Designs for a broad substrate specificity keto acid dehydrogenase

Radical-free hyperpolarized MRI using endogenously occurring pyruvate analogues and UV-induced nonpersistent radicals

It was recently demonstrated that nonpersistent radicals can be generated in frozen solutions of metabolites such as pyruvate by irradiation with UV light, enabling radical-free dissolution dynamic nuclear polarization. Although pyruvate is endogenous, the presence of pyruvate may interfere with metabolic processes or the detection of pyruvate as a metabolic product, making it potentially unsuitable as a polarizing agent. Therefore, the aim of the current study was to characterize solutions containing endogenously occurring alternatives to pyruvate as UV-induced nonpersistent radical precursors for in vivo hyperpolarized MRI. The metabolites alpha-ketovalerate (αkV) and alpha-ketobutyrate (αkB) are analogues of pyruvate and were chosen as potential radical precursors. Sample formulations containing αkV and αkB were studied with UV-visible spectroscopy, irradiated with UV light, and their nonpersistent radical yields were quantified with electron spin resonance and compared with pyruvate. The addition of 13 C-labeled substrates to the sample matrix altered the radical yield of the precursors. Using αkB increased the 13 C-labeled glucose liquid-state polarization to 16.3% ± 1.3% compared with 13.3% ± 1.5% obtained with pyruvate, and 8.9% ± 2.1% with αkV. For [1-13 C]butyric acid, polarization levels of 12.1% ± 1.1% for αkV, 12.9% ± 1.7% for αkB, 1.5% ± 0.2% for OX063 and 18.7% ± 0.7% for Finland trityl, were achieved. Hyperpolarized [1-13 C]butyrate metabolism in the heart revealed label incorporation into [1-13 C]acetylcarnitine, [1-13 C]acetoacetate, [1-13 C]butyrylcarnitine, [5-13 C]glutamate and [5-13 C]citrate. This study demonstrates the potential of αkV and αkB as endogenous polarizing agents for in vivo radical-free hyperpolarized MRI. UV-induced, nonpersistent radicals generated in endogenous metabolites enable high polarization without requiring radical filtration, thus simplifying the quality-control tests in clinical applications.

Enzymatic biofuel cells based on protein engineering: recent advances and future prospects

Enzymatic biofuel cells (EBFCs), as one of the most promising sustainable and green energy sources, have attracted significant interest.

Triple Isotope Effects Support Concerted Hydride and Proton Transfer and Promoting Vibrations in Human Heart Lactate Dehydrogenase

Transition path sampling simulations have proposed that human heart lactate dehydrogenase (LDH) employs protein promoting vibrations (PPVs) on the femtosecond (fs) to picosecond (ps) time scale to promote crossing of the chemical barrier. This chemical barrier involves both hydride and proton transfers to pyruvate to form l-lactate, using reduced nicotinamide adenine dinucleotide (NADH) as the cofactor. Here we report experimental evidence from three types of isotope effect experiments that support coupling of the promoting vibrations to barrier crossing and the coincidence of hydride and proton transfer. We prepared the native (light) LDH and a heavy LDH labeled with ¹³C, ¹⁵N, and nonexchangeable ²H (D) to perturb the predicted PPVs. Heavy LDH has slowed chemistry in single turnover experiments, supporting a contribution of PPVs to transition state formation. Both the [4-²H]NADH (NADD) kinetic isotope effect and the D₂O solvent isotope effect were increased in dual-label experiments combining both NADD and D₂O, a pattern maintained with both light and heavy LDHs. These isotope effects support concerted hydride and proton transfer for both light and heavy LDHs. Although the transition state barrier-crossing probability is reduced in heavy LDH, the concerted mechanism of the hydride-proton transfer reaction is not altered. This study takes advantage of triple isotope effects to resolve the chemical mechanism of LDH and establish the coupling of fs-ps protein dynamics to barrier crossing.

