Effect on thermostability and catalytic activity of introducing disulfide bonds into Aspergillus awamori glucoamylase

Two additional disulfide bonds and three combined thermostabilizing mutations were introduced into Aspergillus awamori glucoamylase to test their effects on enzyme thermostability and catalytic properties. The single cysteine mutations N20C, A27C, T72C and A471C were made and combined to produce the double cysteine mutations N20C/ A27C and T72C/A471C. The double cysteine mutants were expressed efficiently in Saccharomyces cerevisiae, and disulfide bonds formed spontaneously after fermentation. At 50 degrees C, the single mutants N20C and A27C had decreased specific activity, whereas the specific activity of the double mutants N20C/A27C and T72C/A471C were similar to wild-type glucoamylase. The N20C/A27C mutation increased thermostability, with an increased activation free energy of 1.5 kJ/mol at 65 degrees C, while the single mutation A27C only slightly increased thermostability and N20C decreased it. The other disulfide bond-forming mutation T72C/A471C did not affect thermostability at pH 4.5. The N20C/A27C mutation was separately combined with two other thermostabilizing mutations, G137A and S436P. Thermostabilities of all of the combined mutated glucoamylases were additive. N20C/A27C/G137A glucoamylase had higher specific activity than wild-type glucoamylase from 45 to 67.5 degrees C. The disulfide bond between positions 20 and 27 connects the C- terminus of helix 1 and the following beta-turn, suggesting that this region is important for glucoamylase thermostability.      

Regulation of trypsin activity by Cu2+ chelation of the substrate binding site

Lysine 188 of trypsin was replaced with histidine in order to create a metal chelation site in the substrate binding pocket of this protease, built in a metal binding 'switch,' and to be able to modulate its activity at lower pH. The catalytic properties of wild-type and mutant trypsin were measured with tetrapeptide substrates containing a nitroanilide leaving group and whole native protein substrate: beta- casein. The results obtained reveal that K188H mutation does not affect catalytic efficiency, raising only slightly (from 6 to 8) the arginine/lysine preference of the mutant and increasing 1.8- and 1.2- fold the second-order rate constant k(cat)/Km for arginine- and lysine- containing substrates, respectively. Compared with wild-type trypsin, K188H mutant shows, in the absence of Cu2+, a different catalytic activity pattern as a function of pH. The addition of Cu2+ to trypsin K188H induces a 30-100-fold increase in Km, while k(cat) is scarcely decreased. The hydrolytic activity of this mutant can be fully restored by addition of EDTA. In contrast to a chelating active site, a novel mode of metal-dependent inhibition activity of trypsin with copper is presented. As suggested by molecular modelling studies, the substrate binding pocket of the protease is considerably perturbed by vicinal chelation. More generally, this type of transition metal chelate may present wider possibilities of trypsin activity and specificity modulation than the previously accomplished chelation of a histidine moiety from a catalytic triad.      

Concurrent mutations in six amino acids in beta-glucuronidase improve its thermostability

To achieve a thermostable beta-glucuronidase (GUS) and identify key mutation sites, we applied in vitro directed evolution strategy through DNA shuffling and obtained a highly thermostable mutant GUS gene, gus-tr, after four rounds of DNA shuffling and screening. This variant had mutations in 15 nucleic acid sites, resulting in changes in 12 amino acids (AAs). Using gus-tr as the template, we further performed site-directed mutagenesis to reverse the individual mutation to the wild-type protein. We found that six sites (Q493R, T509A, M532T, N550S, G559S and N566S) present in GUS-TR3337, were the key AAs needed to confer its high thermostability. Of these, Q493R and T509A were not reported previously as important residues for thermostability of GUS. Furthermore, all of these six mutations must be present concurrently to confer the high thermostability. We expressed the gus-tr3337 gene and purified the GUS-TR3337 protein that contained the six AA mutations. Compared with the wild-type protein which lost its activity completely after 10 min at 70 degrees C, the mutant GUS-TR3337 protein retained 75% of its activity when heated at 80 degrees C for 10 min. The GUS-TR3337 exhibited high activity even heated at 100 degrees C for 30 min on nitrocellulose filter. The comparison of molecular models of the mutated and wild-type enzyme revealed the relation of protein function and these structural modifications.     

