The turnover of rat-liver folate pools

Folylpolyglutamate synthesis and role in the regulation of one-carbon metabolism

The physiological importance of folylpolyglutamates is now well established. These derivatives are the intracellular substrates and regulators of one-carbon metabolism, and their synthesis is required for normal folate retention by tissues. Over the last few years, a considerable amount of information has been obtained on the mechanism by which these compounds are synthesized, on how this synthesis is regulated, and on the effects of the polyglutamate chain on the interaction of folate substrates and inhibitors with folate-dependent enzymes. Many regulatory implications have been suggested by these studies, but the physiological relevance of some of these observations remains to be explored. Folates in mammalian tissues are metabolized to polyglutamates of chain lengths considerably longer than that required for folate retention, but the metabolic advantages of this are not entirely clear. Several in vivo model systems have been developed to explore the functioning of specific folylpolyglutamate chain lengths in metabolic cycles of one-carbon metabolism, and these are likely to shed further light on this point. The role of folate-binding proteins in folate transport, the metabolic role of glutamylhydrolases, and the role of folylpolyglutamates in putative multifunctional protein complexes are also areas that are being actively pursued at present and are likely to produce new insights in the future. Recent studies on the retention of antifolates by cells and on their substrate efficacy for folylpolyglutamate synthetases have also suggested mechanisms for the differential cytotoxicity of these agents for different tissues.

Folate pentaglutamate and folate hexaglutamate mediated one-carbon metabolism

The proposal that folate polyglutamate cofactors of different chain lengths function differently in metabolism was investigated. We identified the one-carbon units present in rat liver folates within each of the liver folate polyglutamate groups, the folate penta-, hexa-, and heptaglutamates. This identification revealed that at the pentaglutamate level, 5-methyl-H4folate was the major form, accounting for 18% of the total liver folates, with small amounts of H4folate. At the hexaglutamate level, 5-methyl-H4folate and H4folate were major forms, accounting for 17% and 22% of the liver folates, respectively. At the heptaglutamate level, 5-methyl-H4folate occurred in small amounts while H4folate predominated. The rats used here had been fed a diet low in methionine and were exposed to N2O gas. These results are qualitatively similar to those from rat brain [Brody, T., Shin, Y. S., & Stokstad, E. L. R. (1976) J. Neurochem. 27, 409--413] where 5-methyl-H4folate was a major fraction of the folate pentaglutamates but a minor, if detectable, part of the hexa- and heptaglutamates. The folates 5-methyl-H4PteGlu5-7 were metabolically active in the liver, as illustrated by the severe contraction in the amounts of these folates following an injection of methionine. This indicates that "folate-binding proteins" do not prevent 5-methyl-H4folates from entering into one-carbon metabolism.

The effect of diet and alcohol on the development of folate deficiency in the rat

Studies of the rate of depletion of serum and tissue methylated and non-methylated folates were carried our in rats maintained for long periods on either a folate deficient (sucrose-water/sulphathiazole) diet or a deficient diet plus high alcohol intake. By means of implantation of a feeding gastrostomy tube, it was possible to sustain constant blood ethanol levels of between 50 and 300 mg/dl for 3-4 weeks with relatively normal calorie intake and without death of the animal. Using this animal model, which closely resembles severe alcoholism in man, a very rapid depression in serum 5-methyl tetrahydrofolate was observed similar to that reported in alcoholic man. At the same time, release of folates from liver stores was umimpaired by alcohol ingestion. Liver folate store depletion rates were identical for alcoholic and folate starved animals. The explanation for the sudden alcohol suppression of serum folate levels must, therefore, be sought at a point in the internal metabolic sequences of folate other than the delivery of folate stores to plasma.