The residue I415 in pyruvate decarboxylase from Saccharomyces cerevisiae was substituted with a variety of uncharged side chains of varying steric requirements to test the hypothesis that this residue is responsible for supporting the V coenzyme conformation reported for this enzyme [Arjunan et al. (1996) J. Mol. Biol. 256, 590-600]. Changing the isoleucine to valine and threonine decreased the kcat value and shifted the kcat-pH profile to more alkaline values progressively, indicating that the residue at position 415 not only is important for providing the optimal transition state stabilization but also ensures correct alignment of the ionizable groups participating in catalysis. Substitutions to methionine (the residue used in pyruvate oxidase for this purpose) or leucine (the corresponding residue in transketolase) led to greatly diminished kcat values, showing that for each thiamin diphosphate-dependent enzyme an optimal hydrophobic side chain evolved to occupy this key position. Computational studies were carried out on the wild-type enzyme and the I415V, I415G, and I415A variants in both the absence and the presence of pyruvate covalently bound to C2 of the thiazolium ring (the latter is a model for the decarboxylation transition state) to determine whether the size of the side chain is critically required to maintain the V conformation. Briefly, there are sufficient conformational constraints from the binding of the diphosphate side chain and three conserved hydrogen bonds to the 4'-aminopyrimidine ring to enforce the V conformation, even in the absence of a large side chain at position 415. There appears to be increased coenzyme flexibility on substitution of Ile415 to Gly in the absence compared with the presence of bound pyruvate, suggesting that entropy contributes to the rate acceleration. The additional CH3 group in Ile compared to Val also provides increased hydrophobicity at the active center, likely contributing to the rate acceleration. The computational studies suggest that direct proton transfer to the 4'-imino nitrogen from the thiazolium C2H is eminently plausible.
Restricted
by their molecular structure defects, poly(methylphenylsiloxanes) usually
exhibit a relatively low thermal stability, thus limiting their application in high-temperature areas. In this paper, we introduce a cost-effective
synthesis method to prepare poly(methylphenylsiloxanes) (PPMS-M) with
methyl–phenyl mixed cyclic monomers as raw materials. The molecular
structure characterization shows that PPMS-M contain abundant phenyl
groups, and the phenylsiloxane units are evenly distributed among
methylsiloxane segments. The thermal degradation kinetics are systematically
studied with the Flynn–Wall–Ozawa method. It shows that
PPMS-M exhibits much higher degradation activation energy than ordinary
poly(methylphenylsiloxanes) (PPMS-PD) does, which is prepared by 2,4,6-trimethyl-2,4,6-triphenylcyclotrisiloxane
(P3) and octamethylcyclotetrasiloxane (D4).
The thermogravimetry–Fourier transform infrared characterization
shows that the degradation process of the phenyl group in PPMS-M occurs
at temperatures of 100–200 °C higher than those for PPMS-PD.
PPMS-M exhibits good thermal stability and a low glass transition
temperature. Our method would be applied to cost-effective synthesis of other
high-performance functional polysiloxanes.
A new class of compounds, the 2-oxo-3-alkynoic acids with a phenyl substituent at carbon 4 was reported by the authors as potent irreversible and mechanism-based inhibitors of the thiamin diphosphate- (ThDP-) dependent enzyme pyruvate decarboxylase [Chiu, C.-F., & Jordan, F. (1994) J. Org. Chem. 59, 5763-5766]. The method has been successfully extended to the synthesis of the 4-, 5-, and 7-carbon aliphatic members of this family of compounds. These three compounds were then tested on three ThDP-dependent pyruvate decarboxylases: the Escherichia coli pyruvate dehydrogenase multienzyme complex (PDHc) and its E1 (ThDP-dependent) component, pyruvate oxidase (POX, phosphorylating; from Lactobacillus plantarum),and pyruvate decarboxylase (PDC) from Saccharomycescerevisiae. All three enzymes were irreversibly inhibited by the new compounds. The 4-carbon acid is the best substrate-analog inactivator known to date for PDHc, more potent than either fluoropyruvate or bromopyruvate. The following conclusions were drawn from extensive studies with PDHc: (a) The kinetics of inactivation of PDH complexes and of resolved E1 by 2-oxo-3-alkynoic acids is time- and concentration-dependent. (b) The 4-carbon acid has a Ki 2 orders of magnitude stronger than the 5-carbon acid, clearly demonstrating the substrate specificity of PDHc. (c) The rate of inactivation of PDH complexes and of resolved E1 by 2-oxo-3-alkynoic acids is enhanced by the addition of ThDP and MgCl2. (d) Pyruvate completely protects E1 and partially protects PDHc from inactivation by 2-oxo-3-butynoic acid. (e) E1 but not E2-E3 is the target of inactivation by 2-oxo-3-butynoic acid. (f) Inactivation of E1 by 2-oxo-3-butynoic acid is accompanied by modification of 1.3 cysteines/E1 monomer. The order of reactivity with the 4-carbon acid was PDHc > POX > PDC. While the order of reactivity with PDHc and POX was 2-oxo-3-butynoic acid > 2-oxo-3-pentynoic acid > 2-oxo-3-heptynoic acid, the order of reactivity was reversed with PDC.
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