Directed evolution on the cold adapted properties of TAB5 alkaline phosphatase

Psychrophilic alkaline phosphatase (AP) from the Antarctic strain TAB5 was subjected to directed evolution in order to identify the key residues steering the enzyme's cold-adapted activity and stability. A round of random mutagenesis and further recombination yielded three thermostable and six thermolabile variants of the TAB5 AP. All of the isolated variants were characterised by their residual activity after heat treatment, Michaelis-Menten kinetics, activation energy and microcalorimetric parameters of unfolding. In addition, they were modelled into the structure of the TAB5 AP. Mutations which affected the cold-adapted properties of the enzyme were all located close to the active site. The destabilised variants H135E and H135E/G149D had 2- and 3-fold higher kcat, respectively, than the wild-type enzyme. Wild-type AP has a complex heat-induced unfolding pattern while the mutated enzymes loose local unfolding transitions and have large shifts of the Tm values. Comparison of the wild-type and mutated TAB5 APs demonstrates that there is a delicate balance between the enzyme activity and stability and that it is possible to improve the activity and thermostability simultaneously as demonstrated in the case of the H135E/G149D variant compared to H135E.     

Construction of a new leucine dehydrogenase with preferred specificity for NADP+ by site-directed mutagenesis of the strictly NAD+-specific enzyme

On the basis of sequence comparison between NAD+-dependent leucine dehydrogenase (LeuDH) from Thermoactinomyces intermedius and NADP+- dependent dehydrogenases, a set of amino acid residues that are supposed to determine the coenzyme specificity of LeuDH were assigned. Systematic replacement of these amino acids by others was done with the aim to switch its natural coenzyme specificity to a new one preferring NADP+. Single D203A, double D203A-I204R and triple D203A-I204R-D210R mutation enzymes were constructed. The wild-type LeuDH is inactive with NADP+. However, D203A single mutant exhibited dual specificity for NAD+ and NADP+ with essentially identical k(cat)/Km values for both coenzymes, but the values were three orders of magnitude lower than that of the wild-type enzyme. Introduction of positive charge at 204 together with the removal of the negative charge at 203 in the double mutant D203A-I204R provided the enzyme with significantly high affinity for NADP+. The best k(cat)/Km value for NADP+ was shown for the triple mutant D203A-I204R-D210R: more than 2% of the k(cat)/Km value of the wild-type enzyme. Thus, we succeeded in constructing a mutant LeuDH with a new coenzyme specificity preferring NADP+ which is highly active (specific activity, 19 micromol/mg/min).      

Separation of the two reactions, oxidation and isomerization, catalyzed by Streptomyces cholesterol oxidase

Site-directed mutagenesis was used to identify key amino acid residues of the cholesterol oxidase from Streptomyces sp., which catalyzes the oxidation of cholesterol and the isomerization of 5-cholesten-3-one. Eight mutant enzymes were constructed and the following amino acid substitutions were identified: N318A, N318H, E356A, E356D, H441A, H441N, N480A and N480Q. Mutants N318A and N318H retained both oxidation and isomerization activities. The mutant E356D retained oxidation but not isomerization activity. On the other hand, mutants N480A and N480Q showed no oxidation activity but retained their isomerization activities. The two catalytic reactions, oxidation and isomerization, in cholesterol oxidase were thus successfully separated. When the H441A or H441N mutation was introduced, both the oxidase and isomerase activities were completely lost. The H441, E356 and N480 residues thus appear to participate in the catalysis of cholesterol oxidase, whereas N318 does not. An analysis of the products of these mutant enzymes suggested that the previously proposed 6-hydroxylation reaction by cholesterol oxidase is actually autooxidation from 5-cholesten-3-one. Kinetic studies of the purified wild-type and mutant enzymes showed that the k(cat)/Km values for oxidation in E356D and for isomerization in N480A increased six- and threefold, respectively, over those in the wild-type. These mutational effects and the reaction mechanisms are discussed in terms of the three-dimensional structure of the enzyme constructed on the basis of homology modeling.      

