strain). Saturation mutagenesis at codon 217 resulted in the discovery of nine enzyme variants showing in several cases profound differences in activity and enantioselectivity towards various epoxides when compared to the data of the wild-type enzyme. The site 217 is located at the entrance of the tunnel that provides the substrate with access to the active site. The exchange of Ala at this position for Cys has led to a doubled enantioselectivity (E-value of 5.0) towards benzyl glycidyl ether. The same substitution resulted in a threefold-enhanced activity of the enzyme towards allyl glycidyl ether and styrene oxide without affecting enantioselectivity. The variant A217L showed an enhanced enantioselectivity towards tert-butyl glycidyl ether reaching an E-value of 100 (from 60 for the wild-type enzyme). Replacement of A217 by Val has led to higher activity towards allyl glycidyl ether by a factor of six. The substitutions Ala-->Glu and Ala-->Gln increased the enantioselectivity towards allyl glycidyl ether and styrene oxide by over 50% to E-values of 10 and 16, respectively. The study underlines that single amino acid exchanges in the substrate tunnel region can lead to significant improvements in enantioselectivity and activity of the epoxide hydrolase from A. niger M200.     

Important amino acid residues of hexachlorocyclohexane dehydrochlorinases (LinA) for enantioselective transformation of hexachlorocyclohexane isomers

LinA-type1 and LinA-type2 are two well-characterized variants of the enzyme ‘hexachlorocyclohexane (HCH)-dehydrochlorinase’. They differ from each other at ten amino acid positions and exhibit differing enantioselectivity for the transformation of the (–) and (+) enantiomers of α-HCH. Amino acids responsible for this enantioselectivity, however, are not known. An in silico docking analysis identified four amino acids (K20, L96, A131, and T133) in LinA-type1 that could be involved in selective binding of the substrates. Experimental studies with constructed mutant enzymes revealed that a combined presence of three amino acid changes in LinA-type1, i.e. K20Q, L96C, and A131G, caused a reversal in its preference from the (–) to the (+) enantiomer of α-HCH. This preference was enhanced by the additional amino acid change T133 M. Presence of these four changes also caused the reversal of enantioselectivity of LinA-type1 for δ-HCH, and β-, γ-, and δ-pentachlorocyclohexens. Thus, the residues K20, L96, A131, and T133 in LinA-type1 and the residues Q20, C96, G131, and M133 in LinA-type 2 appear to be important determinants for the enantioselectivity of LinA enzymes.     

Improving the carboligase activity of benzoylformate decarboxylase from Pseudomonas putida by a combination of directed evolution and site-directed mutagenesis

Benzoylformate decarboxylase (BFD) from Pseudomonas putida was subjected to directed molecular evolution to generate mutants with increased carboligase activity which is a side reaction of the enzyme. After a single round of random mutagenesis mutants were isolated which exhibited a 5-fold increased carboligase activity in aqueous buffer compared to the wild-type enzyme with a high enantiomeric excess of the product (S)-2-hydroxy-1-phenyl-propanone. From the same library, mutants with enhanced carboligase activity in water-miscible organic solvents have been isolated. The selected mutants have been characterized by sequencing, revealing that all mutants carry a mutation at Leu476, which is close to the active site but does not directly interact with the active center. BFD-L476Q has a 5-fold higher carboligase activity than the wild-type enzyme. L476 was subjected to saturation mutagenesis yielding eight different mutants with up to 5-fold increased carboligase activity. Surprisingly, all L476 mutants catalyze the formation of 2-hydroxy-1-phenyl-propanone with significantly higher enantioselectivity than the wild-type enzyme although enantioselectivity was not a selection parameter. Leu476 potentially plays the role of a gatekeeper of the active site of BFD, possibly by controlling the release of the product. The biocatalyst could be significantly improved for its side reaction, the C-C bond formation and for application under conditions that are not optimized in nature.     

R-2-卤代酸脱卤酶的同源模建及底物对映体选择性研究

对来自假单胞菌ZJU26中的R-2-卤代酸脱卤酶(DehI-R)进行同源模建,分析其与底物的相互作用,为解析酶的底物对映体选择性提供理论依据.采用Sybyl中的APM模块首次构建并优化了R-2-卤代酸脱卤酶的三维结构,并用Procheck 验证结构模型的合理性.使用Suflex-Docking模块将结构模型与底物分别进行对接,分析相互之间的作用.序列比对结果显示,R-2-卤代酸脱卤酶与恶臭假单胞菌PP3中DehI的相似性达23.71％.Deh-R模建后的结构与模板很好的吻合.模型比对分析DehI-R中参与催化的残基,除Asn2.03外大部分都比较保守.分子对接结果表明,R-2-氯丙酸和S-2-氯丙酸都可以结合到活性位点上,决定其选择性的是值点Asn203,在RS-2-卤代酸脱卤酶所对应位点的残基为Ala,相比之下,Aan具备较大的空间位阻,从而阻止了S-2-氯丙酸的反应.利用Sybyl中的Biopolymer模块对R-2-卤代酸脱卤酶中的Asn203突变成具有不同空间位阻的Ala、Gly和Gln.突变酶与底物对接结果进一步证实了Asn203位点对R-2-卤代酸脱卤酶的底物对映体选择性作用.     

