In vitro stimulation of microsomal diethyl nitrosamine deethylase activity by vitamin K3 (menadione).

Vitamin K3 (menadione) has been found to stimulate diethyl nitrosamine (DEN)-deethylase activity in rat liver microsomes. The vitamin also takes care of the inhibitory effect of the anaerobic conditions as well as those of cytochrome poisons like sodium azide and sodium cyanide, possibly through production of active oxygen species. The enzyme was also stimulated by H2O2 and SOD and inhibited by catalase, thereby suggesting that H2O2 or some derivatives of it may be the active oxygen species involved in the reaction.

Effect of riboflavin or pyridoxine deficiency on inflammatory response.

Inflammatory response has been assessed in riboflavin or pyridoxine deficient rats. Edema was increased by 54% in pyridoxine deficiency as compared to weight-matched control rats. Food restriction per se reduced the volume of edema by 63%. In pyridoxine deficiency, concentrations of thiobarbituric acid reactive substances (which indicate the extent of lipid peroxidation) increase by 30 and 43% respectively in the edematous tissues of the paw as well as in the wounded skin. Both these parameters were not affected by riboflavin deficiency. Activities of NADPH oxidase and superoxide dismutase in elicited leukocytes from peritoneal cavity were reduced by 54 and 52%, respectively, in riboflavin deficiency but were unaltered in pyridoxine deficiency. Superoxide level and acid phosphatase activity were not influenced by either of the deficiencies, whereas hydrogen peroxide level was increased by 48% in riboflavin deficiency. Food restriction did not affect leukocyte enzymes or the levels of reduced oxygen species. The data suggest that inflammation is enhanced in pyridoxine deficiency but not in riboflavin deficiency.

Mechanism of impaired skin collagen maturity in riboflavin or pyridoxine deficiency.

To elucidate the biochemical basis of impaired skin collagen maturity in pyridoxine-or riboflavin-deficient rats the following two mechanistic possibilities were tested: (i) Reduction in the activity of skin lysyl oxidase (EC 1·4·3·13) which initiates the cross-linking of collagen and (ii) putative rise in homocysteine level leading to neutralization of allysine (α-aminoadipic acid δ-5-semialdehyde)or hydroxyallysine (hydroxy α-aminoadepic acid (δ-semialdehyde) in collagen by the formation of thiazine complexes. Skin lysyl oxidase activity was not affected in pyridoxine deficiency suggesting that pyridoxal phosphate may not be its cofactor. In riboflavin deficiency, lysyl oxidase activity was not altered in the newly regenerated rat skin but a slight reduction was observed in the skin of 18-day-old rat pups. This could be related to the body weight deficit rather than deficiency per se. Aldehyde content of purified salt soluble collagen of regenerated skin was significantly reduced in both the deficiencies. A 2 to 4-fold increase in the concentration of skin homocysteine was observed in both the deficiencies. The results suggest that increase in skin homocysteine level may be responsible for the impaired skin collagen maturity in riboflavin or pyridoxine deficiency.