Debra C. Henly

Intracellular mitochondrial membrane potential as an indicator of hepatocyte energy metabolism: Further evidence for thermodynamic control of metabolism

The lipophilic triphenylmethylphosphonium cation (TPMP+) has been employed to measure delta psi m, the electrical potential across the inner membrane of the mitochondria of intact hepatocytes. The present studies have examined the validity of this technique in hepatocytes exposed to graded concentrations of inhibitors of mitochondrial energy transduction. Under these conditions, TPMP+ uptake allows a reliable measure of delta psi m in intracellular mitochondria, provided that the ratio [TPMP+]i/[TPMP+]e is greater than 50:1 and that at the end of the incubation more than 80% of the hepatocytes exclude Trypan blue. Hepatocytes, staining with Trypan blue, incubated in the presence of Ca2+, do not concentrate TPMP+. The relationships between delta psi m and two other indicators of cellular energy state, delta GPc and Eh, or between delta psi m and J0, were examined in hepatocytes from fasted rats by titration with graded concentrations of inhibitors of mitochondrial energy transduction. Linear relationships were generally observed between delta psi m and delta GPc, Eh or J0 over the delta psi m range of 120-160 mV, except in the presence of carboxyatractyloside or oligomycin, where delta psi m remained constant. Both the magnitude and the direction of the slope of the observed relationships depended upon the nature of the inhibitor. Hepatocytes from fasted rats synthesized glucose from lactate or fructose, and urea from ammonia, at rates which were generally linear functions of the magnitude of delta psi m, except in the presence of oligomycin or carboxyatractyloside. Linear relationships were also observed between delta psi m and the rate of formation of lactate in cells incubated with fructose and in hepatocytes from fed rats. The linear property of these force-flow relationships is taken as evidence for the operation of thermodynamic regulatory mechanisms within hepatocytes.

Linear relationships between mitochondrial forces and cytoplasmic flows argue for the organized energy‐coupled nature of cellular metabolism

We have studied rates of formation of glucose, urea and lactate by isolated hepatocytes incubated with a variety of inhibitors of energy transduction. Linear relationships have been found between these metabolic rates and mitochondrial forces (membrane, redox and phosphorylation potentials). The findings are suggestive of extensive enzyme organization within these metabolic pathways.

Effects of fatty acid oxidation on glucose utilization by isolated hepatocytes

We have studied the inhibitory action of long‐ and short‐chain fatty acids on hepatic glucose utilization in hepatocytes isolated from fasted rats. The rates of hepatic glucose phosphorylation and glycolysis were determined from the tritiated products of [2‐3H] and [6‐3H]glucose metabolism, respectively. The difference between these was taken as an estimate of the ‘cycling’ between glucose and glucose‐6‐phosphate. In the presence of 40 mM glucose this cycling was estimated at 0.68 μ;molmin/g wet wt. Glucose phosphorylation was unaffected during palmitate and hexanoate oxidation to ketone bodies but glycolysis was inhibited. The rate of glucose cycling was increased during this phase to 1.25 μmol/min > g. Following the complete metabolism of the fatty acids, glycolysis was reinstated and cycling rates returned to control levels. Hepatic glucose cycling appears to be an important component of the glucose/fatty acid cycle.

Evidence that stimulation of gluconeogenesis by fatty acid is mediated through thermodynamic mechanisms

We have studied the stimulatory effects of palmitate on the rate of glucose synthesis from lactate in isolated hepatocytes. Control of the metabolic flow was achieved by modulating the activity of enolase using graded concentrations of fluoride. Unexpectedly, palmitate stimulated gluconeogenesis even when enolase was rate‐limiting. This stimulation was also observed when the activities of phosphoenolpyruvate carboxykinase and aspartate aminotransferase were modulated using graded concentrations of quinolinate and aminooxyacetate, respectively. Linear force‐flow relationships were found between the rate of gluconeogenesis and indicators of cellular energy status (i.e. mitochondrial membrane and redox potentials and cellular phosphorylation potential). These findings suggest that the fatty acid stimulation of glucose synthesis is in part mediated through thermodynamic mechanisms.

Effect of palmitate concentration on the relative contributions of the β-oxidation pathway and citric acid cycle to total O2 consumption of isolated rat hepatocytes

The relative contributions of beta-oxidation and citric acid cycle activity to total O2 consumption during fatty acid oxidation were examined in isolated hepatocytes. When hepatocytes were incubated with palmitate alone, a rise in fatty acid concentration induced an increase in O2 uptake that reflected a large stimulation of beta-oxidation and an accompanying smaller inhibition of citric acid cycle oxidation. In the presence of lactate, successive increments in palmitate concentration over the range from 0 to 1.0 mM stimulated glucose synthesis and brought about a concomitant incremental stimulation of both beta-oxidation and citric acid cycle flux. However, above 1.5 mM palmitate, additional increments in fatty acid concentration depressed gluconeogenesis and citric acid cycle activity but induced a further stimulation of beta-oxidation. These findings demonstrate that, during fatty acid oxidation, the rate of citric acid cycle turnover is more closely linked to the rate of glucose synthesis than is the rate of beta-oxidation. This may be relevant to observations that the stimulation of hepatic O2 consumption, induced by fatty acid oxidation, is much greater than can be explained in terms of the ATP-demand arising from exposure of hepatocytes to fatty acid.

