George D. V. van Rossum

Effects of vanadyl sulfate on carbohydrate and lipid metabolism in patients with non-insulin-dependent diabetes mellitus.

The safety and efficacy of vanadyl sulfate (VS) was tested in a single-blind, placebo-controlled study. Eight patients (four men and four women) with non-insulin-dependent diabetes mellitus (NIDDM) received VS (50 mg twice daily orally) for 4 weeks. Six of these patients (four men and two women) continued in the study and were given a placebo for an additional 4 weeks. Euglycemic-hyperinsulinemic clamps were performed before and after the VS and placebo phases. VS was associated with gastrointestinal side effects in six of eight patients during the first week, but was well tolerated after that. VS administration was associated with a 20% decrease in fasting glucose concentration (from 9.3 +/- 1.8 to 7.4 +/- 1.4 mmol/L, P < .05) and a decrease in hepatic glucose output (HGO) during hyperinsulinemia (from 5.0 +/- 1.0 pre-VS to 3.1 +/- 0.9 micromol/kg x min post-VS, P < .02). The improvement in fasting plasma glucose and HGO that occurred during VS treatment was maintained during the placebo phase. VS had no significant effects on rates of total-body glucose uptake, glycogen synthesis, glycolysis, carbohydrate (CHO) oxidation, or lipolysis during euglycemic-hyperinsulinemic clamps. We conclude that VS at the dose used was well tolerated and resulted in modest reductions of fasting plasma glucose and hepatic insulin resistance. However, the safety of larger doses and use of vanadium salts for longer periods remains uncertain.

Ras-dependent Signaling by the GTPase-deficient Mutant of Gα12

Gα12 and Gα13regulate diverse responses through the small GTPases Ras, CDC42, Rac, and Rho. Whereas they activate similar responses in many different cell types, they also activate more specific and critical signaling pathways in other cell types. In COS cells, in which both Gα12 and Gα13 stimulate Na+/H+ exchange, they do so by activating different signaling pathways. Here we report that the differential recruitment of specific small GTPases by Gα12 and Gα13 defines the molecular basis for their functional differences. We have observed that the stimulation of Na+/H+ exchange by the GTPase-deficient mutant of Gα12 (Gα12QL) requires a functional Ras and is independent of Rac/CDC42 and Jun kinase signaling module. By contrast, the stimulation of Na+/H+ exchange by Gα13QL requires a functional Rac/CDC42 and the Jun kinase signaling module. Our results also indicate that Gα12QL-Ras stimulation of Na+/H+ exchange involves a D609-sensitive phospholipase and protein kinase C. These studies, for the first time, describe a novel Gα12-specific signaling pathway involving Ras, phosphatidylcholine hydrolysis, and protein kinase C in the regulation of Na+/H+ exchange.

Effects of Pb2+ added in vitro on Ca2+ movements in isolated mitochondria and slices of rat kidney cortex

We have studied the effects of Pb2+ added in vitro on the movements of Ca2+ in renal cortical mitochondria and tissue slices. The isolated mitochondria rapidly accumulated 45Ca2+ at 25 degrees by a mechanism that was dependent on respiration and inhibited 96% by ruthenium red. A concentration of 10 microM Pb2+ inhibited the Ca2+ accumulation at least as effectively as did ruthenium red. About 20% of the Ca2+ accumulation persisted at 1 degrees with a similar sensitivity to inhibitors, including 60% inhibition by Pb2+. Similar results were obtained when the accumulation of Ca2+ at 25 degrees was measured by means of a calcium-sensitive electrode, Pb2+ inhibiting by 80%. Calcium that had been accumulated by mitochondria at 25 degrees was released completely by the ionophore A23187 or by 10 microM Pb2+. The release induced by Pb2+ was greatly inhibited by ruthenium red. The Ca2+ content of tissue slices of renal cortex increased 4-fold during incubation at 1 degree while the Ca2+ content of mitochondria within the slices more than doubled, the latter being determined by isolation of mitochondria from the slices after incubation. The presence of Pb2+ (200 microM) in the incubation medium of the slices substantially reduced the entry of Ca2+ into the whole slices and into mitochondria within the slices. When the slices preincubated at 1 degree were warmed to 25 degrees in oxygenated medium, they brought about a net extrusion of Ca2+, some of which was derived from the mitochondria; Pb2+ did not alter the final level of Ca2+ then attained in the slices, but it caused a significant decrease in the quantity retained in the mitochondria. We conclude that Pb2+ both inhibits the uptake of Ca2+ by renal cortical mitochondria and displaces Ca2+ from them, these effects occurring whether the mitochondria are isolated or in situ.