Protein engineering of epoxide hydrolase from Agrobacterium radiobacter AD1 for enhanced activity and enantioselective production of (R)-1-phenylethane-1,2-diol

DNA shuffling and saturation mutagenesis of positions F108, L190, I219, D235, and C248 were used to generate variants of the epoxide hydrolase of Agrobacterium radiobacter AD1 (EchA) with enhanced enantioselectivity and activity for styrene oxide and enhanced activity for 1,2-epoxyhexane and epoxypropane. EchA variant I219F has more than fivefold-enhanced enantioselectivity toward racemic styrene oxide, with the enantiomeric ratio value (E value) for the production of (R)-1-phenylethane-1,2-diol increased from 17 for the wild-type enzyme to 91, as well as twofold-improved activity for the production of (R)-1-phenylethane-1,2-diol (1.96 +/- 0.09 versus 1.04 +/- 0.07 micromol/min/mg for wild-type EchA). Computer modeling indicated that this mutation significantly alters (R)-styrene oxide binding in the active site. Another three variants from EchA active-site engineering, F108L/C248I, I219L/C248I, and F108L/I219L/C248I, also exhibited improved enantioselectivity toward racemic styrene oxide in favor of production of the corresponding diol in the (R) configuration (twofold enhancement in their E values). Variant F108L/I219L/C248I also demonstrated 10-fold- and 2-fold-increased activity on 5 mM epoxypropane (24 +/- 2 versus 2.4 +/- 0.3 micromol/min/mg for the wild-type enzyme) and 5 mM 1,2-epoxyhexane (5.2 +/- 0.5 versus 2.6 +/- 0.0 micromol/min/mg for the wild-type enzyme). Both variants L190F (isolated from a DNA shuffling library) and L190Y (created from subsequent saturation mutagenesis) showed significantly enhanced activity for racemic styrene oxide hydrolysis, with 4.8-fold (8.6 +/- 0.3 versus 1.8 +/- 0.2 micromol/min/mg for the wild-type enzyme) and 2.7-fold (4.8 +/- 0.8 versus 1.8 +/- 0.2 micromol/min/mg for the wild-type enzyme) improvements, respectively. L190Y also hydrolyzed 1,2-epoxyhexane 2.5 times faster than the wild-type enzyme.     

A Focal Epilepsy and Intellectual Disability Syndrome Is Due to a Mutation in TBC1D24

We characterized an autosomal-recessive syndrome of focal epilepsy, dysarthria, and mild to moderate intellectual disability in a consanguineous Arab-Israeli family associated with subtle cortical thickening. We used multipoint linkage analysis to map the causative mutation to a 3.2 Mb interval within 16p13.3 with a LOD score of 3.86. The linked interval contained 160 genes, many of which were considered to be plausible candidates to harbor the disease-causing mutation. To interrogate the interval in an efficient and unbiased manner, we used targeted sequence enrichment and massively parallel sequencing. By prioritizing unique variants that affected protein translation, a pathogenic mutation was identified in TBC1D24 (p.F251L), a gene of unknown function. It is a member of a large gene family encoding TBC domain proteins with predicted function as Rab GTPase activators. We show that TBC1D24 is expressed early in mouse brain and that TBC1D24 protein is a potent modulator of primary axonal arborization and specification in neuronal cells, consistent with the phenotypic abnormality described.     

