Adenine nucleotide compartmentation in foetal rat hepatocytes. Effects of atractyloside, oligomycin, calcium ionophore and adrenergic agonists

In the presence of lactate plus pyruvate, or glucose or alanine as substrates, ATP/ADP ratios in the cytosol were higher than in mitochondria in isolated rat foetal hepatocytes. The cytosolic ATP/ADP ratios were dependent on substrate (lactate + pyruvate greater than glucose greater than alanine). Oleate increased the cytosolic ATP/ADP ratios in the presence of the other substrates studied. Atractyloside decreased the cytosolic ATP/ADP ratios, oligomycin decreasing these values in both compartments. Isoproterenol, phenylephrine and Ca2+ ionophore decreased the cytosolic ATP/ADP ratio, without altering this value in mitochondria.     

Regulation of gluconeogenesis by norepinephrine, vasopressin, and angiotensin II: a comparative study in the absence and presence of extracellular Ca2+1

In hepatocytes isolated from fasted rats, vasopressin and angiotensin II stimulate the rate of gluconeogenesis from lactate or pyruvate in a Ca2+-dependent manner similar to that previously reported for norepinephrine. Actions of the peptide hormones on gluconeogenesis from glycerol or sorbitol, reduced substrates that require oxidation before they enter the gluconeogenic pathway at triosephosphate, also resemble those of norepinephrine. Stimulation of glucose production from these substrates is observed only in the presence of extracellular Ca2+. Actions of the peptide hormones on gluconeogenesis from dihydroxyacetone or fructose, the oxidized counterparts of glycerol and sorbitol, respectively, do not resemble those of norepinephrine. While norepinephrine enhances rates of glucose production from dihydroxyacetone or fructose in the absence of extracellular Ca2+, vasopressin and angiotensin II are ineffective either in the absence or presence of extracellular Ca2+. When the oxidation-reduction state in hepatocytes metabolizing dihydroxyacetone is altered by adding an equimolar concentration of ethanol (to provide cytosolic reducing equivalents), the results are similar to those obtained when cells are incubated with the reduced counterpart of dihydroxyacetone, glycerol, i.e., the peptide hormones cause an apparent increase in the rate of glucose production in a Ca2+-dependent manner. If, on the other hand, hepatocytes are incubated with glycerol or sorbitol and an equimolar concentration of pyruvate (to provide a cytosolic hydrogen acceptor), the peptide hormones, unlike norepinephrine, are ineffective in stimulating gluconeogenesis in the absence of extracellular Ca2+. These results indicate that whereas many of the actions of vasopressin and angiotensin II are similar to those of alpha 1-adrenergic agents, there are major differences in the manner in which the hormones act at various sites to regulate gluconeogenesis.     

Phosphorylation state of cytosolic and mitochondrial adenine nucleotides and of pyruvate dehydrogenase in isolated rat liver cells.

1. Cytosolic and mitochondrial ATP and ADP concentrations of liver cells isolated from normal fed, starved and diabetic rats were determined. 2. The cytosolic ATP/ADP ratio was 6,9 and 10 in normal fed, starved and diabetic rats respectively. 3. The mitochondrial ATP/ADP ratio was 2 in normal and diabetic rats and 1.6 in starved rats. 4. Adenosine increased the cytosolic and lowered the mitochondrial ATP/ADP ratio, whereas atractyloside had the opposite effect. 5. Incubation of the hepatocytes with fructose, glycerol or sorbitol led to a fall in the ATP/ADP ratio in both the cytosolic and the mitochondrial compartment. 6. The interrelationship between the mitochondrial ATP/ADP ratio and the phosphorylation state of pyruvate dehydrogenase in intact cells was studied. 7. In hepatocytes isolated from fed rats an inverse correlation between the mitochondrial ATP/ADP ratio and the active form of pyruvate dehydrogenase (pyruvate dehydrogenase a) was demonstrable on loading with fructose, glycerol or sorbitol. 8. No such correlation was obtained with pyruvate or dihydroxyacetone. For pyruvate, this can be explained by inhibition of pyruvate dehydrogenase kinase. 9. Liver cells isolated from fed animals displayed pyruvate dehydrogenase a activity twice that found in vivo. Physiological values were obtained when the hepatocytes were incubated with albumin-oleate, which also yielded the highest mitochondrial ATP/ADP ratio.     