Protein Conformational Landscapes and Catalysis. Influence of Active Site Conformations in the Reaction Catalyzed by L-Lactate Dehydrogenase

In the last decade L-Lactate Dehydrogenase (LDH) has become an extremely useful marker in both clinical diagnosis and in monitoring the course of many human diseases. It has been assumed from the 80s that the full catalytic process of LDH starts with the binding of the cofactor and the substrate followed by the enclosure of the active site by a mobile loop of the protein before the reaction to take place. In this paper we show that the chemical step of the LDH catalyzed reaction can proceed within the open loop conformation, and the different reactivity of the different protein conformations would be in agreement with the broad range of rate constants measured in single molecule spectrometry studies. Starting from a recently solved X-ray diffraction structure that presented an open loop conformation in two of the four chains of the tetramer, QM/MM free energy surfaces have been obtained at different levels of theory. Depending on the level of theory used to describe the electronic structure, the free energy barrier for the transformation of pyruvate into lactate with the open conformation of the protein varies between 12.9 and 16.3 kcal/mol, after quantizing the vibrations and adding the contributions of recrossing and tunneling effects. These values are very close to the experimentally deduced one (14.2 kcal·mol^-1) and ~2 kcal·mol^-1 smaller than the ones obtained with the closed loop conformer. Calculation of primary KIEs and IR spectra in both protein conformations are also consistent with our hypothesis and in agreement with experimental data. Our calculations suggest that the closure of the active site is mainly required for the inverse process; the oxidation of lactate to pyruvate. According to this hypothesis H4 type LDH enzyme molecules, where it has been propose that lactate is transformed into pyruvate, should have a better ability to close the mobile loop than the M4 type LDH molecules.

Characterization of site-specific mutations in a short-chain-length/medium-chain-length polyhydroxyalkanoate synthase: in vivo and in vitro studies of enzymatic activity and substrate specificity

Saturation point mutagenesis was carried out at position 479 in the polyhydroxyalkanoate (PHA) synthase from Chromobacterium sp. strain USM2 (PhaC(Cs)) with specificities for short-chain-length (SCL) [(R)-3-hydroxybutyrate (3HB) and (R)-3-hydroxyvalerate (3HV)] and medium-chain-length (MCL) [(R)-3-hydroxyhexanoate (3HHx)] monomers in an effort to enhance the specificity of the enzyme for 3HHx. A maximum 4-fold increase in 3HHx incorporation and a 1.6-fold increase in PHA biosynthesis, more than the wild-type synthase, was achieved using selected mutant synthases. These increases were subsequently correlated with improved synthase activity and increased preference of PhaC(Cs) for 3HHx monomers. We found that substitutions with uncharged residues were beneficial, as they resulted in enhanced PHA production and/or 3HHx incorporation. Further analysis led to postulations that the size and geometry of the substrate-binding pocket are determinants of PHA accumulation, 3HHx fraction, and chain length specificity. In vitro activities for polymerization of 3HV and 3HHx monomers were consistent with in vivo substrate specificities. Ultimately, the preference shown by wild-type and mutant synthases for either SCL (C(4) and C(5)) or MCL (C(6)) substrates substantiates the fundamental classification of PHA synthases.

Rationally re-designed mutation of NAD-independent L-lactate dehydrogenase: high optical resolution of racemic mandelic acid by the engineered Escherichia coli

Background

NAD-independent l-lactate dehydrogenase (l-iLDH) from Pseudomonas stutzeri SDM can potentially be used for the kinetic resolution of small aliphatic 2-hydroxycarboxylic acids. However, this enzyme showed rather low activity towards aromatic 2-hydroxycarboxylic acids.

Results

Val-108 of l-iLDH was changed to Ala by rationally site-directed mutagenesis. The l-iLDH mutant exhibited much higher activity than wide-type l-iLDH towards l-mandelate, an aromatic 2-hydroxycarboxylic acid. Using the engineered Escherichia coli expressing the mutant l-iLDH as a biocatalyst, 40 g·L^-1 of dl-mandelic acid was converted to 20.1 g·L^-1 of d-mandelic acid (enantiomeric purity higher than 99.5%) and 19.3 g·L^-1 of benzoylformic acid.

Conclusions

A new biocatalyst with high catalytic efficiency toward an unnatural substrate was constructed by rationally re-design mutagenesis. Two building block intermediates (optically pure d-mandelic acid and benzoylformic acid) were efficiently produced by the one-pot biotransformation system.