Increasing the thermostability of D-xylose isomerase by introduction of a proline into the turn of a random coil

Thermostability can be increased by introducing prolines atsuitable sites in target proteins. Two single (G138P, G247D)mutants and one double (G138P/G247D) mutant of xylose isomerasefrom Streptomyces diastaticus No.7, strain M1033 have been constructedby site-directed mutagenesis. With respect to the wild-typeenzyme, G138P showed about a 100% increase in thermostability,and G247D showed an increased catalytic activity. Significantly,the double mutant, G138P/G247D displayed even higher activitythan G247D and better heat stability than G138P. Its half lifewas about 2.5-fold greater than the wild-type enzyme, usingxylose as a substrate. Molecular modelling suggested that theintroduction of a proline residue in the turn of a random coilmay cause the surrounding conformation to be tightened by reducingthe backbone flexibility. The change in thermostability can,therefore, be explained based on changes in the molecular rigidity.Furthermore, the improvements in the properties of the doublemutant indicated that the advantages of two single mutants canbe combined effectively.     

Directed evolution by accumulating tailored mutations: thermostabilization of lactate oxidase with less trade-off with catalytic activity

We assumed that adverse effects posed by introducing multiple mutations could be decomposed into those of each of the component mutations and that the risk could be reduced by the accumulation of mutations that were finely tuned for directed improvement of a specific property. We propose here a directed evolution strategy for improving a specific property with less effect on other ones. This strategy is composed of fine-tuning of mutations and their accumulation by our original mutation-assembling method. In this study, we selected lactate oxidase (LOX) as a model enzyme, because its directed evolution had showed a trade-off between thermostability and catalytic activity. Mutation profiling at each of the sites found by error-prone PCR revealed a strong inverse relationship between the two properties. Thermostable mutations with less effect on catalytic activity were selected at each site and accumulated with ideal combinations by our method. The resultant multiple mutants exhibited 5- to 10-fold superior catalytic activity and comparable thermostability with those created by accumulating thermostable mutations, which were not tuned for catalytic activity. This result demonstrates that the accumulation of fine-tuned mutations is an advantageous approach to reduce the risk of adverse effects posed by accumulating multiple mutations.     

Engineering of Pseudomonas aeruginosa lipase by directed evolution for enhanced amidase activity: mechanistic implication for amide hydrolysis by serine hydrolases

A lipase from Pseudomonas aeruginosa was subjected to directed evolution for increased amidase activity to probe the catalytic mechanism of serine hydrolases for the hydrolysis of amides. Random mutagenesis combined with saturation mutagenesis for all the amino acid residues at the substrate-binding site successfully identified the mutation at the residue 252 next to the catalytic H251 as a hot spot for selectively increasing the amidase activity of the lipase. The saturation mutagenesis targeted for the oxyanion hole (M16 and H83) gave no positive results. The substitutions of Met or Phe for Leu252 significantly increased the amidase activity toward N-(2-naphthyl)oleamide (2), whereas the esterase activity toward structurally similar 2-naphthyl oleate (1) was not affected by the substitution. The triple mutant F207S/A213D/M252F (Sat252) exhibited amidase activity (k(cat)/K(m)) 28-fold higher than that of the wild-type lipase. Kinetic analysis of Sat252 and its parental clone 10F12 revealed that the amidase activity was increased by the increase in the catalytic efficiency (k(cat)). The increase in k(cat) suggested the importance of the leaving group protonation by the catalytic His during the break down of the tetrahedral intermediate in the hydrolysis of amides.     