The identification of the major excreted protein (MEP) from a transformed mouse fibroblast cell line as a catalytically active precursor form of cathepsin L.

Incubation of hepatocytes from 24 h-starved rats in the presence of 0.5 mM-adenosine decreased gluconeogenesis from lactate, but not from alanine. The inhibition of gluconeogenesis was associated with a stimulation of ketone-body production and an inhibition of pyruvate oxidation. These metabolic changes were suppressed in the presence of iodotubercidin (an inhibitor of adenosine kinase), but were reinforced in the presence of deoxycoformycin (an inhibitor of adenosine deaminase); 2-chloroadenosine induced no change in gluconeogenesis from lactate. These data indicate that the inhibition of gluconeogenesis by adenosine probably results from its conversion into adenine nucleotides. In the presence of lactate or pyruvate, but not with alanine or asparagine, this conversion resulted in a decrease in the [ATP]/[ADP] ratio in both mitochondrial and cytosolic compartments. Adenosine decreased the Pi concentration with all gluconeogenic substrates.     

The role of calcium in the stimulation of gluconeogenesis by catecholamines

In hepatocytes isolated from fasted normal rats and incubated without albumin or gelatin, norepinephrine stimulated gluconeogenesis from fructose or dihydroxyacetone only in the absence of added calcium and from sorbitol or glycerol only in the presence of added calcium. The effects of calcium, norepinephrine, or calcium in combination with norepinephrine on the concentration of intermediary metabolites were therefore studied in hepatocytes metabolizing fructose or sorbitol as the representative oxidized or reduced substrate, respectively. With fructose as the substrate, addition of calcium increased the concentrations of lactate, pyruvate, glyceraldehyde 3-phosphate, and β-hydroxybutyrate, but decreased the concentrations of phosphoenolpyruvate, 2-phosphoglycerate, 3-phosphoglycerate, glucose 6-phosphate, malate, citrate, and α-oxoglutarate. With sorbitol as the substrate, calcium increased the concentrations of pyruvate, malate, β-hydroxybutyrate, and glucose. With either substrate, calcium caused a decrease in the lactate/ pyruvate ratio and an increase in the β-hydroxybutyrate/acetoacetate ratio, indicating the stimulation of transfer of reducing equivalents from cytosol to mitochondria. With sorbitol as the substrate, and with calcium present, norepinephrine promoted further electron transfer from cytosolic to mitochondrial NAD. Enhanced cytosolic calcium concentrations, when cells are exposed to catecholamines in the presence of medium calcium, stimulate the mitochondrial α-glycerophosphate dehydrogenase and thus the transfer of electrons between cell compartments.     

Evidence that the flux control coefficient of the respiratory chain is high during gluconeogenesis from lactate in hepatocytes from starved rats. Implications for the hormonal control of gluconeogenesis and action of hypoglycaemic agents.

