Shengying Zhou scite author profile

Breakdown of lipid peroxides results in the formation of aldehydic compounds which are toxic to biological systems and deleterious to food quality. To determine the potential of skeletal muscle compounds to protect biomolecules from lipid oxidation products, the ability of carnosine and various other related compounds to quench monounsaturated and polyunsaturated aldehydes was investigated. Carnosine, the most abundant dipeptide in skeletal muscle, is capable of quenching alpha,beta-monounsaturated aldehydes and 4-hydroxy-2-trans-nonenal (HNE) more effectively than its constituent amino acid. Carnosine (5 mM) reduced 44% of headspace trans-2-hexenal (0.5 mM) after 1 h incubation at 40 degrees C and pH 7.4. Other histidine-containing dipeptides and the amine compounds, spermine and spermidine, had similar or slightly lower quenching activity than carnosine. Glutathione and thioctic acid had superior quenching ability than carnosine, but their overall contribution to aldehyde quenching compared to carnosine is limited due to their lower concentration in skeletal muscle. The results suggest that carnosine could be important for decreasing the toxicity of lipid oxidation products in biological systems and for minimizing rancidity in muscle foods.

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Adipocytes and lipid distribution in the muscle tissue of Atlantic salmon (Salmo salar)

Zhou¹,

Ackman²,

Morrison³

1996

Can. J. Fish. Aquat. Sci.

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Altered Hydrophobicity and Membrane Composition in Stress-Adapted Listeria innocua

Moorman

Thelemann

Zhou

et al. 2008

Journal of Food Protection

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Exposure of Listeria innocua to acid and starvation stress decreases sensitivity to the quaternary ammonium compound cetrimide, whereas exposure to cold and heat stress increases sensitivity to this compound. Changes in membrane lipids occur in response to certain types of stress, and these changes likely impact cell sensitivity to chemical sanitizers. The present study included an assessment of the effects of acid, starvation, cold, and heat stress on net cell hydrophobicity and fatty acid composition in L. innocua. Net cell hydrophobicity was determined by measuring absorbance of stress-adapted cell suspensions after partitioning with the nonpolar solvent n-hexadecane. Free fatty acids extracted from stress-adapted suspensions were analyzed by gas chromatography. Adaptation to acid and starvation increased net cell hydrophobicity and decreased membrane fluidity, which was correlated with reductions in anteiso fatty acids and in ratios of anteiso to iso fatty acids. Conversely, cold-stressed populations exhibited decreased net cell hydrophobicity and increased membrane fluidity with a corresponding increase in C15:C17 and anteiso:iso ratios and in C18 unsaturated fatty acids. No significant changes in net cell hydrophobicity or membrane fluidity were observed in heat-stressed cells, which exhibited increased sensitivity to cetrimide, suggesting another mechanism for altered cell sensitivity. These findings indicate that the efficacy of cetrimide against Listeria is partially dependent on the physiological state of the organism following exposure to various environmental stresses.

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Ability of Amino Acids, Dipeptides, Polyamines, and Sulfhydryls To Quench Hexanal, a Saturated Aldehydic Lipid Oxidation Product

Zhou

Decker

1999

J. Agric. Food Chem.

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Hexanal is a common product arising from the oxidation of omega-6 fatty acids. Because aldehydic lipid oxidation products can react with food components, interactions between hexanal and sulfhydryl- and amine-containing compounds were determined. The polyamines, spermidine and spermine, and the sulfhydryl-containing compounds, glutathione and thioctic acid, decreased headspace hexanal concentrations < or =7.0%. Histidine was the only amino acid tested that was able to quench headspace hexanal. Histidine-containing dipeptides decreased headspace hexanal 3.0-8.5-fold more than histidine. Hexanal quenching by the hisitidine-containing dipeptides increased as the size of the aliphatic side group of the amino acid adjacent to histidine increased, with Leu-His having the greatest hexanal quenching activity. The ability of Leu-His to quench histidine increased with increasing pH. The ability of histidine-containing dipeptides to interact with hexanal suggests that it may be possible to design peptides to alter the concentration of saturated aldehydes in oxidizing lipids.

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Identification of Hydrazine in Commercial Preparations of Carnosine and Its Influence on Carnosine's Antioxidative Properties

Zhou¹,

Dickinson²,

Li³

et al. 1998

Analytical Biochemistry

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Shengying Zhou

Ability of Carnosine and Other Skeletal Muscle Components To Quench Unsaturated Aldehydic Lipid Oxidation Products

Adipocytes and lipid distribution in the muscle tissue of Atlantic salmon (Salmo salar)

Altered Hydrophobicity and Membrane Composition in Stress-Adapted Listeria innocua

Ability of Amino Acids, Dipeptides, Polyamines, and Sulfhydryls To Quench Hexanal, a Saturated Aldehydic Lipid Oxidation Product

Identification of Hydrazine in Commercial Preparations of Carnosine and Its Influence on Carnosine's Antioxidative Properties

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