Laboratory evolution of P450 BM3 for mediated electron transfer yielding an activity-improved and reductase-independent variant

One of the main obstacles in employing P450 monooxygenases for preparative chemical syntheses in cell-free systems is their requirement for cofactors such as NAD(P)H. In order to engineer P450 BM3 from Bacillus megaterium for cost-effective process conditions in vitro, a validated medium throughput screening system based on cheap Zn dust as an electron source and Cobalt(III)sepulchrate (Co(III)sep) as a mediator was reported. In the current study, the alternative cofactor system Zn/Co(III)sep was used in a directed evolution experiment to improve the Co(III)sep-mediated electron transfer to P450 BM3. A variant, carrying five mutations (R47F F87A V281G M354S D363H, Table I), P450 BM3 M5 was identified and characterized with respect to its kinetic parameters. P450 BM3 M5 achieved for mediated electron transfer a 2-fold higher k(cat) value and a 3-fold higher catalytic efficiency compared with the starting point mutant P450 BM3 F87A (k(cat): 62 min(-1) compared with 28 min(-1); k(cat)/K(m): 62 microM(-1)min(-1) compared to 19 microM(-1)min(-1)). For obtaining first insights on electron transfer contributions, three reductase-deficient variants were generated. The reductase-deficient mutant of P450 BMP M5 exhibited a catalytic efficiency of 69% and a k(cat) value of 89% of the values obtained for P450 BM3 M5.     

3-D structure of the D153G mutant of Escherichia coli alkaline phosphatase: an enzyme with weaker magnesium binding and increased catalytic activity

The substitution of aspartate at position 153 in Escherichiacoli alkaline phosphatase by glycine results in a mutant enzymewith 5-fold higher catalytic activity (k_cat but no change inKm at pH 8.0 in 50 mM Tris-HCl. The increased k_cat is achievedby a faster release of the phosphate product as a result ofthe lower phosphate affinity. The mutation also affects Mg²⁺binding, resulting in an enzyme with lower metal affinity. The3-D X-ray structure of the D153G mutant has been refined at2.5 Å to a crystallographic Rfactor of 16.2%. An analysisof this structure has revealed that the decreased phosphateaffinity is caused by an apparent increase in flexibility ofthe guanidinium side chain of Argl66 involved in phosphate binding.The mutation of Aspl53 to Gly also affects the position of thewater ligands of Mg²⁺, and the loop Glnl52–Thrl55 is shiftedby 0.3 Å away from the active site. The weaker Mg²⁺ bindingof the mutant compared with the wild type is caused by an alteredcoordination sphere in the proximity of the Mg²⁺ ion, and alsoby the loss of an electrostatic interaction (Mg²⁺.COO^-Aspl53)in the mutant Its ligands W454 and W455 and hydroxyl of Thrl55,involved in the octahedral coordination of the Mg²⁺ ion, arefurther apart in the mutant compared with the wild-type     

Construction of novel subtilisin E with high specificity, activity and productivity through multiple amino acid substitutions

Through three cumulative amino acid substitutions, we constructed novel mutant subtilisins E of Bacillus subtilis, all with high specificity, activity and productivity. The substitution of conserved Gly127, constituting P1 substrate-binding pocket, with Ala and Val showed a marked preference for the small P1 substrate. Leu was then substituted for Ile31 next to the catalytic Asp32 to enhance the catalytic activity. Both double mutants (I31L/G127A and I31L/G127V) showed a 3-5- fold increase in catalytic efficiency due to a large kcat, without any change in the specificity of the mutants at position 127. Molecular modeling suggests that large P1 residues were unable to access the pocket because of steric hindrance. A third mutation was introduced by replacing Tyr(-1) with Ala in the propeptide essential for autoprocessing to active mature subtilisin in vivo. A prominent 7-20- fold increase in active enzyme production occurred in the triple mutants (Y-1A/I31L/G127A and Y-1A/I31L/G127V).      