Force field design and molecular dynamics simulations of factor-inhibiting HIF-1 and its complex with known inhibitors: implications for rational inhibitor design

Based on molecular dynamics simulations in aqueous solution, we investigate the dynamic properties of factor-inhibiting HIF-1 (FIH1) and its complexes with the substrate 2-oxoglutarate (2OG) and the two known inhibitors, N-oxalylglycine (NOG) and N-oxalyl-D-phenylalanine (NODP). The results obtained with the newly developed force field parameters for the coordination environment of the active-site ferrous ion show that FIH1 undergoes a significant conformational stabilization with a decrease in motional amplitude upon binding of the substrate or the inhibitors. Two loop structures around the active-site reveal a high flexibility in the resting form of FIH1 with the high B-factor values. These high-amplitude motions of the flexible loops are found to be weakened significantly in the presence of the substrate or a weak inhibitor (NOG), and damped out upon binding of a potent and selective inhibitor (NODP) in the active site. A characteristic feature that discriminates the coordination structures of the active-site ferrous ion in complex with 2OG and NOG in solution from those in the X-ray crystal structures lies in the presence of a structural water molecule from bulk solvent at the sixth coordination position, which leads to the formation of a stable octahedral coordination geometry. However, the approach of such a structural water molecule to the active-site ferrous ion is prohibited in the FIH1-NODP complex, which should be attributed to the formation of hydrophobic contacts between the phenyl ring of the inhibitor and the side chains of Tyr102, Leu186, and Trp296 at the entrance of the active site. This indicates that the D-enantiomeric side-chain phenyl group of NODP should play an essential role in potent and selective inhibition of FIH1.

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.

Enzymatic properties of the lactate dehydrogenase enzyme from Plasmodium falciparum

The lactate dehydrogenase enzyme from Plasmodium falciparum (PfLDH) is a target for antimalarial compounds owing to structural and functional differences from the human isozymes. The plasmodial enzyme possesses a five-residue insertion in the substrate-specificity loop and exhibits less marked substrate inhibition than its mammalian counterparts. Here we provide a comprehensive kinetic analysis of the enzyme by steady-state and transient kinetic methods. The mechanism deduced by product inhibition studies proves that PfLDH shares a common mechanism with the human LDHs, that of an ordered sequential bireactant system with coenzyme binding first. Transient kinetic analysis reveals that the major rate-limiting step is the closure of the substrate-specificity loop prior to hydride transfer, in line with other LDHs. The five-residue insertion in this loop markedly increases substrate specificity compared with the human muscle and heart isoforms.

Conversion of Lactobacillus pentosus D-lactate dehydrogenase to a D-hydroxyisocaproate dehydrogenase through a single amino acid replacement

The single amino acid replacement of Tyr52 with Leu drastically increased the activity of Lactobacillus pentosus NAD-dependent D-lactate dehydrogenase toward larger aliphatic or aromatic 2-ketoacid substrates by 3 or 4 orders of magnitude and decreased the activity toward pyruvate by about 30-fold, converting the enzyme into a highly active D-2-hydroxyisocaproate dehydrogenase.

Protein engineering 20 years on

It is 20 years since site-directed mutagenesis was first used to modify the active site of an enzyme of known structure and mechanism. Since then, this method has contributed far-reaching insights into catalysis, specificity, stability and folding of proteins. Engineered proteins are now being used in industry and for the improved treatment of human disease.

A method for the determination of enzyme mass loading on an electrode surface through radioisotope labelling

A direct method has been developed for the quantitation of the amount of immobilised enzymes on biosensor surfaces. This quantity is of key importance in establishing the activity, kinetics and optimal immobilisation conditions in the construction of both amperometric and optical biosensors. Recombinant L-lactate dehydrogenase incorporating both a biosynthetically introduced radiolabel, 3H-leucine, and a hexahistidine peptide tag was immobilised on a poly(aniline) composite film and then quantitated by liquid scintillation counting. It was found that enzyme mass loading was proportional to the concentration of LDH in solution, and also depended on the morphology of the composite film. The LDH mass loading on the composite film doubled when a surface cysteine containing variant was used, possibly due to the covalent attachment of the cysteine to the diiminoquinoid rings of the poly(aniline).

Introduction of a (poly)histidine tag in L-lactate dehydrogenase produces a mixture of active and inactive molecules

A (poly)histidine tag was fused to either the N- or the C-terminus of L-lactate dehydrogenase (LDH) of Bacillus stearothermophilus to facilitate purification and immobilization of these enzymes. The C-terminally tagged enzyme displayed lower activity compared both to the wild-type and to the N-terminally tagged variant. The reason for this loss of activity was investigated by affinity chromatography of the enzymes on a 5'-AMP-Sepharose resin and by size-exclusion chromatography. The C-terminally tagged enzyme could be separated into an inactive, unbound fraction and an active, bound fraction. Further differences between the C-terminally tagged enzyme and the N-terminally tagged and wild-type LDH were observed on size-exclusion chromatography of the three enzymes. These data suggest that the introduction of a "his-tag" at the C-terminus may induce misfolding of the LDH and serve as a warning that the introduction of a (poly)histidine tag can produce unforseen changes in a protein.

