Michael T. Ashby scite author profile

Cysteine sulfenic acid has been generated in alkaline aqueous solution by oxidation of cysteine with hypohalous acid (HOX, X = Cl or Br). The kinetics and mechanisms of the oxidation reaction and the subsequent reactions of cysteine sulfenic acid have been studied by stopped-flow spectrophotometry between pH 10 and 14. Two reaction pathways were observed: (1) below pH 12, the condensation of two sulfenic acids to give cysteine thiosulfinate ester followed by the nucleophilic attack of cysteinate on cysteine thiosulfinate ester and (2) above pH 10, a pH-dependent fast equilibrium protonation of cysteine sulfenate that is followed by rate-limiting comproportionation of cysteine sulfenic acid with cysteinate to give cystine. The observation of the first reaction suggests that the condensation of cysteine sulfenic acid to give cysteine thiosulfinate ester can be competitive with the reaction of cysteine sulfenic acid with cysteine.

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Redox Buffering of Hypochlorous Acid by Thiocyanate in Physiologic Fluids

Ashby

2004

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The major antimicrobial products of neutrophilic myeloperoxidase (MPO) in physiologic fluids are hypochlorous acid (HOCl) and hypothiocyanite (OSCN-), and the former is generally believed to be the killing agent. However, we have determined that HOCl oxidizes SCN- in a facile nonenzymic reaction. The observed kinetics and computational models substantiate the hypothesis that SCN- serves to moderate the potential autotoxicity of HOCl by restricting its lifetime in physiologic fluids. Furthermore, the oxidizing equivalents of HOCl are preserved in OSCN-, a more discriminate biocide that is not lethal to mammalian cells.

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Catabolite Control Protein A Controls Hydrogen Peroxide Production and Cell Death inStreptococcus sanguinis

et al. 2011

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Streptococcus sanguinis is a commensal oral bacterium producing hydrogen peroxide (H 2 O 2 ) that is dependent on pyruvate oxidase (Spx) activity. In addition to its well-known role in bacterial antagonism during interspecies competition, H 2 O 2 causes cell death in about 10% of the S. sanguinis population. As a consequence of H 2 O 2 -induced cell death, largely intact chromosomal DNA is released into the environment. This extracellular DNA (eDNA) contributes to the self-aggregation phenotype under aerobic conditions. To further investigate the regulation of spx gene expression, we assessed the role of catabolite control protein A (CcpA) in spx expression control. We report here that CcpA represses spx expression. An isogenic ⌬ccpA mutant showed elevated spx expression, increased Spx abundance, and H 2 O 2 production, whereas the wild type did not respond with altered spx expression in the presence of glucose and other carbohydrates. Since H 2 O 2 is directly involved in the release of eDNA and bacterial cell death, the presented data suggest that CcpA is a central control element in this important developmental process in S. sanguinis.

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Kinetics and mechanism of catalysis of the asymmetric hydrogenation of .alpha.,.beta.-unsaturated carboxylic acids by bis(carboxylato) {2,2'-bis(diphenylphosphino)-1,1'-binaphthyl}ruthenium(II), [RuII(BINAP) (O2CR)2]

Ashby¹,

Halpern²

1991

J. Am. Chem. Soc.

161

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Inorganic Chemistry of Defensive Peroxidases in the Human Oral Cavity

Ashby

2008

J Dent Res

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The innate host response system is comprised of various mechanisms for orchestrating host response to microbial infection of the oral cavity. The heterogeneity of the oral cavity and the associated microenvironments that are produced give rise to different chemistries that affect the innate defense system. One focus of this review is on how these spatial differences influence the two major defensive peroxidases of the oral cavity, salivary peroxidase (SPO) and myeloperoxidase (MPO). With hydrogen peroxide (H2O2) as an oxidant, the defensive peroxidases use inorganic ions to produce antimicrobials that are generally more effective than H2O2 itself. The concentrations of the inorganic substrates are different in saliva vs. gingival crevicular fluid (GCF). Thus, in the supragingival regime, SPO and MPO work in unison for the exclusive production of hypothiocyanite (OSCN−, a reactive inorganic species), which constantly bathes nascent plaques. In contrast, MPO is introduced to the GCF during inflammatory response, and in that environment it is capable of producing hypochlorite (OCl−), a chemically more powerful oxidant that is implicated in host tissue damage. A second focus of this review is on inter-person variation that may contribute to different peroxidase function. Many of these differences are attributed to dietary or smoking practices that alter the concentrations of relevant inorganic species in the oral cavity ( e.g.: fluoride, F−; cyanide, CN−; cyanate, OCN−; thiocyanate, SCN−; and nitrate, NO3−). Because of the complexity of the host and microflora biology and the associated chemistry, it is difficult to establish the significance of the human peroxidase systems during the pathogenesis of oral diseases. The problem is particularly complex with respect to the gingival sulcus and periodontal pockets (where the very different defensive stratagems of GCF and saliva co-mingle). Despite this complexity, intriguing in vitro and in vivo studies are reviewed here that reveal the interplay between peroxidase function and associated inorganic chemistry.