1. Increasing concentrations of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), a mild respiratory-chain inhibitor [Halestrap (1987) Biochim. Biophys. Acta 927, 280-290], caused progressive inhibition of glucose production from lactate + pyruvate by hepatocytes from starved rats incubated in the presence or absence of oleate and gluconeogenic hormones. 2. No significant changes in tissue ATP content were observed, but there were concomitant decreases in ketone-body output and cytochrome c reduction and increases in NADH fluorescence and the ratios of [lactate]/[pyruvate] and [beta-hydroxybutyrate]/[acetoacetate]. 3. The inhibition by DCMU of palmitoylcarnitine oxidation by isolated liver mitochondria was used to calculate a flux control coefficient of the respiratory chain towards gluconeogenesis. In the presence of 1 mM-oleate, the calculated values were 0.61, 0.39 and 0.25 in the absence of hormone and in the presence of glucagon or phenylephrine respectively, consistent with activation of the respiratory chain in situ as previously suggested [Quinlan & Halestrap (1986) Biochem. J. 236, 789-800]. 4. Cytoplasmic oxaloacetate concentrations were shown to decrease under these conditions, implying inhibition of pyruvate carboxylase. 5. Inhibition of gluconeogenesis from fructose and dihydroxyacetone was also observed with DCMU and was accompanied by an increased output of lactate + pyruvate, suggesting that activation of pyruvate kinase was occurring. With the latter substrate, measurements of tissue ADP and ATP contents showed that DCMU caused a small fall in [ATP]/[ADP] ratio. 6. Two inhibitors of fatty acid oxidation, pent-4-enoate and 2-tetradecylglycidate, were shown to abolish and to decrease respectively the effects of hormones, but not valinomycin, on gluconeogenesis from lactate + pyruvate, without changing tissue ATP content. 7. It is concluded that the hormonal increase in mitochondrial matrix volume stimulates fatty acid oxidation and respiratory-chain activity, allowing stimulation of pyruvate carboxylation and thus gluconeogenesis to occur without major changes in [ATP]/[ADP] or [NADH]/[NAD+] ratios. 8. The high flux control coefficient of the respiratory chain towards gluconeogenesis may account for the hypoglycaemic effect of mild respiratory-chain inhibitors.     

Antagonizing effects of phorbol 12-myristate 13-acetate on hormonally stimulated gluconeogenesis in isolated rat hepatocytes involve activity changes of pyruvate kinase

The tumor-promoting phorbol ester phorbol 12-myristate 13-acetate partially neutralized the stimulatory effects of epinephrine (alpha 1-adrenergic actions), glucagon, and dibutyryl-cAMP on gluconeogenesis in isolated hepatocytes of fasted rats, when lactate or dihydroxyacetone was used as the substrate. By constructing metabolic crossover plots and by comparing rates of lactate production from dihydroxyacetone with K0.5 values of extracted pyruvate kinase for phosphoenolpyruvate, we obtained evidence that phorbol ester actions on hormonally stimulated gluconeogenesis were accompanied by proportionate increases in activity of pyruvate kinase. Although purified pyruvate kinase from rat liver was a substrate for protein kinase C in vitro, phosphorylation was not accompanied by modulation of kinetic parameters. Furthermore, incubation of pyruvate kinase extracted from hormone-treated hepatocytes with protein kinase C revealed no activation of the prephosphorylated enzyme. This and the absence of effects of the phorbol ester on basal rates of gluconeogenesis and lactate production suggest that effects of protein kinase C on pyruvate kinase activity in hepatocytes may result from impairment of steps at the level of hormone-induced signal transduction.     

Effect of glycerol and dihydroxyacetone on hepatic lipogenesis

Glycerol is a dietary component which is metabolized primarily by the liver and kidney where it is used mainly for glucose synthesis. The metabolism of glycerol is very similar to that of dihydroxyacetone which can be considered its more oxidized counterpart. The effects of these substrates on hepatic lipogenesis and gluconeogenesis were examined. In isolated hepatocytes, 10 mM dihydroxyacetone caused a large increase in glucose output and stimulated lipogenesis without affecting the lactate/pyruvate ratio or the total ATP content of the cells. (As compared to dihydroxyacetone, 10 mM glycerol was less effective as a gluconeogenic substrate, increased the lactate/pyruvate ratio, caused a slight decrease in the total ATP content, and inhibited lipogenesis by at least 40% depending on the type of diet fed to the rats.) The fall in ATP levels was very small and did not correlate with the changes in fatty acid synthesis. The immediate cause of the inhibition of lipogenesis, brought about by glycerol in hepatocytes from sucrose fed rats, seemed to be a large decrease in pyruvate levels. This did not result from impairment of glycolysis but from a rise in the cytosolic NADH/NAD ratio.     