Effects of ethacrynic acid on ion transport and energy metabolism in slices of avian salt gland and of mammalian liver and kidney cortex

SummaryEthacrynic acid greatly inhibited net transport of ions and aerobic, energyconserving metabolism in slices of avian salt gland, rat liver, and rat and guinea-pig kidney cortex. The effects of increasing concentrations of ethacrynic acid on the transport of Na+, K+ and Cl− ran closely parallel to its effects on tissue ATP levels and respiration. The concentration needed for maximal inhibition of transport reduced ATP levels by 80–90%. Respiration was reduced by 80–90% in salt gland and kidney cortex, and by a maximum of 30% in liver slices. The effects of low concentrations of ethacrynic acid required time to become fully manifest in some tissues, and the development of transport inhibition followed a similar course to decline of respiration and ATP levels. Ca2+ extrusion by liver cells was inhibited by ethacrynic acid. The concentration dependence of the inhibition was similar to that shown by the other transport systems inhibited. There was no distinction evident between the sensitivity of Na+ extrusion and of K+ accumulation to the diuretic. Lactate production increased as respiration decreased in the presence of increasing concentrations of ethacrynic acid. We conclude that ethacrynic acid acted primarily as an inhibitor of mitochondrial respiration and ATP synthesis in the tissue slices, and that inhibition of ion transport was a nonspecific consequence of the failure of the energy supply.

Uptake of inorganic lead in vitro by isolated mitochondria and tissue slices of rat renal cortex.

Slices of rat renal cortex were shown to take up Pb2+ during incubation in vitro; Pb2+ was also shown to enter mitochondria within the slices. The uptake of Pb2+ by isolated mitochondria was inhibited by N-3, La3+ and ruthenium red. A steady state of uptake was attained within 60 sec. The concentration dependence of uptake was complex; maximum uptake was attained at 25 microM and inhibition ensued at higher concentrations. A substantial inhibitor-resistant component of Pb2+ uptake was noted, especially at medium Pb2+ concentrations greater than 25 microM, and these concentrations also inhibited respiration state 3. The effects on respiration were reduced if the mitochondria had been preincubated with ruthenium red. Slices of renal cortex incubated at 1 degree in medium with various concentrations of Pb2+ showed two fractions of uptake, one saturating at 50-100 microM external Pb2+ and the other at 150-200 microM. Subsequent incubation for 60 min at 25 degrees led to further uptake at all concentrations. Upon isolation of mitochondria from incubated slices, significant amounts of Pb2+ were detected in the mitochondria within 5 min of addition of Pb2+ (200 microM), with maximum attained at 30 min. Electron microscopy of slices showed electron-dense particles, apparently of Pb2+, in the cortical cells but the greatest concentration was deposited in the basement membranes. The results indicate the importance of the basement membrane in limiting access of Pb2+ to cortical cells, and of mitochondria in accumulating Pb2+ once it is in the cells. They also illustrate the importance of interactions between Pb2+ and Ca2+.

Activated mutant of Gα12 enhances the hyperosmotic stress response of NIH3T3 cells

Heterotrimeric G protein G12 stimulates diverse physiological responses including the activities of Na+/H+ exchangers and Jun kinases. We have observed that the expression of the constitutively activated, GTPase‐deficient mutant of Gα12 (Gα12QL) accelerates the hyperosmotic response of NIH3T3 cells as monitored by the hyperosmotic stress‐stimulated activity of JNK1. The accelerated response appears to be partly due to the increased basal activity of JNK since cell lines—such as NIH3T3 cells expressing JNK1—in which JNK activity is elevated, show a similar response. NIH3T3 cells expressing Gα12QL also display heightened sensitivity to hyperosmotic stress. This is in contrast to JNK1–NIH3T3 cells that failed to enhance sensitivity although they do exhibit an accelerated hyperosmotic response. Reasoning that the increased sensitivity seen in Gα12QL cells is due to a signaling component other than JNK, the effect of dimethyamiloride, an inhibitor of Na+/H+ exchanger in this response, was assessed. Treatment of vector control NIH3T3 cells with 50 μM dimethylamiloride potently inhibited their hyperosmotic response whereas the response was only partially inhibited in Gα12QL‐NIH3T3 cells. These results, for the first time, identify that NHEs are upstream of the JNK module in the hyperosmotic stress‐signaling pathway and that Gα12 can enhance this response by modulating either or both of these components namely, JNKs and NHEs in NIH3T3 cells. J. Cell. Biochem. 81:1–8, 2001.

Effects of monensin on ATP levels and cell functions in rat liver and lung in vitro

SummaryEffects of the proton-alkali cation-exchanging ionophore, monensin, on aspects of cellular metabolism and ionic exchanges have been studied in rat tissues in vitro. Incubation of liver slices at 38°C with 0.1 μm monensin induced timedependent vesiculation, initially in the Golgi region, reduction of ATP content and of protein synthesis. At 1 νm, monensin also reduced net, active movements of K+, Na+, Cl− and water in liver slices and inhibited state 3 respiration in isolated mitochondria. The respiratory inhibitor, amytal, similarly reduced ATP content and protein synthesis at concentrations lower than those inhibiting ion transport in slices. Low concentrations of monensin (0.1–1.0 μm) had similar effects on ATP and ion transport in slices of adult lung. By contrast, late-fetal liver and lung were much less sensitive to monensin; in these tissues, glycolysis sustained substantial levels of ATP. Monensin also induced vesiculation of the Golgi apparatus in fetal lung cells. It is concluded that by lowering ATP levels, monensin can markedly alter various metabolic activities in those cells which depend primarily on oxidative phosphorylation for their metabolic energy.

