William N. Chia

Rational construction of a 2-hydroxyacid dehydrogenase with new substrate specificity

Using site-directed mutagenesis on the lactate dehydrogenase gene from Bacillus stearothermophilus, three amino acid substitutions have been made at sites in the enzyme which we suggest in part determine specificity toward different hydroxyacids (R-CHOH-COOH). To change the preferred substrates from the pyruvate/lactate pair (R = -CH3) to the oxaloacetate/malate pair (R = -CH2-COO-), the volume of the active site was increased (thr 246----gly), an acid was neutralized (asp-197----asn) and a base was introduced (gln-102 - greater than arg). The wild type enzyme has a catalytic specificity for pyruvate over oxaloacetate of 1000 whereas the triple mutant has a specificity for oxaloacetate over pyruvate of 500. Despite the severity and extent of these active site alterations, the malate dehydrogenase so produced retains a reasonably fast catalytic rate constant (20 s-1 for oxaloacetate reduction) and is still allosterically controlled by fructose-1,6-bisphosphate.

Regulatory elements involved in the tissue-specific expression of the yellow gene of Drosophila

SummaryWe have assessed the DNA sequence requirements for the correct spatial pattern and phenotypic expression of y in the late embryo/larvae. The wild-type larval phenotype requires both the regions between-294 bp and-92 bp and a portion of the intron; the sequence element(s) located within the intron can act in a position independent manner to effect the wild-type larval phenotype. The larval expression pattern was examined by tissue experiments in situ and by staining germline transformants derived from various y/lacZ fusion constructs. The larval expression of y is restricted to the mouthparts, microsetae and anal plates. While the-495 bp to+194 bp region alone cannot effect a wild-type larval expression pattern, this region in conjunction with the intron appears to be sufficient to drive β-gal expression in an essentially wild-type pattern. Our data further suggest that the-294 bp to-92 bp region contains elements which specify the larval pattern and that the element(s) in the intron normally act to enhance the level of expression necessary for the wild-type larval phenotype. We also present a phenotypic analysis of the adult cuticle structures of germline transformants derived from a variety of deletion and rearrangement constructs of the y gene. This analysis has revealed several new features associated with the regulation of y expression.

The use of a genetically engineered tryptophan to identify the movement of a domain of B. stearothermophilus lactate dehydrogenase with the process which limits the steady-state turnover of the enzyme

A general technique for monitoring the intramolecular motion of a protein is described. Genetic engineering is used to replace all the natural tryptophan residues with tyrosine. A single tryptophan residue is then inserted at a specific site within the protein where motion is then detected from the fluorescence characteristics of this fluorophore. This technique has been used in B. stearothermophilus lactate dehydrogenase mutant (W80Y, W150Y, W203Y, G106W) to correlate the slow closure of a surface loop of polypeptide (residues 98-110) with the maximum catalytic velocity of the enzyme.

A strong carboxylate-arginine interaction is important in substrate orientation and recognition in lactate dehydrogenase

Using site-directed mutagenesis, Arginine-171 at the substrate-binding site of Bacillus stearothermophilus, lactate dehydrogenase has been replaced by lysine. In the closely homologous eukaryotic lactate dehydrogenase, this residue binds the carboxylate group of the substrate by forming a planar bifurcated bond. The mutation diminishes the binding energy of pyruvate, alpha-ketobutyrate and alpha-ketovalerate (measured by kcat/Km) by the same amount (about 6 kcal/mol). For each additional methylene group on the substrate, there is a loss of about 1.5 kcal/mol of binding energy in both mutant and wild-type enzymes. From these parallel trends in the two forms of enzyme, we infer that the mode of productive substrate binding is identical in each, the only difference being the loss of a strong carboxylate-guanidinium interaction in the mutant. In contrast to this simple pattern in kcat/Km, the Km alone increases with substrate-size in the wild-type enzyme, but decreases in the mutant. These results can be most simply explained by the occurrence of relatively tight unproductive enzyme-substrate complexes in the mutant enzyme as the substrate alkyl chain is extended. This does not occur in the wild-type enzyme, because the strong orienting effect of Arg-171 maximizes the frequency of substrates binding in the correct alignment.

The engineering of a more thermally stable lactate dehydrogenase by reduction of the area of a water-accessible hydrophobic surface

A site-directed mutant of Bacillus stearothermophilus lactate dehydrogenase (lactate:NAD+ oxidoreductase, EC 1.1.1.27) has been engineered in which the conserved hydrophobic residue isoleucine-250 has been replaced by the more hydrophilic residue asparagine. This isoleucine forms a large part of a water-accessible, hydrophobic surface in the active site of the apo-enzyme which is covered by the B-face of the nicotinamide ring when coenzymes are bound. Reduction in the area of this hydrophobic surface results in the mutant tetramer being more thermally stable than the wild-type enzyme.

