Glucose and pyruvate metabolism in preimplantation blastocysts from normal and diabetic rats

Abstract

Glucose metabolism was analysed in day-5 rat blastocysts incubated in the presence of [5-3H]-, [6-14C]- or [U-14C]glucose. Glycolysis, quantified by 3H2O recovery rate, was the main pathway of glucose utilization by fresh (11.5 ± 0.36 pmol per embryo h-1) or cultured (24 h) blastocysts (20.4 ± 0.6 pmol per embryo h-1). Glucose consumption rate was almost saturated at a medium glucose concentration of 0.28 mmol l-1 (K(m): 0.17 mmol l-1; V(max): 23 pmol per embryo h-1). A further 10% increase in glucose utilization was obtained with a tenfold higher glucose concentration (3 mmol l-1). Phloretin completely abolished the rapid component of glucose utilization kinetics, suggesting the existence of a Na+-independent glucose transport system. Less than 1% of [6-14C]glucose consumed by cultured blastocysts was oxidized through the Krebs cycle. [1-14C]pyruvate, however, was oxidized at a rate of 2 pmol per embryo h-1 by fresh blastocysts. The pentose-phosphate pathway accounted for about 2% of glucose utilization. One to two per cent of the total glucose metabolized in 24 h was retained in macromolecules. Insulin had no effect on glucose uptake, utilization, incorporation and turnover, or on pyruvate oxidation. Blastocysts from diabetic mothers utilized glucose at a rate similar to that of normal blastocysts. These results show that glucose is actively taken up by rat blastocysts and utilized mainly through the Embden-Meyerhof pathway, which is rapidly saturated at low glucose concentrations. Retention of glucose-derived products in macromolecules, although relatively small, may modulate the effect of high glucose concentrations on embryo growth. The lack of effect of insulin on the main metabolic pathways of glucose metabolism does not rule out a more discrete insulin effect at some molecular levels.