Robert S. Phillips

Temperature modulation of the stereochemistry of enzymatic catalysis: Prospects for exploitation

The use of physical variables to control the stereochemical outcome of enzymecatalysed reactions is of great interest in biocatalysis. The effects of temperature on stereochemistry were not understood and fully appreciated until recently. This article indicates how temperature can influence the stereochemistry of enzymatic reactions, and reviews the prospects for future applications of temperature modulation of the stereochemical course of enzymatic reactions.

A redox-active FKBP-type immunophilin functions in accumulation of the photosystem II supercomplex in Arabidopsis thaliana

Photosystem II (PSII) catalyzes the first of two photosynthetic reactions that convert sunlight into chemical energy. Native PSII is a supercomplex consisting of core and light-harvesting chlorophyll proteins. Although the structure of PSII has been resolved by x-ray crystallography, the mechanism underlying its assembly is poorly understood. Here, we report that an immunophilin of the chloroplast thylakoid lumen is required for accumulation of the PSII supercomplex in Arabidopsis thaliana. The immunophilin, FKBP20-2, belongs to the FK-506 binding protein (FKBP) subfamily that functions as peptidyl-prolyl isomerases (PPIases) in protein folding. FKBP20-2 has a unique pair of cysteines at the C terminus and was found to be reduced by thioredoxin (Trx) (itself reduced by NADPH by means of NADP-Trx reductase). The FKBP20-2 protein, which contains only two of the five amino acids required for catalysis, showed a low level of PPIase activity that was unaffected on reduction by Trx. Genetic disruption of the FKBP20-2 gene resulted in reduced plant growth, consistent with the observed lower rate of PSII activity determined by fluorescence (using leaves) and oxygen evolution (using isolated chloroplasts). Analysis of isolated thylakoid membranes with blue native gels and immunoblots showed that accumulation of the PSII supercomplex was compromised in mutant plants, whereas the levels of monomer and dimer building blocks were elevated compared with WT. The results provide evidence that FKBP20-2 participates specifically in the accumulation of the PSII supercomplex in the chloroplast thylakoid lumen by means of a mechanism that has yet to be determined.

Recent advances in alcohol dehydrogenase-catalyzed asymmetric production of hydrophobic alcohols

The efficiency of biocatalytic redox reactions catalyzed by alcohol dehydrogenases (ADHs) have been the subject of considerable research recently. Two major challenges have restricted their application in asymmetric synthesis until now. First of all, most of the interesting substrates are either insoluble or sparingly soluble in aqueous media, the natural medium for enzymes. This drawback has been overcome by using non-aqueous media like organic solvents, ionic liquids, and supercritical carbon dioxide in mono- and biphasic reactions, and several ADHs show high activity at high concentrations of such reaction media. The second challenge is the strict substrate specificity for most ADHs. The continuous search for new ADHs, together with random and rational mutagenesis to widen substrate specificity, will help in attracting organic chemists to consider utilizing them in organic synthesis more often. The aim of this perspective is to highlight recent efforts to overcome the above-mentioned limitations.

A Single Point Mutation Reverses the Enantiopreference of Thermoanaerobacter ethanolicus Secondary Alcohol Dehydrogenase

Alcohol dehydrogenases (ADHs) are enzymes that catalyze the reversible reduction of carbonyl compounds to their corresponding alcohols. It is beyond doubt that they are important biocatalysts in asymmetric synthesis. Recent reports have shown that it is possible to use a number of ADHs for synthetic applications in nonaqueous media with high activities, which make them attractive choices to organic chemists. The stereopreferences of ADHs can be predicted by Prelog’s rule (Figure 1), which depends on the relative sizes of the two

Investigation of the role of 3-hydroxyanthranilic acid in the degradation of lignin by white-rot fungus Pycnoporus cinnabarinus.

An aminophenol, 3-hydroxyanthranilic acid (3-HAA), has been proposed to play important roles in lignin degradation. Production of 3-HAA in Pycnoporus cinnabarinus was completely inhibited by a combination of tryptophan and S-(2-aminophenyl)-L-cysteine S,S-dioxide (APCD) while the fungus grew well and produced high amounts of laccase. The biosynthesis of 3-HAA is mainly through the metabolism of tryptophan in the kynurenine pathway. A minor pathway for 3-HAA synthesis is through the hydroxylation of anthranilic acid during the biosynthesis of tryptophan in the shikimic acid pathway. Through UV irradiation of wild-type P. cinnabarinus (WT-Pc) spores, a 3-HAA-less mutant was produced. Both WT-Pc, under the inhibitory culture condition, and the 3-HAA-less mutant were found to degrade lignin in unbleached kraft pulp as efficiently as the WT-Pc, which unambiguously demonstrated that 3-HAA does not play an important role in the fungal degradation of lignin.

Mutation of cysteine-295 to alanine in secondary alcohol dehydrogenase from Thermoanaerobacter ethanolicus affects the enantioselectivity and substrate specificity of ketone reductions.

The mutation of Cys-295 to alanine in Thermoanaerobacter ethanolicus secondary alcohol dehydrogenase (SADH) was performed to give C295A SADH, on the basis of molecular modeling studies utilizing the X-ray crystal structure coordinates of the highly homologous T. brockii secondary alcohol dehydrogenase (1YKF.PDB). This mutant SADH has activity for 2-propanol comparable to wild-type SADH. However, the C295A mutation was found to cause a significant shift of enantioselectivity toward the (S)-configuration in the reduction of some ethynylketones to the corresponding chiral propargyl alcohols. This result confirms our prediction that Cys-295 is part of a small alkyl group binding pocket whose size determines the binding orientation of ketone substrates, and, hence, the stereochemical configuration of the product alcohol. Furthermore, C295A SADH has much higher activity towards t-butyl and some alpha-branched ketones than does wild-type SADH. The C295A mutation does not affect the thioester reductase activity of SADH. The broader substrate specificity and altered stereoselectivity for C295A SADH make it a potentially useful tool for asymmetric reductions.

