Holotranscobalamins in B12 and non B12 requiring prokaryotes and eukaryotes

Cyanocobalamin (vitamin B12) conjugates with enhanced solubility

Cyanocobalamin (vitamin B12) is an essential nutrient as well as a very useful carrier in drug delivery. Conjugates of vitamin B12 are investigated due to their wide range of therapeutic applications. We report the synthesis of six vitamin B12 conjugates, and the effect of conjugation on their solubilities and stabilities in various media. We reveal here that vitamin B12 can be released readily if a 2'-hydroxyl group is conjugated rather than the 5'-hydroxyl group, and the solubility (thus the equivalents of vitamin B12) could be enhanced as much as 19-fold, by simple conjugates such as glycolates. Findings disclosed here provide insights into the reactivities of vitamin B12 conjugates, the design of future prodrugs and similar conjugated moieties using vitamin B12.

Cobalamin (vitamin B12) and holotranscobalamin changes in plasma and liver tissue in alcoholics with liver disease

OBJECTIVE

We wanted to know if alterations in plasma cobalamin (B12) concentration and B12 carriers, e.g., holotranscobalamins (holo TC), occur in blood and liver tissue from patients with severe alcoholic liver disease. Our purpose was to test the hypothesis that liver disease may disrupt B12 distribution.

METHOD

Total B12, as well as B12 bound to transcobalamin I, II, III (holo TC), were measured to determine their concentration in plasma and in liver tissue; Poteriochromonas malhamensis--a protozoan reagent served to measure only metabolically active (true) B12. Total B12 as distributed in holo TC in plasma and liver tissue of healthy subjects (controls) were compared to patients with severe alcoholic liver disease.

RESULTS

Severe liver disease initiates highly elevated B12 levels in plasma and a lowered liver tissue total B12 concentration. The percent of B12 distributed to holo TC II is significantly depleted during liver disease. In contrast, holo TC I and III are elevated in plasma during liver disease and contain more B12 than controls. Total B12 and B12 distributed to TC are lower in diseased liver tissue.

CONCLUSION

Severe alcoholic liver disease involves leakage of total B12 from liver tissue into the plasma. Holo TC I and III concentration increases in plasma; this preserves the high plasma B12 from being excreted. However, plasma holo TC II B12 distribution is decreased, indicating that there is a depression of exogenous B12 entering the plasma and tissues. In severe liver disease, liver tissue B12 binding and storage by TC is disrupted and causes B12 to leak out of the liver into the circulation. Eventually liver disease could produce enough severe tissue B12 deficits to cause metabolic dysfunction despite elevated plasma total B12. Elevation of plasma B12, accompanied by a lowering of holo TC II distribution, seemed to be a useful index of liver disease severity suggesting preventive treatment.