Stuart Smith scite author profile

Background and Aim: Reduction of short-chain poorly absorbed carbohydrates (FODMAPs) in the diet reduces symptoms of irritable bowel syndrome (IBS). In the present study, we aimed to compare the patterns of breath hydrogen and methane and symptoms produced in response to diets that differed only in FODMAP content. Methods: Fifteen healthy subjects and 15 with IBS (Rome III criteria) undertook a single-blind, crossover intervention trial involving consuming provided diets that were either low (9 g/day) or high (50 g/day) in FODMAPs for 2 days. Food and gastrointestinal symptom diaries were kept and breath samples collected hourly over 14 h on day 2 of each diet. Results: Higher levels of breath hydrogen were produced over the entire day with the high FODMAP diet for healthy volunteers (181 Ϯ 77 ppm.14 h vs 43 Ϯ 18; mean Ϯ SD P < 0.0001) and patients with IBS (242 Ϯ 79 vs 62 Ϯ 23; P < 0.0001), who had higher levels during each dietary period than the controls (P < 0.05). Breath methane, produced by 10 subjects within each group, was reduced with the high FODMAP intake in healthy subjects (47 Ϯ 29 vs 109 Ϯ 77; P = 0.043), but was not different in patients with IBS (126 Ϯ 153 vs 86 Ϯ 72). Gastrointestinal symptoms and lethargy were significantly induced by the high FODMAP diet in patients with IBS, while only increased flatus production was reported by healthy volunteers. Conclusions: Dietary FODMAPs induce prolonged hydrogen production in the intestine that is greater in IBS, influence the amount of methane produced, and induce gastrointestinal and systemic symptoms experienced by patients with IBS. The results offer mechanisms underlying the efficacy of the low FODMAP diet in IBS.

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The animal fatty acid synthase: one gene, one polypeptide, seven enzymes

Smith¹

1994

FASEB j.

548

458

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The animal fatty acid synthase comprises two multifunctional polypeptide chains, each containing seven discrete functional domains, juxtaposed head-to-tail such that two separate centers for fatty acid assembly are formed at the subunit interface. The kinetics and specificities of the component enzymes are well adapted to ensure that, at each of the two centers, the iterative condensation of an acetyl moiety with successive malonyl moieties and complete reduction of the beta-keto intermediates normally results in the formation of palmitic acid as the major product. Nevertheless, utilization of alternative substrates and alternative chain-terminating mechanisms can extend the range of products to include branched-chain, odd carbon-numbered, and shorter chain-length fatty acids. The potential of this multifunctional form of molecular architecture for the elaboration of more complex natural products has been further exploited in microorganisms that, by the use of different fatty acid synthase "modules" that perform variable beta-carbon processing at successive elongation steps, generate a structurally diverse family of polyketides retaining keto, hydroxyl, enoyl, or alkyl functions at specific positions in the carbon chain.

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Structural and functional organization of the animal fatty acid synthase

Smith¹,

Witkowski²,

Joshi³

2003

Progress in Lipid Research

554

419

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The type I fatty acid and polyketide synthases: a tale of two megasynthases

2007

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This review chronicles the synergistic growth of the fields of fatty acid and polyketide synthesis over the last century. In both animal fatty acid synthases and modular polyketide synthases, similar catalytic elements are covalently linked in the same order in megasynthases. Whereas in fatty acid synthases the basic elements of the design remain immutable, guaranteeing the faithful production of saturated fatty acids, in the modular polyketide synthases, the potential of the basic design has been exploited to the full for the elaboration of a wide range of secondary metabolites of extraordinary structural diversity.

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ACC/AHA/ACP–ASIM Guidelines for the Management of Patients With Chronic Stable Angina: Executive Summary and Recommendations

Gibbons¹,

Chatterjee²,

Daley³

et al. 1999

Circulation

351

141

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Mechanism and Substrate Recognition of Human Holo ACP Synthase

Bunkóczi¹,

Pasta²,

Joshi³

et al. 2007

Chemistry & Biology

130

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SummaryMammals utilize a single phosphopantetheinyl transferase for the posttranslational modification of at least three different apoproteins: the carrier protein components of cytosolic and mitochondrial fatty acid synthases and the aminoadipate semialdehyde reductase involved in lysine degradation. We determined the crystal structure of the human phosphopantetheinyl transferase, a eukaryotic phosphopantetheinyl transferase characterized, complexed with CoA and Mg2+, and in ternary complex with CoA and ACP. The involvement of key residues in ligand binding and catalysis was confirmed by mutagenesis and kinetic analysis. Human phosphopantetheinyl transferase exhibits an α/β fold and 2-fold pseudosymmetry similar to the Sfp phosphopantetheinyl transferase from Bacillus subtilis. Although the bound ACP exhibits a typical four-helix structure, its binding is unusual in that it is facilitated predominantly by hydrophobic interactions. A detailed mechanism is proposed describing the substrate binding and catalytic process.

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Insulin acutely decreases hepatic fatty acid synthase activity

et al. 2005

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Insulin is viewed as a positive regulator of fatty acid synthesis by increasing fatty acid synthase (FAS) mRNA transcription. We uncover a new mechanism by which insulin acutely reduces hepatic FAS activity by inducing phosphorylation of the carcinoembryonic antigen-related cell adhesion molecule 1 (CEACAM1) and its interaction with FAS. Ceacam1 null mice (Cc1(-/-)) show loss of insulin's ability to acutely decrease hepatic FAS activity. Moreover, adenoviral delivery of wild-type, but not the phosphorylation-defective Ceacam1 mutant, restores the acute effect of insulin on FAS activity in Cc1(-/-) primary hepatocytes. Failure of insulin to acutely reduce hepatic FAS activity in hyperinsulinemic mice, including L-SACC1 transgenics with liver inactivation of CEACAM1, and Ob/Ob obese mice, suggests that the acute effect of insulin on FAS activity depends on the prior insulinemic state. We propose that this mechanism acts to reduce hepatic lipogenesis incurred by insulin pulses during refeeding.

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Structure and molecular organization of mammalian fatty acid synthase

Asturias

Chadick

Cheung

et al. 2005

Nat Struct Mol Biol

145

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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Stuart Smith

Manipulation of dietary short chain carbohydrates alters the pattern of gas production and genesis of symptoms in irritable bowel syndrome

The animal fatty acid synthase: one gene, one polypeptide, seven enzymes

Structural and functional organization of the animal fatty acid synthase

The type I fatty acid and polyketide synthases: a tale of two megasynthases

ACC/AHA/ACP–ASIM Guidelines for the Management of Patients With Chronic Stable Angina: Executive Summary and Recommendations

Mechanism and Substrate Recognition of Human Holo ACP Synthase

Insulin acutely decreases hepatic fatty acid synthase activity

Structure and molecular organization of mammalian fatty acid synthase

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