Vitamin B-6 metabolism in the blood of young adult and senescent mice

Pyridoxal-5'-phosphate and pyridoxal biokinetics in aging Wistar rats

Biokinetic parameters of plasma pyridoxal-5'-phosphate (PLP) and pyridoxal (PL) disposition were studied in male Wistar rats aged 8 and 27 months kept from weaning on a purified diet containing 250 g casein and 6 mg pyridoxine.HCl per kg. Baseline plasma PLP concentration was lower in the older animals (514 +/- 56 nmol/L for young and 317 +/- 124 nmol/L for old animals), whereas baseline plasma PL concentration did not differ between age groups (average 235 nmol/L for both young and old animals). We hypothesized lower baseline plasma PLP in the older animals was caused by an increased PLP elimination rate, a decreased PLP synthesis rate, or a combination of these processes. Observations from earlier in vitro experiments suggest age-related changes occur in vitamin B-6 metabolizing enzyme activities. In the in vivo experiments described here no age-related difference in plasma PLP elimination rate nor in plasma PLP synthesis rate was observed to explain the observed decrease in plasma PLP concentration with age.

Concentration of vitamin B6 and activities of enzymes of B6 metabolism in the blood of alcoholic and nonalcoholic men

The purpose of this study was to compare concentrations of vitamin B6 compounds and the activities of enzymes that synthesize or catabolize pyridoxal 5'-phosphate in the plasma and erythrocytes of nonalcoholic and alcoholic subjects. Blood was obtained from male nonalcoholics and chronic alcoholics with minimal liver damage and normal hematology. Plasma, erythrocyte, and urinary B6 compounds were analyzed by high performance liquid chromatography, and pyridoxal phosphate was also measured enzymatically. Erythrocyte pyridoxine kinase and pyridoxine phosphate oxidase and erythrocyte and plasma pyridoxine phosphate phosphatases were assayed. Plasma pyridoxal phosphate concentration was significantly lower in the alcoholics (31.3 +/- 3.6 nmol/liter) than in the nonalcoholics (58.7 +/- 7.5 nmol/liter). The concentrations of the other B6 compounds in plasma, erythrocytes, and urine were not different in the two groups. Plasma alkaline pyridoxine phosphate phosphatase activity was significantly higher in the alcoholics (4.05 +/- 0.36 nmol/(h.mg] than in the nonalcoholics (3.01 +/- 0.18 nmol/(h.mg]. The activities of erythrocyte kinase, oxidase, and phosphatases were not significantly different in the two groups. The relationship of plasma pyridoxal phosphate concentration to its metabolites and the activities of the enzymes involved in its metabolism was determined. Plasma pyridoxine phosphate phosphatase activity assayed at pH 9.0 or 7.4 correlated negatively with plasma pyridoxal phosphate concentration. The low pyridoxal phosphate concentration observed in the plasma of the alcoholic subjects may in part be related to increased plasma phosphatase activity.

Pyridoxamine (pyridoxine) phosphate oxidase activity in mammalian tissues

1. Vitamin B6-sufficient rats had moderate pyridoxamine-P oxidase specific activities in heart, brain, kidney and liver, but no detectable activity in skeletal muscle. Vitamin B6-deficiency in rats resulted in a decreased oxidase activity in liver but no change in the activities in other tissues. 2. The pyridoxamine-P oxidase activity in vitamin B6-sufficient mice was high in liver, moderate in brain and kidney, and not measurable in skeletal muscle and heart. Vitamin B6-deficient, compared with control mice, had decreased oxidase activities in brain, kidney and liver. 3. Mouse erythrocytes took up pyridoxine more rapidly than did rat and human erythrocytes. 4. Mouse and human erythrocytes rapidly converted pyridoxine to pyridoxal-P. Rat, hamster and rabbit erythrocytes had appreciably lower pyridoxamine-P oxidase activity than did mouse and human erythrocytes.