Inhibition of mitochondrial oxidative metabolism by SKF-525a in intact cells and isolated mitochondria

We have examined the effects of various concentrations of SKF-525A (beta-diethylaminoethyldiphenylpropyl acetate X HCl) on the energy metabolism of liver slices, isolated liver mitochondria, and two types of ascites tumor cells, as well as on ion transport in liver slices. In liver slices, 0.2 to 1.0 mM SKF-525A caused an initial stimulation of O2 uptake which was followed, at 0.5 to 1.0 mM, by a progressive inhibition of O2 consumption, a fall of slice ATP content, and a reduced transport of K+, Na+ and Ca2+. In isolated mitochondria, we studied the effects of SKF-525A on the rate of respiration and on the oxidation-reduction responses of NAD(P)+ and cytochrome b in the presence of various substrates. The results suggest that SKF-525A had three distinct actions on liver mitochondria, viz. an uncoupling action at low concentrations (0.02 to 0.17 mM); at higher concentrations (0.2 to 0.5 mM) an inhibition of the oxidation of NAD(P)+-linked substrates, exerted close to the substrate level; also at 0.2 to 0.5 mM, a less effective inhibition of electron transfer at a point between cytochrome b and O2 in the electron-transfer chain. Experiments on O2 consumption and cytochrome b oxidation-reduction changes in ascites cells showed only the first two of these effects in the intact tumor cells. We conclude that inhibition of mitochondrial energy-conserving reactions by SKF-525A can have a marked influence on energy-requiring aspects of liver-cell metabolism, one example of which is inhibition of cation active transport.

Effects of medium calcium, and agents affecting cytoskeletal function, on cellular volume and morphology in liver tissue in vitro

The possible role of an exocytotic, vesicular mechanism in cellular volume regulation under iso‐osmotic conditions has been studied in slices of rat liver. The effects of incubation conditions and agents affecting the actin cytoskeleton were examined for changes of water, ionic composition, and ultrastructure. Slices were pre‐incubated at 1°C in an iso‐osmotic buffered medium to induce swelling. Upon restoration to 37°C in the same medium, tissue lost water. The Na+–K+ adenosine triphosphatase (ATPase) inhibitor ouabain inhibited water extrusion of about 50%, an effect that was accompanied by the formation of characteristic vesicles in the cytoplasmic region between the Golgi apparatus and the bile canaliculi. Water extrusion in the presence of ouabain was partially inhibited by trifluoroperazine and completely inhibited when the medium was free of Ca2+. In the presence of ouabain, brefeldin A caused a small reduction of water extrusion, whereas phalloidin and cytochalasins A, D, or E caused a marked inhibition. In these conditions there was a marked increase in size and number of cytoplasmic vesicles and a more widespread distribution of them within the cells, lacking the more specific orientation to the Golgi and canalicular regions that was seen in the presence of ouabain alone. Water extrusion was inhibited by phalloidin and cytochalasins in the absence of ouabain. In conclusion, our results are consistent with the hypothesis that iso‐osmotic expulsion of water from hepatocytes can proceed partly through an accumulation of water in cytoplasmic vesicles, followed by exocytosis. This mechanism does not depend on Na+–K+ ATPase activity. J. Cell. Biochem. 113: 1915–1925, 2012.

The control of anaerobic glycolysis by glucose transport and ouabain in slices of hepatoma 3924A.

1. The activities of glycolysis and K-+ transport have been studied in slices of Morris hepatoma 3924A incubated under anaerobic conditions in the presence of different concentrations of glucose (1-50 mM). 2. Ouabain-sensitive net transport of K-+ was observed at all glucose concentrations greater than 1 mM; ouabain reduced the rate of glycolysis by about 25% at all glucose concentrations able to support ion transport. 3. The net entry of glucose into the intracellular phase was studied at varying glucose concentrations. The rate of glucose entry was similar to the rate of glucose utilisation by anaerobic glycolysis at medium concentrations of 10 mM and less, but exceeded the rate of glycolysis at 20 mM and above. 4. The glucose entry was not Na-+-dependent and was not inhibited by ouabain. 5. The results suggest (a) that the reduction in glycolytic activity caused by ouabain is not due to an inhibition of glucose transport and (b) that the glucose transport system of this poorly differentiated hepatoma has properties similar to that of normal liver.