The first examples of (S)-2-hydroxyacid dehydrogenases catalyzing the transfer of the pro-4S hydrogen of NADH are found in the archaea

Reduction of 2-oxoacids to the corresponding (S)-2-hydroxyacids is an important transformation in biochemistry. To date all (S)-2-hydroxyacid dehydrogenases belonging to the L-lactate/L-malate dehydrogenase family have been found to transfer the pro-4R hydrogen of either NADH or NADPH to C-2 of the 2-oxoacid substrates during their reduction. Here, we report that recombinantly generated (S)-2-hydroxyacid dehydrogenases present in the methanoarchaea Methanococcus jannaschii and Methanothermus fervidus use the pro-4S hydrogen of NADH to reduce a series of 2-oxoacids to the corresponding (S)-2-hydroxyacids. This information as well as the low sequence identity between these archaeal enzymes and the L-lactate/L-malate family of enzymes indicate that these enzymes are not evolutionary related and therefore constitute a new class of (S)-2-hydroxyacid dehydrogenases.

Some Lactobacillus L-lactate dehydrogenases exhibit comparable catalytic activities for pyruvate and oxaloacetate

The nonallosteric and allosteric L-lactate dehydrogenases of Lactobacillus pentosus and L. casei, respectively, exhibited broad substrate specificities, giving virtually the same maximal reaction velocity and substrate K(m) values for pyruvate and oxaloacetate. Replacement of Pro101 with Asn reduced the activity of the L. pentosus enzyme toward these alternative substrates to a greater extent than the activity toward pyruvate.

Identification of an archaeal 2-hydroxy acid dehydrogenase catalyzing reactions involved in coenzyme biosynthesis in methanoarchaea

Two putative malate dehydrogenase genes, MJ1425 and MJ0490, from Methanococcus jannaschii and one from Methanothermus fervidus were cloned and overexpressed in Escherichia coli, and their gene products were tested for the ability to catalyze pyridine nucleotide-dependent oxidation and reduction reactions of the following alpha-hydroxy-alpha-keto acid pairs: (S)-sulfolactic acid and sulfopyruvic acid; (S)-alpha-hydroxyglutaric acid and alpha-ketoglutaric acid; (S)-lactic acid and pyruvic acid; and 1-hydroxy-1,3,4,6-hexanetetracarboxylic acid and 1-oxo-1,3,4, 6-hexanetetracarboxylic acid. Each of these reactions is involved in the formation of coenzyme M, methanopterin, coenzyme F(420), and methanofuran, respectively. Both the MJ1425-encoded enzyme and the MJ0490-encoded enzyme were found to function to different degrees as malate dehydrogenases, reducing oxalacetate to (S)-malate using either NADH or NADPH as a reductant. Both enzymes were found to use either NADH or NADPH to reduce sulfopyruvate to (S)-sulfolactate, but the V(max)/K(m) value for the reduction of sulfopyruvate by NADH using the MJ1425-encoded enzyme was 20 times greater than any other combination of enzymes and pyridine nucleotides. Both the M. fervidus and the MJ1425-encoded enzyme catalyzed the NAD(+)-dependent oxidation of (S)-sulfolactate to sulfopyruvate. The MJ1425-encoded enzyme also catalyzed the NADH-dependent reduction of alpha-ketoglutaric acid to (S)-hydroxyglutaric acid, a component of methanopterin. Neither of the enzymes reduced pyruvate to (S)-lactate, a component of coenzyme F(420). Only the MJ1425-encoded enzyme was found to reduce 1-oxo-1,3,4,6-hexanetetracarboxylic acid, and this reduction occurred only to a small extent and produced an isomer of 1-hydroxy-1,3,4,6-hexanetetracarboxylic acid that is not involved in the biosynthesis of methanofuran c. We conclude that the MJ1425-encoded enzyme is likely to be involved in the biosynthesis of both coenzyme M and methanopterin.