Improving thermostability of phosphatidylinositol-synthesizing Streptomyces phospholipase D

Aimed to produce thermostable phosphatidylinositol (PI)-synthesizing phospholipase D (PLD), we initiated site-directed combinatorial mutagenesis followed by high-throughput screening. Previous site-directed combinatorial mutagenesis of wild-type Streptomyces PLD produced a mutant, DYR (W187D/Y191Y/Y385R) with PI-synthesizing ability. Deriving PI as a product of transphosphatidylation between phosphatidylcholine and myo-inositol, with myo-inositol in excess at high-temperature reaction conditions can increase yield due to enhanced solubility of this substrate. Thus, we improved DYR's thermostability by introduction of random mutations into selected amino acid positions having high B-factor. Screening of the libraries under restricted conditions yielded single-point mutants, specifically D40H, T291Y and R329G. Combinations of these point mutations yielded double (D40H/T291Y, D40H/R329G and T291Y/R329G) and triple (D40H/T291Y/R329G) mutants. PI synthesis at elevated temperatures pointed at D40H/T291Y as the most efficient enzyme. Circular dichroism analysis revealed D40H/T291Y to have increased melting temperature and postponed onset of thermal unfolding compared with DYR. Thermal tolerance study at 65°C confirmed D40H/T291Y's thermostability as its half-inactivation time was 8.7 min longer compared with DYR. This mutant had significantly less root-mean-square deviation change compared with DYR and showed no change in root-mean-square fluctuation when temperature shifts from 40 to 60°C, as determined by molecular dynamics analysis. Acquired different degrees of thermostability were also observed for several other DYR mutants.     

Glucoamylase mutants in the conserved active-site segment Trp170-Tyr175 located at a distance from the site of catalysis

To mimic the structure of the 1.8-fold more active (k(cat)) Rhizopus oryzae glucoamylase (GA), Aspergillus niger GA was subjected to site- directed mutagenesis in the Trp170-Tyr175 segment of the third of the six well-conserved alpha-->alpha connecting loops of the catalytic (alpha/alpha)6-barrel. While the Trp170-->Phe, Gln172-->Asn and Tyr175-- >Phe mutants showed an up to 1.7-fold increased k(cat) and Gly174-->Cys GA and approximately 2-fold reduced k(cat) towards maltotriose and longer substrates, Asn171-->Ser, Thr173-->Gly and A.niger wild-type GA had very similar kcat and K(m) values for the hydrolysis of isomaltose and the malto-oligosaccharides of DP 2-7. Crystal structures of pseudotetrasaccharide inhibitor complexes of Aspergillus awamori var. X100 GA, which is 94% identical to A.niger GA, indicate that Tyr175 is located at binding subsite 4, while the preceding target residues and the high-mannose type unit on Asn171 are at a larger distance from the site of catalysis. The mutations had a modest effect on thermostability; the temperature for 50% inactivation, Tm, was thus unchanged for Tyr175 -->Phe GA and reduced by 0.2-2.9 degrees C for the other mutants. The deletion of the N-linked high-mannose unit-in Asn171 -->Ser and Thr173-->Gly GAs-appeared to be of minor importance for enzyme activity and thermostability, and did not increase the sensitivity to proteolysis.      

Engineered dimer interface mutants of triosephosphate isomerase: the role of inter-subunit interactions in enzyme function and stability

The role of inter-subunit interactions in maintaining optimal catalytic activity in triosephosphate isomerase (TIM) has been probed, using the Plasmodium falciparum enzyme as a model. Examination of subunit interface contacts in the crystal structures suggests that residue 75 (Thr, conserved) and residue 13 (Cys, variable) make the largest number of inter-subunit contacts. The mutants Cys13Asp (C13D) and Cys13Glu (C13E) have been constructed and display significant reduction in catalytic activity when compared with wild-type (WT) enzyme (～ 7.4-fold decrease in k(cat) for the C13D and ～ 3.3-fold for the C13E mutants). Analytical gel filtration demonstrates that the C13D mutant dissociates at concentrations <1.25 μM, whereas the WT and the C13E enzymes retain the dimeric structure. The order of stability of the mutants in the presence of chemical denaturants, like urea and guanidium chloride, is WT > Cys13Glu > Cys13Asp. Irreversible thermal precipitation temperatures follow the same order as well. Modeling studies establish that the Cys13Asp mutation is likely to cause a significantly greater structural perturbation than Cys13Glu. Analysis of sequence and structural data for TIMs from diverse sources suggests that residues 13 and 82 form a pair of proximal sites, in which a limited number of residue pairs may be accommodated.     