Directed Evolution of Thermus Maltogenic Amylase toward Enhanced Thermal Resistance

The thermostability of maltogenic amylase from Thermus sp. strain IM6501 (ThMA) was improved greatly by random mutagenesis using DNA shuffling. Four rounds of DNA shuffling and subsequent recombination of the mutations produced the highly thermostable mutant enzyme ThMA-DM, which had a total of seven individual mutations. The seven amino acid substitutions in ThMA-DM were identified as R26Q, S169N, I333V, M375T, A398V, Q411L, and P453L. The optimal reaction temperature of the recombinant enzyme was 75°C, which was 15°C higher than that of wild-type ThMA, and the melting temperature, as determined by differential scanning calorimetry, was increased by 10.9°C. The half-life of ThMA-DM was 172 min at 80°C, a temperature at which wild-type ThMA was completely inactivated in less than 1 min. Six mutations that were generated during the evolutionary process did not significantly affect the specific activity of the enzyme, while the M375T mutation decreased activity to 23% of the wild-type level. The molecular interactions of the seven mutant residues that contributed to the increased thermostability of the mutant enzyme with other adjacent residues were examined by comparing the modeled tertiary structure of ThMA-DM with those of wild-type ThMA and related enzymes. The A398V and Q411L substitutions appeared to stabilize the enzyme by enhancing the interdomain hydrophobic interactions. The R26Q and P453L substitutions led potentially to the formation of genuine hydrogen bonds. M375T, which was located near the active site of ThMA, probably caused a conformational or dynamic change that enhanced thermostability but reduced the specific activity of the enzyme.     

Rationally engineered double substituted variants of Yarrowia lipolytica lipase with enhanced activity coupled with highly inverted enantioselectivity towards 2‐bromo phenyl acetic acid esters

Inverting enzyme enantioselectivity by protein engineering is still a great challenge. Lip2p lipase from Yarrowia lipolytica, which demonstrates a low S‐enantioselectivity (E‐value = 5) during the hydrolytic kinetic resolution of 2‐bromo‐phenyl acetic acid octyl esters (an important class of chemical intermediates in the pharmaceutical industry), was converted, by a rational engineering approach, into a totally R‐selective enzyme (E‐value > 200). This tremendous change in selectivity is the result of only two amino acid changes. The starting point of our strategy was the prior identification of two key positions, 97 and 232, for enantiomer discrimination. Four single substitution variants were recently identified as exhibiting a low inversion of selectivity coupled to a low‐hydrolytic activity. On the basis of these results, six double substituted variants, combining relevant mutations at both 97 and 232 positions, were constructed by site‐directed mutagenesis. This work led to the isolation of one double substituted variant (D97A‐V232F), which displays a total preference for the R‐enantiomer. The highly reversed enantioselectivity of this variant is accompanied by a 4.5‐fold enhancement of its activity toward the preferred enantiomer. The molecular docking of the R‐ and S‐enantiomers in the wild‐type enzyme and the D97A‐V232F variant suggests that V232F mutation provides a more favorable stacking interaction for the phenyl group of the R‐enantiomer, that could explain both the enhanced activity and the reversal of enantioselectivity. These results demonstrate the potential of rationally engineered mutations to further enhance enzyme activity and to modulate selectivity. Biotechnol. Bioeng. 2010;106: 852–859. © 2010 Wiley Periodicals, Inc.     

Inverting enantioselectivity of Burkholderia gladioli esterase EstB by directed and designed evolution

Esterase EstB from Burkholderia gladioli, showing moderate S-enantioselectivity (E(S)=6.1) in the hydrolytic kinetic resolution of methyl-beta-hydroxyisobutyrate, was subjected to directed evolution in order to reverse its enantioselectivity. After one round of ep-PCR, saturation mutagenesis and high-throughput screening, it was found that different mutations at position 152 (in the vicinity of the active site) increase, decrease and even reverse the natural enantioselectivity of this enzyme. The newly created R-enantioselectivity of the esterase mutein (E(Rapp)=1.5) has been further enhanced by a designed evolution strategy involving random mutations close to the active site. Based on the three-dimensional structure nineteen amino acid residues have been selected as mutation sites for saturation mutagenesis. Mutations at three sites (135, 253 and 351) were found to increase R-enantioselectivity. Successive rounds of saturation mutagenesis at these "hot spots" resulted in an increase in R-enantioselectivity from E(Rapp)=1.5 for the parent mutant to E(Rapp)=28.9 for the best variant which carried four amino acid substitutions. Our results prove designed evolution followed by high-throughput screening to be an efficient strategy for engineering enzyme enantioselectivity.     

Asymmetric transesterification of secondary alcohols catalyzed by feruloyl esterase from Humicola insolens

A new asymmetric transesterification of secondary alcohols catalyzed by feruloyl esterase from Humicola insolens has been found. Although alcohols are not the natural substrates for this enzyme, a high R enantioselectivity was observed. Stereochemical studies showed that variations in substrate structure lead to strong variations in enantioselectivity. The highest enantioselectivities are obtained when the beta-carbon of the secondary alcohol is tertiary or quaternary.     