Structure and mechanism of tryptophan indole-lyase and tyrosine phenol-lyase.

Tyrosine phenol-lyase (TPL) and tryptophan indole-lyase (Trpase) catalyse the reversible hydrolytic cleavage of L-tyrosine or L-tryptophan to phenol or indole, respectively, and ammonium pyruvate. These enzymes are very similar in sequence and structure, but show strict specificity for their respective physiological substrates. We have mutated the active site residues of TPL (Thr(124), Arg(381), and Phe(448)) to those of Trpase and evaluated the effects of the mutations. Tyr(71) in Citrobacter freundii TPL, and Tyr(74) in E. coli Trpase, are essential for activity with both substrates. Mutation of Arg(381) of TPL to Ala, Ile, or Val (the corresponding residues in the active site of Trpase) results in a dramatic decrease in L-Tyr beta-elimination activity, with little effect on the activity of other substrates. Arg(381) may be the catalytic base with pK(a) of 8 seen in pH-dependent kinetic studies. T124D TPL has no measureable activity with L-Tyr or 3-F-L-Tyr as substrate, despite having high activity with SOPC. T124A TPL has very low but detectable activity, which is about 500-fold less than wild-type TPL, with L-Tyr and 3-F-L-Tyr. F448H TPL also has very low activity with L-Tyr. None of the mutant TPLs has any detectable activity with L-Trp as substrate. H463F Trpase also exhibits low activity with L-Trp, but retains high activity with other substrates. Thus, additional residues remote from the active site may be needed for substrate specificity. Both Trpase and TPL may react by a rare S(E)2-type mechanism.

The Role of the Catalytic Base in the Protein Tyrosine Kinase Csk

A potential distinguishing feature between protein tyrosine kinases and homologous serine/threonine kinases is the function of the catalytic base in these enzymes. In this study, we show that a peptide containing the unnatural amino acid trifluorotyrosine shows remarkably similar efficiency as a substrate of the tyrosine kinase Csk (C-terminal Src kinase) compared with the corresponding tyrosine-containing peptide despite a 4-unit change in the phenolic pKa. These results argue against the importance of early tyrosine deprotonation by a catalytic base in Csk. To further explore the role of the proposed catalytic base, the Csk mutant protein D314E was produced. This mutant displayed a significant reduction in km (approximately 104) but relatively little effect on substrate Km values compared with wild-type Csk. Examination of the thio effect (km-ATP/km-adenosine 5′-O-(thiotriphosphate)) for D314E Csk led to the suggestion that a role of aspartate 314 may be to enhance the reactivity of the γ-phosphate of ATP toward electrophilic attack. These results may have significant impact on protein tyrosine kinase inhibitor design.

Reactions of O-acyl-L-serines with tryptophanase, tyrosine phenol-lyase, and tryptophan synthase.

The reactions of tryptophanase, tyrosine phenol-lyase, and tryptophan synthase with a new class of substrates, the O-acyl-L-serines, have been examined. A method for preparation of O-benzoyl-L-serine in high yield from tert.-butyloxycarbonyl (tBoc)-L-serine has been developed. Reaction of the cesium salt of tBoc-L-serine with benzyl bromide in dimethylformamide gives tBoc-L-serine benzyl ester in excellent yield. Acylation with benzoyl chloride and triethylamine in acetonitrile followed by hydrogenolysis with 10% palladium on carbon in trifluoroacetic acid gives O-benzoyl-L-serine, isolated as the hydrochloride salt. O-Benzoyl-L-serine is a good substrate for beta-elimination or beta-substitution reactions catalyzed by both tryptophanase and tyrosine phenol-lyase, with Vmax values 5- to 6-fold those of the physiological substrates and comparable to that of S-(o-nitrophenyl)-L-cysteine. Unexpectedly, O-acetyl-L-serine is a very poor substrate for these enzymes, with Vmax values about 5% of those of the physiological substrates. Both O-acyl-L-serines are poor substrates for tryptophan synthase, measured either by the synthesis of 5-fluoro-L-tryptophan from 5-fluoroindole and L-serine catalyzed by the intact alpha 2 beta 2 subunit or by the beta-elimination reaction catalyzed by the isolated beta 2 subunit. With all three enzymes, the elimination of benzoate appears to be irreversible. These results suggest that the binding energy from the aromatic ring of O-benzoyl-L-serine is used to lower the transition-state barrier for the elimination reactions catalyzed by tryptophanase and tyrosine phenol-lyase. Our findings support the suggestion (M. N. Kazarinoff and E. E. Snell (1980) J. Biol. Chem. 255, 6228-6233) that tryptophanase undergoes a conformational change during catalysis and suggest that tyrosine phenol-lyase also may undergo a conformational change during catalysis.

Activity and selectivity of W110A secondary alcohol dehydrogenase from Thermoanaerobacter ethanolicus in organic solvents and ionic liquids: mono- and biphasic media

The asymmetric reduction of hydrophobic phenyl-ring-containing ketones and the enantiospecific kinetic resolution of the corresponding racemic alcohols catalyzed by Thermoanaerobacter ethanolicus W110A secondary alcohol dehydrogenase were performed in mono- and biphasic systems containing either organic solvents or ionic liquids. Both yield and enantioselectivity for these transformations can be controlled by changing the reaction medium. The enzyme showed high tolerance to both water-miscible and -immiscible solvents, which allows biotransformations to be conducted at high substrate concentrations.