Engineering Leifsonia Alcohol Dehydrogenase for Thermostability and Catalytic Efficiency by Enhancing Subunit Interactions

Leifsonia alcohol dehydrogenase (LnADH) is a promising biocatalyst for the synthesis of chiral alcohols. However, limitations of wild-type LnADH observed for practical application include low activity and poor stability. In this work, protein engineering was employed to improve its thermostability and catalytic efficiency by altering the subunit interfaces. Residues T100 and S148 were identified to be significant for thermostability and activity, and the melting temperature (ΔT_m) and catalytic efficiency of the mutant T100R/S148I toward ketone substrates was improved by 18.7 °C and 1.8–5.5-fold. Solving the crystal structures of the wild-type enzyme and T100R/S148L revealed beneficial effects of mutations on stability and catalytic activity. The most robust mutant T100R/S148I is promising for industrial applications and can produce 200 g liter⁻¹ day⁻¹ chiral alcohols at 50 °C by only a 1 : 500 ratio of enzyme to substrate.     

Shifting the optimal pH of activity for a laccase from the fungus Trametes versicolor by structure-based mutagenesis

Laccases are oxidizing enzymes of interest because of their potential environmental and industrial applications. We performed site-directed mutagenesis of a laccase produced by Trametes versicolor in order to improve its catalytic properties. Considering a strong interaction of the Asp residue in position 206 with the substrate xylidine, we replaced it with Glu, Ala or Asn, expressed the mutant enzymes in the yeast Yarrowia lipolytica and assayed the transformation of phenolic and non-phenolic substrates. The transformation rates remain within the same range whatever the mutation of the laccase and the type of substrate: at most a 3-fold factor increase was obtained for k(cat) between the wild-type and the most efficient mutant Asp206Ala with 2,2'-azinobis(3-ethylbenzthiazoline-6-sulfonic) acid as a substrate. Nevertheless, the Asn mutation led to a significant shift of the pH (DeltapH = 1.4) for optimal activity against 2,6-dimethoxyphenol. This study also provides a new insight into the binding of the reducing substrate into the active T1 site and induced modifications in catalytic properties of the enzyme.     

Phosphotriesterase variants with high methylphosphonatase activity and strong negative trade-off against phosphotriesters

The most lethal organophosphorus nerve agents (NA), like sarin, soman, agent-VX and Russian-VX, share a methylphosphonate moiety. Pseudomonas diminuta phosphotriesterase (PTE) catalyses the hydrolysis of methylphosphonate NA analogues with a catalytic efficiency orders of magnitude lower than that towards the pesticide paraoxon. With a view to obtaining PTE variants that more readily accept methylphosphonate NA, ~75,000 PTE variants of the substrate-binding residues Gly-60, Ile-106, Leu-303 and Ser-308 were screened with fluorogenic analogues of the NA Russian-VX and cyclosarin. Seven new PTE variants were isolated, purified and their k(cat)/K(M) determined against five phosphotriesters and five methylphosphonate analogues of sarin, cyclosarin, soman, agent-VX and Russian-VX. The novel PTE variants exhibited as much as a 10-fold increase in activity towards the methylphosphonate compounds--many reaching a k(cat)/K(M) of 10? M?1 s?1--and as much as a 29,000-fold decrease in their phosphotriesterase activity. The mutations found in two of the variants, SS0.5 (G60V/I106L/S308G) and SS4.5 (G60V/I106A/S308G), were modelled into a high-resolution structure of PTE-wild type and docked with analogues of cyclosarin and Russian-VX using Autodock 4.2. The kinetic data and docking simulations suggest that the increase in activity towards the methylphosphonates and the loss of function against the phosphotriesters were due to an alteration of the shape and hydrophobicity of the binding pocket that hinders the productive binding of non-chiral racemic phosphotriesters, yet allows the binding of the highly asymmetric methylphosphonates.