The importance of arginine 171 in substrate binding by Bacillus stearothermophilus lactate dehydrogenase.

A variant of lactate dehydrogenase from Bacillus stearothermophilus has been engineered by site-directed mutagenesis in which an active-site arginine residue at position 171 in the protein sequence is replaced by lysine. Replacement of this arginine by lysine has no effect on co-enzyme binding, a relatively small effect on the rate of turnover of the enzyme, but causes a 2000-fold increase in the Michaelis constant for pyruvate, a 6000-fold increase in the dissociation constant for oxamate and results in a Michaelis constant for lactate which is too high to measure. The decrease in binding energy for these carboxylate-containing substrates caused by this mutation is very large, around 5.5 kcal.mol-1 and in part, is explained by the small increase in the distance of a lysine-substrate carboxylate interaction at this site and the absence of the additional hydrogen bond from a two-point arginine-carboxylate interaction. Consistent with this last observation, the ability of this mutant enzyme to stabilize an NAD+-sulphite compound in its active site (an alternative enzyme-substrate complex which does not involve bifurcated bonding to arginine) is only reduced 14-fold.

A single amino acid substitution deregulates a bacterial lactate dehydrogenase and stabilizes its tetrameric structure

We have engineered a variant of the lactate dehydrogenase enzyme from Bacillus stearothermophilus in which arginine-173 at the proposed regulatory site has been replaced by glutamine. Like the wild-type enzyme, this mutant undergoes a reversible, protein-concentration-dependent subunit assembly, from dimer to tetramer. However, the mutant tetramer is much more stable (by a factor of 400) than the wild type and is destabilized rather than stabilized by binding the allosteric regulator, fructose 1,6-biphosphate (Fru-1,6-P2). The mutation has not significantly changed the catalytic properties of the dimer (Kd NADH, Km pyruvate, Ki oxamate and kcat), but has weakened the binding of Fru-1,6-P2 to both the dimeric and tetrameric forms of the enzyme and has almost abolished any stimulatory effect. We conclude that the Arg-173 residue in the wild-type enzyme is directly involved in the binding of Fru-1,6-P2, is important for allosteric communication with the active site, and, in part, regulates the state of quaternary structure through a charge-repulsion mechanism.

The use of site-directed mutagenesis and time-resolved fluorescence spectroscopy to assign the fluorescence contributions of individual tryptophan residues in Bacillus stearothermophilus lactate dehydrogenase

Site-directed mutagenesis has been used to generate two mutant Bacillus stearothermophilus lactate dehydrogenases: in one, Trp-150 has been replaced with a tyrosine residue and, in the other, both Trp-150 and -80 are replaced with tyrosines. Both enzymes are fully catalytically active and their affinities for substrates and coenzymes, and thermal stabilities are very similar to those of the native enzyme. Time-resolved fluorescence measurements using a synchrotron source have shown that all three tryptophans in the native enzyme fluoresce. By comparing the mutant and native enzymes it was possible, for the first time, to assign, unambiguously, lifetimes to the individual tryptophans: Trp-203 (7.4 ns), Trp-80 (2.35 ns) and Trp-150 (less than 0.3 ns). Trp-203 is responsible for 75-80% of the steady-state fluorescence emission, Trp-80 for 20%, and Trp-150 for less than 2%.

Expression of the copy DNA for human A4 and B4 l-lactate dehydrogenases in Escherichia coli

The human LDH-A and LDH-B cDNAs, containing the coding regions for the L-lactate dehydrogenase A4 (M) and B4 (H) polypeptides respectively have been cloned into Escherichia coli to place the cDNAs under the control of hybrid E. coli/Bacillus stearothermophilus transcriptional and translational signals. Human A4- and B4-isoenzymes are produced in E. coli cells harbouring the expression plasmids pHLDHA22 and pHLDHB10 at levels of 6.5 and 1.5% of the soluble protein of the cell, respectively. The tac promoter of these vectors was not induced by isopropyl beta-D-thiogalactopyranoside. The A4 and B4 human isoenzymes synthesized in E. coli were purified to homogeneity and show the same properties as isoenzymes isolated from human tissue. The amino acid sequences of 12 N-terminal residues of the human isoenzymes synthesized in E. coli were determined to be identical to those deduced from the DNA sequence of the cloned cDNAs except that the N-terminal methionine was absent from both. However, in contrast to LDH made in human cells, acetylation of the N-terminal alanine does not take place in E. coli cells.