Thermozymes

Enzymes synthesized by thermophiles (organisms with optimal growth temperatures > 60 degrees C) and hyperthermophiles (optimal growth temperatures > 80 degrees C) are typically thermostable (resistant to irreversible inactivation at high temperatures) and thermophilic (optimally active at high temperatures, i.e., > 60 degrees C). These enzymes, called thermozymes, share catalytic mechanisms with their mesophilic counterparts. When cloned and expressed in mesophilic hosts, thermozymes usually retain their thermal properties, suggesting that these properties are genetically encoded. Sequence alignments, amino acid content comparisons, and crystal structure comparisons indicate that thermozymes are, indeed, very similar to mesophilic enzymes. No obvious sequence or structural features account for enzyme thermostability and thermophilicity. Thermostability and thermophilicity molecular mechanisms are varied, differing from enzyme to enzyme. Thermostability and thermophilicity are usually caused by the accumulation of numerous subtle sequence differences. This review concentrates on the mechanisms involved in enzyme thermostability and thermophilicity. Their relationships with protein rigidity and flexibility and with protein folding and unfolding are discussed. Intrinsic stabilizing forces (e.g., salt bridges, hydrogen bonds, hydrophobic interactions) and extrinsic stabilizing factors are examined. Finally, thermozymes' potential as catalysts for industrial processes and specialty uses are discussed, and lines of development (through new applications, and protein engineering) are also proposed.

Hybrid enzymes: manipulating enzyme design

Hybrid enzymes are engineered to contain elements of two or more enzymes. Hybrid-enzyme approaches, by taking advantage of the vast array of enzymatic properties that nature has evolved, as well as the strategies that nature has used to evolve them, are becoming an increasingly important avenue for obtaining novel enzymes with desired activities and properties.

Cloning, sequencing and functional expression of a DNA encoding pig cytosolic malate dehydrogenase: purification and characterization of the recombinant enzyme

Using the polymerase chain reaction, DNA encoding cytosolic malate dehydrogenase (cMDH) has been cloned from a pig heart cDNA library. Large amounts of the enzyme (30 mg per litre of original culture) have been produced in Escherichia coli using an inducible expression vector (pKK223-3) in which the 5'-non-coding region of the gene was replaced with the tac promoter. The complete nucleotide sequence of the DNA is reported for the first time. The recombinant cMDH purified was shown to be identical to the native enzyme according to: chromatographic behaviour, isoelectric point, N-terminal amino acid sequence, and physiochemical and catalytic properties.

A single amino acid mutation enhances the thermal stability of Escherichia coli malate dehydrogenase

The stability of wild-type Escherichia coli malate dehydrogenase was compared with a mutant form of the enzyme with the amino acid residue at position 102 changed from arginine to glutamine. The mutation occurs on the underside of a mobile loop which closes over the active-site cleft on formation of the enzyme/cofactor/substrate ternary complex. The mutant enzyme is kinetically compromised while the wild-type enzyme is highly specific for oxaloacetate. The mutant enzyme was shown to be more resistant to irreversible thermal denaturation by thermal inactivation experiments and high-sensitivity differential scanning calorimetry than the wild-type enzyme. In contrast, resistance of both enzymes to reversible unfolding in guanidinium chloride was similar. Circular dichroic spectropolarimetry shows the secondary structures of the enzymes are similar but there is a demonstrable difference in tertiary structure. From the position of the mutation, it is conjectured that the substitution on a mobile surface loop results in partial closure of the loop and greater resistance to thermal inactivation of the mutant enzyme. However, molecular modelling combined with circular dichroic spectropolarimetry indicate that the mutation may have a more widespread effect on the structure than simply partial closure of the mobile surface loop as the environment of distant tyrosine residues is altered. Resistance of the wild-type enzyme to thermal inactivation can be increased by cofactor addition, which may have the effect of partial closure of the mobile surface loop, but has little effect on the mutant enzyme.