Effects of thyroid status on glucose cycling by isolated rat hepatocytes

The effects of alterations in thyroid status on glucose metabolism have been investigated in rat hepatocytes. Addition of 10 or 40 mmol/L glucose induced increases in respiration rate that were significantly larger in cells from hyperthyroid rats than from hypothyroid animals. The responses of hepatocytes from euthyroid rats were intermediate. In cells from hyperthyroid rats, most of the increase occurred upon addition of 10 mmol/L glucose, with only a further small stimulation resulting when glucose concentration was increased to 40 mmol/L. For a given glucose concentration, glycolytic rates, determined by measuring release of tritium from [6-3H]glucose, were comparable in all thyroid states. Studies with 10 mmol/L [2-3H]glucose showed that cycling between glucose-6-phosphate and glucose was almost twofold higher in euthyroid and hyperthyroid states as compared with the hypothyroid state, although the magnitude of the increase in cycling rate was only approximately 0.2 mumol glucose.min-1.g-1. When 40 mmol/L [2-3H]glucose was added, over 44% of the glucose that was phosphorylated to glucose-6-phosphate was cycled back to glucose, but this cycling was independent of thyroid status. Cycling between fructose-1,6-bisphosphate and fructose-6-phosphate was negligible in all thyroid states. Rates of glycogen synthesis were comparable in hypothyroid and hyperthyroid states and slightly less than in the euthyroid state. Glycolytically formed pyruvate was cycled back to glucose in hepatocytes from hypothyroid, euthyroid, and hyperthyroid rats. During a 60-minute incubation period, cycling to glucose in the presence of 10 mmol/L or 40 mmol/L glucose was up to twofold higher in cells from euthyroid and hyperthyroid rats than in hepatocytes from hypothyroid animals. The measured increases in cycling rates induced by thyroid hormone were small and in theory could have been satisfied by a much smaller increase in respiration rate than was observed.

Constraints in the Application of Control Analysis to the Study of Metabolism in Hepatocytes

In recent years it has been argued that quantitative methods are essential for providing new insights into the nature of the living state (Kacser, 1983). A number of mathematical approaches have evolved to meet these demands for quantitative methodologies (Heinrich & Rapoport, 1974; Savageau, 1976; Kacser & Burns, 1979), and of these, control analysis has perhaps attracted the greatest attention. Although its advent has been greeted enthusiastically by many theorists, who see it as an ideal way to quantify the regulatory role of the enzymes of a metabolic pathway, but this analytical method has not yet been widely embraced by experimentalists, because of the difficulties encountered in applying it to complex cellular systems. The work that we shall report in this chapter will illustrate some of these difficulties. The cell system we have used for our studies is the isolated hepatocyte preparation, and we shall present some representative examples from the many hundreds of experiments we have performed in this area.

Relationship between the stimulation of citric acid cycle oxidation and the stimulation of fatty acid esterification and inhibition of ketogenesis by lactate in isolated rat hepatocytes

Isolated hepatocytes from fasted rats were used to study the effects of lactate on palmitate metabolism. Lactate was found to stimulate fatty acid esterification and citric acid cycle oxidation and to inhibit ketone body synthesis. These effects of lactate were largely maintained when gluconeogenesis was inhibited with either quinolinate or perfluorosuccinate, but were overcome by alpha-cyano-4-hydroxycinnamate. However, the responses of hepatocytes to lactate could be restored in the presence of alpha-cyano-4-hydroxycinnamate by the further addition of propionate. The stimulation of triacylglycerol synthesis by lactate was not associated with an increase in the concentration of glycerol 3-phosphate. Rather, there was a correlation between flux through the citric acid cycle and the rate of triacylglycerol synthesis. In all instances reduction of ketone body formation in the presence of lactate was accompanied by a stimulation of citric acid cycle oxidation.

Stimulation of gluconeogenesis leads to an increased rate of β-oxidation in hepatocytes from fasted diabetic but not from fasted normal rats

We have investigated the effects of imposing an ATP demand, generated by the addition of lactate, on hepatocytes isolated from fasted normal and streptozocin-induced diabetic rats. The stimulation of O2 consumption upon lactate addition was much greater in hepatocytes from diabetic rats, as a result of a lactate-induced stimulation of beta-oxidation that was not observed in control cells. This lactate-induced increment in beta-oxidation was extremely sensitive to inhibition by low levels of a number of inhibitors of energy transduction, implying that the increment was tightly coupled to ATP synthesis. Such sensitivity of the beta-oxidative pathway to the addition of similar low concentrations of these inhibitors was not seen in control cells. Inhibitors of the gluconeogenic pathway were also more effective in decreasing beta-oxidation in cells from diabetic animals than in cells from normal rats. The increment in beta-oxidation was not accompanied by increased rates of glucose synthesis, fatty acid esterification or ureogenesis. We propose that it may be associated with higher rates of glucose cycling in cells from diabetic rats.