Structural studies on human glutathione S-transferase pi. Substitution mutations to determine amino acids necessary for binding glutathione.

In order to identify amino acids involved in binding the co-substrate glutathione to the human glutathione S-transferase (GST) pi enzyme, we assembled three criteria to implicate amino acids whose role in binding and catalysis could be tested. Presence of a residue in the highly conserved exon 4 of the GST gene, positional conservation of a residue in 12 glutathione S-transferase amino acid sequences, and results from published chemical modification studies were used to implicate 14 residues. A bacterial expression vector (pUC120 pi), which enabled abundant production (2-26% of soluble Escherichia coli protein) of wild-type or mutant GST pi, was constructed, and, following nonconservative substitution mutation of the 14 implicated residues, five mutants (R13S, D57K, Q64R, I68Y, L72F) showed a greater than 95% decrease in specific activity. A quantitative assay was developed which rapidly measured the ability of wild-type or mutant glutathione S-transferase to bind to glutathione-agarose. Using this assay, each of the five loss of function mutants showed a greater than 20-fold decrease in binding glutathione, an observation consistent with a recent crystal structure analysis showing that several of these residues help to form the glutathione-binding cleft.     

Development of intramolecularly quenched fluorescent peptides as substrates of angiotensin-converting enzyme 2

Angiotensin-converting enzyme 2 (ACE2 or ACEH) is a novel angiotensin-converting enzyme-related carboxypeptidase that cleaves a single amino acid from angiotensin I, des-Arg bradykinin, and many other bioactive peptides. Using des-Arg bradykinin as a template, we designed a series of intramolecularly quenched fluorogenic peptide substrates for ACE2. The general structure of the substrates was F-X-Q, in which F was the fluorescent group, Abz, Q was the quenching group (either Phe(NO(2)) or Tyr(NO(2))), and X was the intervening peptide. These substrates were selectively cleaved by recombinant human ACE2, as shown by MS and HPLC. Quenching efficiency increased as the peptide sequence was shortened from 8 to 3 aa, and also when Tyr(NO(2)) was used as a quenching group instead of Phe(NO(2)). Two of the optimized substrates, TBC5180 and TBC5182, produced a signal:noise ratio of better than 20 when hydrolyzed by ACE2. Kinetic measurements with ACE2 were as follows: TBC5180, K(m)=58 microM and k(cat)/K(m)=1.3x10(5)M(-1)s(-1); TBC5182, K(m)=23 microM and k(cat)/K(m)=3.5 x 10(4)M(-1)s(-1). Thus, based on hydrolysis rate, TBC5180 was a better substrate than TBC5182. However, TBC5180 was also hydrolyzed by ACE, whereas TBC5182 was not cleaved, suggesting that TBC5182 was a selective for ACE2. We conclude that these two peptides can be used as fluorescent substrates for high-throughput screening for selective inhibitors of ACE2 enzyme.     

A missense mutation (L166P) in DJ-1, linked to familial Parkinson's disease, confers reduced protein stability and impairs homo-oligomerization

The identification of genetic mutations responsible for rare familial forms of Parkinson's disease (PD) have provided tremendous insight into the molecular pathogenesis of this disorder. Mutations in the DJ-1 gene cause autosomal recessive early onset PD in two European families. A Dutch kindred displays a large homozygous genomic deletion encompassing exons 1-5 of the DJ-1 gene, whereas an Italian kindred harbors a single homozygous L166P missense mutation. A homozygous M26I missense mutation was also recently reported in an Ashkenazi Jewish patient with early onset PD. Mutations in DJ-1 are predicted to be loss of function. The recent determination of the crystal structure of human DJ-1 demonstrates that it exists in a homo-dimeric form in vitro, whereas the L166P mutant exists only as a monomer. Here, we examine the in vivo effects of the pathogenic L166P and M26I mutations on the properties of DJ-1 in cell culture. We report that the L166P mutation confers markedly reduced protein stability to DJ-1, which results from enhanced degradation by the 20S/26S proteasome but not from a loss of mRNA expression. Furthermore, the L166P mutant protein exhibits an impaired ability to self-interact to form homo-oligomers. In contrast, the M26I mutation does not appear to adversely affect either protein stability, turnover by the proteasome, or the capacity of DJ-1 to form homo-oligomers. These properties of the L166P mutation may contribute to the loss of normal DJ-1 function and are likely to be the underlying cause of early onset PD in affected members of the Italian kindred.     