Strategic manipulation of the substrate specificity of Saccharomyces cerevisiae flavocytochrome b2

Flavocytochrome b2 from Saccharomyces cerevisiae acts physiologically as an L-lactate dehydrogenase. Although L-lactate is its primary substrate, the enzyme is also able to utilize a variety of other (S)-2-hydroxy acids. Structural studies and sequence comparisons with several related flavoenzymes have identified the key active-site residues required for catalysis. However, the residues Ala-198 and Leu-230, found in the X-ray-crystal structure to be in contact with the substrate methyl group, are not well conserved. We propose that the interaction between these residues and a prospective substrate molecule has a significant effect on the substrate specificity of the enzyme. In an attempt to modify the specificity in favour of larger substrates, three mutant enzymes have been produced: A198G, L230A and the double mutant A198G/L230A. As a means of quantifying the overall kinetic effect of a mutation, substrate-specificity profiles were produced from steady-state experiments with (S)-2-hydroxy acids of increasing chain length, through which the catalytic efficiency of each mutant enzyme with each substrate could be compared with the corresponding wild-type efficiency. The Ala-198-->Gly mutation had little influence on substrate specificity and caused a general decrease in enzyme efficiency. However, the Leu-230-->Ala mutation caused the selectivity for 2-hydroxyoctanoate over lactate to increase by a factor of 80.

Deletion variants of L-hydroxyisocaproate dehydrogenase. Probing substrate specificity

The substrate specificity and catalytic activity of the dinucleotide-dependent L-2-hydroxyisocaproate dehydrogenase from Lactobacillus confusus (L-HicDH) have been altered by modifying an enzyme region which is assumed to be involved in substrate recognition. The design of the variant enzymes was based on an amino acid alignment of the modified region with the functionally related L-lactate dehydrogenases. The best absolute sequence similarity for a protein with known tertiary structure was found for L-lactate dehydrogenase from dogfish (23%). In this study, the coenzyme loop, a functional element which is essential for catalysis and substrate specificity, was modified in order to identify the residues involved in the catalytic reaction and observe the effect on the substrate specificity. Deletions were introduced into the L-hydroxyisocaproate gene by site-directed mutagenesis. Several deletion-variant enzymes Ile100A delta, Lys100B delta, Leu101 delta, Asn105A delta and Pro105B delta showed an altered substrate specificity. For the variant enzyme with the deletion of Asn/Pro105A/B, 2-oxo carboxylic acids branched at C4 proved to be better substrates than 2-oxocaproate, the substrate with the best kcat/KM ratio known for the wild-type enzyme. The mutation resulted in a 5.2-fold increased catalytic efficiency towards 2-oxoisocaproate compared to the wild-type enzyme. After deleting Ile/Lys100A/B, 2-phenylpyruvate is the only substrate which is still converted at a significant catalytic rate. The kcat ratios of 2-oxocaproate versus 2-phenylpyruvate changed by a factor of 6500 when comparing wild-type enzyme and deletion-variant enzyme data. The single amino acid deletions in position 100A and 100B caused drastic reductions in the catalytic activity for all tested substrates, whereas the deletion of Lys100B, Leu101, Asn105A as well as Pro105B showed more specific modifications in catalytic rates and substrate recognition for each tested substrate.

Engineering surface loops of proteins--a preferred strategy for obtaining new enzyme function

A prerequisite for the rational redesign of enzymes is that altering amino acids in an attempt to obtain new biological function does not unexpectedly alter the globular, natural framework of the native protein on which the design is being executed. The results of combinatorial-mutagenesis strategies suggest that random variation of amino acid sequence is most easily tolerated at the solvent-exposed surfaces of a protein. This review analyses effective redesigns of Bacillus stearothermophilus lactate dehydrogenase (bsLDH), in which all residue variations are at solvent-exposed surfaces. The majority of these variations were located within surface loops, which interconnect stable secondary structures traversing the globular core of the protein.

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

The Gln residue at amino acid position 102 of Bacillus 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 by kcat/Km) 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.

Critical amino acids responsible for converting specificities of proteins and for enhancing enzyme evolution are located around beta-turn potentials: data-based prediction

Various reports have described that amino acid substitutions can alter substrate, positional, inhibitory, and target gene specificities of proteins. By using the method of Chou and Fasman, the present work predicts that critical amino acids for converting these substrate specificities of trypsin, L-lactate dehydrogenase, aspartate aminotransferase, beta-lactamase, and cytochrome P-450 are found to exist within regions predicted as beta-turns. The ratios of hydroxylation and oxygenation positions of substrates by cytochrome P-450 and lipoxygenase, respectively, are varied by changes of the protein structures, probably around turn conformations. Inhibitory specificities of bovine pancreatic trypsin inhibitor and alpha 1-antitrypsin and target gene specificity of glucocorticoid receptor are converted by changing turn structures. Occurrence of beta-turn probabilities can be predicted around the amino acid alteration positions of an evolutionally antecedent protein of a nylon degradation enzyme. These findings will have relevance to work on protein engineering and enzyme evolution.

