Andrzej Witkowski scite author profile

For the linear triatomic X–H··· system, the separability of the X–H stretching vibrations from the hydrogen bond vibrations is analyzed in the spirit of the adiabatic approximation. The adiabatic wavefunctions for X–H stretching vibrations are shown to be suitable functions for the evaluation of the principal factors determining the infrared spectral properties of the actual species of carboxylic acid dimers and imidazole crystal. Theoretical infrared spectra in the X–H stretching region of these systems are then obtained and compared with the experimental ones. The quantitative reconstitution of the experimental spectra and, in particular, the predictions for the effect of isotopic substitution of H by D are confirmed. The principal features of the unusual spectral properties of the X–H stretching vibrations in hydrogenbonded systems seem therefore to result from a somewhat peculiar coupling mechanism suggested in the theory.

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Structure and molecular organization of mammalian fatty acid synthase

Asturias

Chadick

Cheung

et al. 2005

Nat Struct Mol Biol

148

121

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De novo synthesis of fatty acids in the cytosol of animal cells is carried out by the multifunctional, homodimeric fatty acid synthase (FAS). Cryo-EM analysis of single FAS particles imaged under conditions that limit conformational variability, combined with gold labeling of the N termini and structural analysis of the FAS monomers, reveals two coiled monomers in an overlapping arrangement. Comparison of dimeric FAS structures related to different steps in the fatty acid synthesis process indicates that only limited local rearrangements are required for catalytic interaction among different functional domains. Monomer coiling probably contributes to FAS efficiency and provides a structural explanation for the reported activity of a FAS monomer dimerized to a catalytically inactive partner. The new FAS structure provides a new paradigm for understanding the architecture of FAS and the related modular polyketide synthases.

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Mechanism of the β-Ketoacyl Synthase Reaction Catalyzed by the Animal Fatty Acid Synthase

Witkowski¹,

Joshi²,

Smith³

2002

Biochemistry

107

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The catalytic mechanism of the beta-ketoacyl synthase domain of the multifunctional fatty acid synthase has been investigated by a combination of mutagenesis, active-site titration, product analysis, and product inhibition. Neither the reactivity of the active-site Cys161 residue toward iodoacetamide nor the rate of unidirectional transfer of acyl moieties to Cys161 was significantly decreased by replacement of any of the conserved residues, His293, His331, or Lys326, with Ala. Decarboxylation of malonyl moieties in the fully-active Cys161Gln background generated equimolar amounts of acetyl-CoA and bicarbonate, rather than carbon dioxide, and was seriously compromised by replacement of any of the conserved basic residues. The ability of bicarbonate to inhibit decarboxylation of malonyl moieties in the Cys161Gln background was significantly reduced by replacement of His293 but less so by replacement of His331. The data are consistent with a reaction mechanism, in which the initial primer transfer reaction is promoted largely through a lowering of the pKa of the Cys161 thiol by a helix dipole effect and activation of the substrate thioester carbon atom by binding of the keto group in an oxyanion hole. The data also indicate that an activated water molecule is present at the active site that is required either for the rapid hydration of carbon dioxide, prior its release as bicarbonate or, alternatively, for an initial attack on the malonyl C3. In the alternative mechanism, a negatively-charged tetrahedral transition state could be generated, stabilized in part by interaction of His293 with the negatively charged oxygen at C3 and interaction of His331 with the negatively charged thioester carbonyl oxygen, that breaks down to generate bicarbonate directly. Finally, the carbanion at C2, attacks the electrophilic C1 of the primer, generating a second tetrahedral transition state, also stabilized through contacts with the oxyanion hole and His331, that breaks down to form the beta-ketoacyl-S-acyl carrier protein product.

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