Selective stimulation of in situ intermediary metabolism by free calcium in permeabilized rat adipocytes

Inhibition of acetyl CoA carboxylase by GTP gamma S

The effect of nonhydrolyzable guanine nucleotides on mammalian acetyl CoA carboxylase (ACC) activity was examined. Using porous rat adipocytes and crude fat cell homogenates to study metabolic pathway flux, GMPPNP and/or GTP gamma S inhibited [14C]fatty acid formation by up to 95% when either [6-14C]glucose-6-phosphate or [1-14C]acetyl CoA was used as substrate. If [2-14C]malonyl CoA initiated flux, however, no inhibition was apparent. These pathway flux studies suggested that ACC was the locus of inhibition, and that the mechanism might involve a disruption of guanine nucleotide hydrolysis by the nonhydrolyzable analogues. Using partially and avidin-sepharose-purified ACC preparations from rat fat, liver and mammary tissue, citrate-stimulated ACC activity was inhibited by 25-75% with 50 microM GTP gamma S. Related compounds and nucleotides had absent-to-minimal effects on ACC. ATP gamma S was inhibitory (10-30% at 5-15 microM), but always to a lesser degree than equimolar GTP gamma S. Filter binding assays with [alpha-32P]GTP or [35S]GTP gamma S were negative, but low-level GTPase activity was detected. Using photoaffinity labelling techniques, [alpha-32P]GTP was found to bind ACC and not pyruvate carboxylase. The hypothesis that citrate-responsive ACC activity may be modulated by an intrinsic or associated GTP binding site is explored. Since ACC forms polymers, as does the cytoskeletal protein beta-tubulin, amino acid sequence comparisons between ACC and atypical GTP binding domain of beta tubulin are presented.

Persistence of disturbed adipocyte metabolism in streptozocin-induced diabetic rats despite near-euglycemia with phlorizin

It is widely accepted that hyperglycemia per se incites and perpetuates the diabetic state by adverse effects on beta cell insulin secretion and peripheral insulin action. Examination of the latter locus has revealed glucose-related abnormalities in facilitated glucose transport. Beyond the plasma membrane, however, there is scant data examining whether hyperglycemia influences important intracellular metabolic events. We recently described a sizable reduction in post-transport, in situ metabolism in permeabilized fat cells from streptozocin-induced diabetic rats. Of importance, the diabetes-related deficit was entirely ameliorated by insulin therapy. In this study we examined whether hyperglycemia per se contributes to this altered intracellular metabolic effect. By infusing phlorizin, near euglycemia was achieved for at least four days in streptozocin-induced diabetic rats. The phlorizin-treated diabetic rats had improved (intact cell) rates of insulin-stimulated 2-deoxyglucose uptake. Despite this, permeabilized fat cell studies revealed no improvement or deterioration in diabetic intracellular metabolism as measured by both the oxidation of [6-14C]glucose-6-phosphate via the citric acid cycle or its incorporation into triglyceride. We conclude that hypoinsulinemia, and not hyperglycemia, mediates the disturbance in porous diabetic adipocyte cellular metabolism.

Activation of in situ glycolytic flux by bisphosphorylated compounds: studies in porous rat adipocytes

By carefully permeabilizing eukaryotic cells such that intracellular enzymes are largely retained, an opportunity is created to explore the regulation of in situ flux. This is particularly important since the latter may not be accurately represented by kinetic measurements of isolated, solubilized enzymes from disrupted cells. In this study the action of fructose 2,6-diphosphate (F2,6DP) and other bisphosphorylated sugars which purportedly activate phosphofructokinase-1 (PFK-1; EC 2.7.1.11) were studied. Using porous adipocytcs and initiating flux with radiolabeled glucose 6-phosphate, the regulation of lactate production under both 0.1 and 1.0 mM ATP conditions by F2,6DP, glucose 1,6-diphosphate (G1,6DP), ribulose 1,5-diphosphate (R1,5DP), 2,3 diphosphoglycerate (2,3DPG), and mannose 6-phosphate (M6P) was examined. Studied at 1, 5, and 25 microM concentrations, F2,6DP and 2,3DPG significantly (and to the same extent) augmented glycolysis compared to control (at 0.1 mM ATP, the respective glycolytic rates--as % above control--at these three above-mentioned concentrations for F2,6DP were 60, 84, and 77%, whereas for 2,3DPG they were 84, 105, and 179%; at 1 mM ATP, the F2,6DP effect was 88, 99, and 121%, and for 2,3DPG it was 52, 89, and 96%). Stimulation by these compounds was less obvious at higher glycolytic flux rates (saturating amounts of G6P). Amongst this group, and only at 1.0 mM ATP, the sole other positive effector was 25 microM R1,5DP. The measured fat cell content of G1,6DP was 24 +/- 4 microM (n = 3); at this concentration no significant effect on glycolysis was observed. Examining the effects of 2,3DPG (25 microM) on proximal glycolysis (to triose phosphates) revealed there was a modest, but significant, 41% increase over basal; in contrast, under the exact same conditions, F2,6DP caused a 123% increase. Separate experiments also examined the effect of F2,6DP, 2,3DPG, and G1,6DP on glycolysis at 5 and 25 microM in the presence of a physiologic cytosolic ATP/ADP ratio and free cation concentrations. Under these conditions, F2,6DP and 2,3DPG remained pre-eminent in their stimulatory prowess, inducing 27-71% increases over control, while G1,6DP remained ineffectual. These studies support a locus of action of 2,3DPG on overall glycolysis which is distal to the triose phosphates. M6P was ineffective at all concentrations. In conclusion, F2,6DP is the pre-eminent in situ regulator of in situ adipocyte glycolysis, especially at higher ATP levels, although other sugars containing two phosphoryl groups may under certain conditions cause activation.