Design of a specific phenyllactate dehydrogenase by peptide loop exchange on the Bacillus stearothermophilus lactate dehydrogenase framework

Restriction sites were introduced into the gene for Bacillus stearothermophilus lactate dehydrogenase which enabled a region of the gene to be excised which coded for a mobile surface loop of polypeptide (residues 98-110) which normally seals the active site vacuole from bulk solvent and is a major determinant of substrate specificity. Oligonucleotide-overlap extension (using the polymerase chain reaction) was used to obtain double-stranded DNA regions which coded for different length and sequence loops and which also contained the same restriction sites. The variable length and sequence loops were inserted into the cut gene and used to synthesize hydroxyacid dehydrogenases with altered substrate specificities. Loops which were longer and shorter than the original were made. The substrate specificities of enzymes with these new loops were considerably altered. For many poor enzyme-substrate pairs, the effect of fructose 1,6-bisphosphate on the steady-state kinetic parameters suggested that the substrate was mainly bound in a nonproductive mode. With one longer loop construction (BL1), activity with pyruvate was reduced one-million-fold but activity with phenylpyruvate was largely unaltered. A switch in specificity (kcat/KM) of 390,000-fold was achieved. The 1700:1 selectivity of enzyme BL1 for phenylpyruvate over pyruvate is that required in a phenyllactate dehydrogenase to be used in monitoring phenylpyruvate in the urine of patients with phenylketonuria consuming an apparently phenylalanine-free diet.

Evidence for temperature-dependent conformational changes in the L-lactate dehydrogenase from Bacillus stearothermophilus

L-Lactate dehydrogenase from Bacillus stearothermophilus (BSLDH) has been shown to change its conformation in a temperature-dependent manner in the temperature range between 25 and 70 degrees C. To provide a more detailed understanding of this reversible structural reorganization of the tetrameric form of BSLDH, we have determined in the presence of 5 mM fructose, 1,6-bisphosphate (FBP) the effect of temperature on far-UV and near-UV circular dichroism (CD), Nile red-binding to the enzyme surface, NADH binding, fluorescence polarization of fluorescamine-labeled protein, and hydrogen-deuterium exchange. In addition, we have analyzed the temperature dependence of the dimer-tetramer equilibrium of this protein by steady-state enzyme kinetics in the absence of FBP. The results obtained from these measurements at various temperatures can be summarized as follows. No changes in the secondary-structure distribution are detectable from far-UV CD measurements. On the other hand, near-UV CD data reveal that changes in the arrangements of aromatic side chains do occur. With increasing temperature, the asymmetry of the environment around aromatic residues decreases with a small change at 45 degrees C and a more pronounced change at 65 degrees C. Nile red-binding data suggest that the BSLDH surface hydrophobicity changes with temperature. It appears that decreasing the surface hydrophobicity may be a strategy to increase the protein stability of the active enzyme. We have noted significant alterations in the thermodynamic binding parameters of NADH above 45 degrees C, indicating a conformational change in the active site at 45 degrees C. The hydrodynamic volume of BSLDH is also temperature dependent.(ABSTRACT TRUNCATED AT 250 WORDS)

Charge balance in the alpha-hydroxyacid dehydrogenase vacuole: an acid test

The proposal that the active site vacuole of NAD(+)-S-lactate dehydrogenase is unable to accommodate any imbalance in electrostatic charge was tested by genetically manipulating the cDNA coding for human muscle lactate dehydrogenase to make a protein with an aspartic acid introduced at position 140 instead of the wild-type asparagine. The Asn 140-Asp mutant enzyme has the same kcat as the wild type (Asn 140) at low pH (4.5), and at higher pH the Km for pyruvate increases 10-fold for each unit increase in pH up to pH 9. We conclude that the anion of Asp 140 is completely inactive and that it binds pyruvate with a Km that is over 1,000 times that of the Km of the neutral, protonated aspartic-140. Experimental results and molecular modeling studies indicate the pKa of the active site histidine-195 in the enzyme-NADH complex is raised to greater than 10 by the presence of the anion at position 140. Energy minimization and molecular dynamics studies over 36 ps suggest that the anion at position 140 promotes the opening of and the entry of mobile solvent beneath the polypeptide loop (98-110), which normally seals off the internal active site vacuole from external bulk solvent.