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Destabilizing d.pi.-p.pi. orbital interactions and the alkylation reactions of iron(II)-thiolate complexes

Ashby¹,

Enemark²,

Lichtenberger³

1988

Inorg. Chem.

100

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Cl, CF3, N02) the -type interaction between formally occupied metal d orbitals and the sulfur lone pair that is principally 3p in character has been modeled with Fenske-Hall molecular orbital calculations and experimentally investigated by gas-phase photoelectron spectroscopy. A calculation for 1 (R = H) predicts that the highest occupied molecular orbital (HOMO) is metal-sulfur antibonding and largely sulfur in character. The observed HOMO ionization energies of 1 correlate with several chemical properties, including the rate of reaction of the thiolate ligand with alkyl halides. Solvent and substituent effects on the reaction rate favor a mechanism involving nucleophilic displacement of the halide by the coordinated thiolate ligand. The nucleophilicity of the coordinated thiolate ligand of 1 is related to the metal-sulfur d -p antibonding interactions.

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Synthesis and molecular structure of an iminophosphide/phosphinoamide anion: [Li(PhN-PPh2)(OEt2)]2

Ashby¹,

Zhong²

1992

Inorg. Chem.

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Lactoperoxidase-Catalyzed Oxidation of Thiocyanate by Hydrogen Peroxide: A Reinvestigation of Hypothiocyanite by Nuclear Magnetic Resonance and Optical Spectroscopy

2006

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In an effort to reconcile conflicting reports regarding the spectra of the human defense factor hypothiocyanite (OSCN(-)), we have synthesized OSCN(-) by three methods and characterized the product spectroscopically. Method I is lactoperoxidase-catalyzed oxidation of SCN(-) by H(2)O(2) at pH 7. Method II is hydrolysis of (SCN)(2) at pH 13. Method III is oxidation of SCN(-) by OX(-) (X = Cl and Br) at pH 13. All three methods produced essentially the same initial UV, (13)C NMR, and (15)N NMR spectra. The UV spectrum reveals a lambda(max) of 376 nm, which is a previously unreported distinguishing feature. The (13)C NMR spectrum (delta = 127.8 ppm at pH 13 vs dioxane at 66.6 ppm) is comparable to those that have been previously reported for OSCN(-) as prepared by methods I and II (although in some cases different assignments have been made). However, the (15)N NMR spectrum we measure (delta = -80.6 ppm at pH 13 vs NO(3)(-) at 0 ppm) contrasts with previous reports. We conclude that all three methods produce the same species, and the spectra are now self-consistent with the formulation OSCN(-).

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Michael T. Ashby

Reactive Sulfur Species: Kinetics and Mechanisms of the Oxidation of Cysteine by Hypohalous Acid to Give Cysteine Sulfenic Acid

Redox Buffering of Hypochlorous Acid by Thiocyanate in Physiologic Fluids

Catabolite Control Protein A Controls Hydrogen Peroxide Production and Cell Death inStreptococcus sanguinis

Kinetics and mechanism of catalysis of the asymmetric hydrogenation of .alpha.,.beta.-unsaturated carboxylic acids by bis(carboxylato) {2,2'-bis(diphenylphosphino)-1,1'-binaphthyl}ruthenium(II), [RuII(BINAP) (O2CR)2]

Inorganic Chemistry of Defensive Peroxidases in the Human Oral Cavity

Destabilizing d.pi.-p.pi. orbital interactions and the alkylation reactions of iron(II)-thiolate complexes

Synthesis and molecular structure of an iminophosphide/phosphinoamide anion: [Li(PhN-PPh2)(OEt2)]2

Lactoperoxidase-Catalyzed Oxidation of Thiocyanate by Hydrogen Peroxide: A Reinvestigation of Hypothiocyanite by Nuclear Magnetic Resonance and Optical Spectroscopy

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