Although mouse oocytes and cleavage-stage embryos are unable to utilize glucose as a metabolic fuel, they have a specific requirement for a short exposure to glucose prior to compaction. The reason for this requirement has been unclear. In this study we confirm that cleavage-stage exposure to glucose is required for blastocyst formation and show that the absence of glucose between 18-64 h after hCG causes an irreversible decrease in cellular proliferation and an increase in apoptosis. More importantly, this glucose signals to activate expression of Slc2a3 transcript and SLC2A3 protein, a facilitative glucose transporter (previously known as GLUT3) associated with developmental competence and increased glucose uptake used to fuel blastocyst formation. Glucosamine could substitute for glucose in these roles, suggesting that hexosamine biosynthesis may be a nutrient-sensing mechanism involved in metabolic differentiation. Inhibition of the rate-limiting enzyme in this pathway, glutamine-fructose-6-phosphate amidotransferase (GFPT), inhibited expression of the SLC2A3 transporter protein and blastocyst formation. Glucosamine, a substrate that enters this pathway downstream of GFPT, was able to overcome this inhibition and support SLC2A3 expression. These data suggest that early embryos rely on hexosamine biosynthesis as a glucose-sensing pathway to initiate metabolic differentiation.
To examine possible regulatory roles of liver and kidney in cobalamin metabolism, specific activities of the two cobalamin-dependent enzymes, uptake in vivo of cyano [57Co]cobalamin [( 57Co]CNCbl) and the binding of [57Co]Cbl to intracellular proteins were measured in normal, cobalamin-loaded and cobalamin-deficient rats. Cobalamin deficiency and cobalamin loading produced greater changes in cobalamin concentration in the kidney than in the liver. Although cobalamin deficiency resulted in a decrease in total methylmalonyl-coenzyme A mutase (methylmalonyl-CoA mutase) in both organs, cobalamin loading had no effect. Neither deficiency nor loading altered total methyltransferase activity. The holoenzyme activities of both enzymes correlated with changes in tissue cobalamin levels. Uptake of [57Co]Cbl indicated that the kidney, in contrast to the liver, increased its uptake during loading and reduced it during deficiency, suggesting a possible regulatory role for this organ. In the normal rat, 24 h after injection of [57Co]CNCbl, 0.3% of the administered [57Co]Cbl was present in the liver as free cobalamin. By contrast, in the kidney, over 13% of the [57Co]Cbl was present in the free form. During deficiency free renal [57Co]Cbl was reduced to 0.6% of the administered [57Co]Cbl whereas in cobalamin-loaded rats it was increased to more than 27%. It is concluded that alterations in tissue cobalamin levels resulting from differences in cobalamin supply are due to changes in the large pool of free cobalamin present in the kidney and not to changes in the intracellular binding.
Binding of cobalamin (Cbl) was compared in liver and kidney plasma membranes prepared from rat and human tissues. Single, high-affinity, saturable (200 pmol/l), binding sites for TC II-Cbl were found in all tissues; by contrast no receptors were present for free cobalamin, for which only non-specific adsorption occurred. Binding constants for TC II-CNCbl determined for liver and kidney plasma membranes were of a similar magnitude. Mean values for Ka (litre/nmol) were 16.7 (rat liver), 18.8 (rat kidney), 8.0 (human liver) and 7.5 (human kidney). Results for binding TC II-OHCbl instead of TC II-CNCbl showed no difference in Ka and Bmax. values, although the non-specific adsorption was decreased to a third. Competitive inhibition results showed that the receptors are specific for the TC II molecule and that binding is unaffected either by the cobalamin moiety or by the presence of free cobalamin. Degradation of the receptor protein molecules by trypsin (10 micrograms/ml) resulted in 90% inhibition of binding. It is concluded that differences between liver and kidney in cobalamin uptake and accumulation cannot be attributed to differences in their TC II receptors.
The effect of cobalamin deficiency on whole body cobalamin content and its turnover was examined in the rat. Quantitative and qualitative changes in hepatic cobalamin were also followed and the effect of deficiency on the turnover of this cobalamin was determined in the isolated perfused liver. As cobalamin deficiency developed after total gastrectomy, whole body cobalamin content declined at a constant rate, indicating no attempt to conserve total body cobalamin stores even when depleted (5% of normal). In contrast, the cobalamin concentration of liver declined more slowly, indicating conservation of hepatic cobalamin. Furthermore, the methylcobalamin (MeCbl) content of liver was maintained or even increased. Measurement of the rate of release of cobalamin by the isolated perfused liver at varying times after gastrectomy showed that as depletion of whole body and hepatic cobalamin stores proceeded, the rates of release of hepatic cobalamin into plasma and bile decreased. Regression analysis showed that the fractional rates of release of hepatic cobalamin into plasma (r = 0.9, P less than 0.001, n = 15) and bile (r = 0.65, P less than 0.01, n = 15) were significantly correlated with hepatic cobalamin content. It is concluded that conservation of hepatic cobalamin in deficiency is achieved, at least in part, by a specific decrease in the rate of release of hepatic cobalamin.
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