Facile modulation of enantioselectivity of thermophilic Geobacillus zalihae lipase by regulating hydrophobicity of its Q114 oxyanion

Site-directed mutagenesis of the oxyanion-containing amino acid Q114 in the recombinant thermophilic T1 lipase previously isolated from Geobacillus zalihae was performed to elucidate its role in the enzyme⿿s enantioselectivity and reactivity. Substitution of Q114 with a hydrophobic methionine to yield mutant Q114M increased enantioselectivity (3.2-fold) and marginally improved reactivity (1.4-fold) of the lipase in catalysing esterification of ibuprofen with oleyl alcohol. The improved catalytic efficiency of Q114L was concomitant with reduced flexibility in the active site while the decreased enantioselectivity of Q114L could be directly attributed to diminished electrostatic repulsion of the substrate carboxylate ion that rendered partial loss in steric hindrance and thus enantioselectivity. The highest E-values for both Q114L (E-value 14.6) and Q114M (E-value 48.5) mutant lipases were attained at 50 °C, after 12⿿16 h, with a molar ratio of oleyl alcohol to ibuprofen of 1.5:1 and at 2.0% (w/v) enzyme load without addition of molecular sieves. Pertinently, site-directed mutagenesis on the Q114 oxyanion of T1 resulted in improved enantioselectivity and such approach may be applicable to other lipases of the same family. We demonstrated that electrostatic repulsion phenomena could affect flexibility/rigidity of the enzyme-substrate complex, aspects vital for enzyme activity and enantioselectivity of T1.     

Variations in the enantioselectivity of salt-activated subtilisin induced by lyophilization

Including excess salt during lyophilization has been shown to increase the activity of freeze-dried subtilisin Carlsberg (SC) in anhydrous media by over 20,000-fold [Ru et al. (1999) Biotechnol Bioeng 63:233-241]. In the present study, salt-activated SC (KCl-SC) showed a 30% enhancement in enantioselectivity compared to the salt-free enzyme in a variety of organic solvents. Activity toward both enantiomers of N-acetyl-phenylalanine methyl ester (APME) increased in tandem by 2-3 orders of magnitude in all solvents, indicating that the mechanism of salt activation is inherent to the enzyme and does not strongly favor one enantiomer over the other. However, activity and enantioselectivity of salt-activated SC could be manipulated through changes in the lyophilization conditions. Variations in lyophilization time, initial KCl concentration, and initial lyophilization volume altered enantioselectivity over 2-fold. The changes in enantioselectivity reflected the activity for the L enantiomer, while the activity toward the D enantiomer was mostly unaffected. The results indicate that the lyophilization time and final water content of the KCl-SC are important determinants of enzyme activity for the L enantiomer, suggesting that the favored reaction is more sensitive to the structural integrity of the salt-activated enzyme.     

Stereoselectivity and conformational stability of haloalkane dehalogenase DbjA from Bradyrhizobium japonicum USDA110: the effect of pH and temperature

The effect of pH and temperature on structure, stability, activity and enantioselectivity of haloalkane dehalogenase DbjA from Bradyrhizobium japonicum USDA110 was investigated in this study. Conformational changes have been assessed by circular dichroism spectroscopy, functional changes by kinetic analysis, while quaternary structure was studied by gel filtration chromatography. Our study shows that the DbjA enzyme is highly tolerant to pH changes. Its secondary and tertiary structure was not affected by pH in the ranges 5.3-10.3 and 6.2-10.1, respectively. Oligomerization of DbjA was strongly pH-dependent: monomer, dimer, tetramer and a high molecular weight cluster of the enzyme were distinguished in solution at different pH conditions. Moreover, different oligomeric states of DbjA possessed different thermal stabilities. The highest melting temperature (T(m) = 49.1 ± 0.2 °C) was observed at pH 6.5, at which the enzyme occurs in dimeric form. Maximal activity was detected at 50 °C and in the pH interval 7.7-10.4. While pH did not have any effect on enantiodiscriminination of DbjA, temperature significantly altered DbjA enantioselectivity. A decrease in temperature results in significantly enhanced enantioselectivity. The temperature dependence of DbjA enantioselectivity was analysed with 2-bromobutane, 2-bromopentane, methyl 2-bromopropionate and ethyl 2-bromobutyrate, and differential activation parameters Δ(R-S)ΔH and Δ(R-S)ΔS were determined. The thermodynamic analysis revealed that the resolution of β-bromoalkanes was driven by both enthalpic and entropic terms, while the resolution of α-bromoesters was driven mainly by an enthalpic term. Unique catalytic activity and structural stability of DbjA in a broad pH range, combined with high enantioselectivity with particular substrates, make this enzyme a very versatile biocatalyst. Enzyme EC3.8.1.5 haloalkane dehalogenase.