Crystallization and preliminary X-ray diffraction studies of two mutants of lactate dehydrogenase from Bacillus stearothermophilus

Bacillus stearothermophilus lactate dehydrogenase, one of the most thermostable bacterial enzymes known, has had its three-dimensional structure solved, the gene coding for it has been cloned, and the protein can be readily overexpressed. Two mutants of the enzyme have been prepared. In one, Arg171 was changed to Trp (R171W) and Gln102 was changed to Arg (Q102R). In the other, the mutation Q102R was maintained, but Arg171 was changed to Tyr (R171Y). In addition, an inadvertent C97G mutant was present. Both mutants have been crystallized by the hanging drop vapor diffusion method at room temperature. Bipyrimidal crystals have been obtained against (NH4)2SO4 in 50 mM piperazine HCl buffer. The crystals belong to space group P6(2)22 (P6(4)22) (whereas the native enzyme, the structure of which has been solved by Piontek et al., Proteins 7:74-92, 1990) crystallized in the space group P6(1)) with a = 102.3 A, c = 168.6 A for the R171W, Q102R, C97G triple mutant, and a = 98.2 A; c = 162.1 A for the R171Y, Q102R, C97G mutant. These crystal forms appear to contain one-quarter of a tetramer (M(r) 135,000) in the asymmetric unit and have VM values of 3.8 and 3.3 A3/dalton, respectively). The R171W mutant diffracts to 2.5 A and the R171 Y mutant to approximately 3.5 A.

Alteration of enzyme specificity and catalysis by protein engineering

New substrate specificities can be introduced into existing enzymes for the purpose of making them more suitable for the chemoenzymic synthesis of single compound drugs and other chiral compounds. The most productive route used in the past year has involved the utilization of the catalytic and substrate-binding properties from homologous enzymes found in nature, one example being the broadening of the substrate specificity of yeast alcohol dehydrogenase. Other highlights include the creation of thermostable dehydrogenases that will interconvert NADPH and NADH, and the design of mutant enzymes with improved catalytic rates compared with their wild-type counterparts.

Construction of new ligand binding sites in proteins of known structure. II. Grafting of a buried transition metal binding site into Escherichia coli thioredoxin

In an accompanying paper a computational procedure is described, which introduces new ligand-binding sites into proteins of known structure. Here we describe the experimental implementation of one of the designs, which is intended to introduce a copper-binding site into Escherichia coli thioredoxin. The new binding site can be introduced with a minimum of four amino acid changes. The binding site is buried so that structural rules for making mutations in the hydrophobic core of a protein, as well as for the introduction of new functions, are being tested in this experiment. The mutant protein is folded even in the absence of metals, and variants that retain the original activity of thioredoxin can be isolated. The protein has gained a metal-binding site specific for transition metals. The metal co-ordination chemistry at the binding site varies depending on the metal that is introduced into it. Mercury(II) is co-ordinated in the expected manner. Copper(II) binds in a way that was not anticipated in the original design. It appears to use two of the four residues intended to form the co-ordination sphere, and two other residues that were not part of the original set of mutations. It is therefore necessary not only to introduce new functional groups to form a new site, but also to consider and remove alternative modes of binding.

Construction of new ligand binding sites in proteins of known structure. I. Computer-aided modeling of sites with pre-defined geometry

We have devised a molecular model building computer program (DEZYMER) which builds new ligand binding sites into a protein of known three-dimensional structure. It alters only the sequence and the side-chain structure of the protein, leaving the protein backbone fold intact by definition. The program searches for a constellation of backbone positions arranged such that if appropriate side-chains were placed there, they would bind the ligand according to a pre-defined geometry of interaction specified by the experimentalist. These binding sites are introduced by the program by taking into account simple rules such as steric hindrance, atomic close-packing and hydrogen bond patterns, which are known to maintain the integrity of a protein structure to a first approximation. A test case is presented in this paper where the copper binding site found in blue-copper proteins such as plastocyanin, azurin and cupredoxin is introduced into Escherichia coli thioredoxin. The model building of one of the solutions found by the program is presented in some detail. The experimental construction and properties of this new protein are described in an accompanying paper. It is hoped that this program provides a general method for the design of ligand binding sites and enzyme active sites, which can then be tested experimentally.