Ca2+-dependent activation of the malate-aspartate shuttle by norepinephrine and vasopressin in perfused rat liver

The role of Ca2+ in stimulation of the malate-aspartate shuttle by norepinephrine and vasopressin was studied in perfused rat liver. Shuttle capacity was indexed by measuring the changes in both the rate of production of glucose from sorbitol and the ratio of lactate to pyruvate during the oxidation of ethanol. (T. Sugano et al. (1986) Amer. J. Physiol. 251, E385-E392). Asparagine (0.5 mM), but not alanine (0.5 mM) decreased the ethanol-induced responses. Norepinephrine and vasopressin had no effect on the ethanol-induced responses when the liver was perfused with sorbitol or glycerol. In the presence of 0.25 mM alanine, norepinephrine, vasopressin, and A23187 decreased the ethanol-induced responses that occurred with the increase of flux of Ca2+. In liver perfused with Ca2+-free medium, asparagine also decreased the ethanol-induced responses, but norepinephrine and vasopressin had no effect. Aminooxyacetate inhibited the effects of norepinephrine, A23187, and asparagine. Regardless of the presence or absence of perfusate Ca2+, the combination of glucagon and alanine had no effect on the ethanol-induced responses. Norepinephrine caused a decrease in levels of alpha-ketoglutarate, aspartate, and glutamate in hepatocytes incubated with Ca2+. The present data suggest that the redistribution of cellular Ca2+ may activate the efflux of aspartate from mitochondria in rat liver, resulting in an increase in the capacity of the malate-aspartate shuttle.     

Localization and role of pyruvate kinase isoenzymes in the regulation of carbohydrate metabolism and pyruvate recycling in rat kidney cortex

This work was performed to gain more information on the role of pyruvate kinase isoenzymes in the regulation of renal carbohydrate metabolism. Immunohistochemically, pyruvate kinase type L is shown to be localized in the proximal tubule of the nephron and pyruvate kinase type M2 in the distal tubule and the collecting duct. a tight relationship between gluconeogenesis and pyruvate recycling was found. The rate of gluconeogenesis (8 mumol/g wet wt. per 30 min) was of the same order of magnitude as the rate of pyruvate recycling (10.92 mumol/g wet wt. per 30 min). Stimulation of gluconeogenesis from 20 mM lactate in kidney cortex slices of 24-h-starved rats by dibutyryl-cAMP, alanine and parathyroid hormone was connected with a decrease in pyruvate recycling; inhibition of gluconeogenesis due to a lack of Ca2+ in the incubation medium was linked with an increase in pyruvate recycling. The degradation of [6-14C]glucose to lactate, pyruvate, ketone bodies and CO2 and of [2-14C]lactate was unaffected by dibutyryl-cAMP, alanine, epinephrine, vasopressin or the omission of Ca2+ from the incubation medium. 1 mM dibutyryl-cAMP or 5 mM alanine did not alter the activities of oxaloacetate decarboxylase, 'malic' enzyme and malate dehydrogenase from rat kidney cortex. Since aerobic glycolysis in the distal tubules and the collecting ducts is not influenced by hormones, dibutyryl-cAMP and Ca2+, pyruvate kinase type M2 residing in this tissue is unlikely to be a control point of glycolysis. Since this tissue degrades only one-seventh of the glucose formed via gluconeogenesis, it does not contribute significantly to pyruvate recycling. Therefore, the decrease of pyruvate recycling in the presence of dibutyryl-cAMP and alanine in rat kidney cortex slices, leading to increased renal gluconeogenesis, has to be ascribed to the regulation of pyruvate kinase type L.     

Stimulation by vasopressin, angiotensin and oxytocin of gluconeogenesis in hepatocyte suspensions.

1. In hepatocytes from starved rats, vasopressin, angiotensin (angiotensin II) and oxytocin stimulated gluconeogenesis from lactate by 25--50%; minimal effective concentrations were about 0.02pM, 1 nM and 0.2 nM respectively. 2. Vasopressin and angiotensin also stimulated gluconeogenesis from alanine, pyruvate, serine and glycerol. EGTA decreased gluconeogenesis from these substrates. 3. Hormonal stimulation of gluconeogenesis from lactate was abolished in the absence of extracellular Ca2+. 4. Insulin did not prevent stimulation of gluconeogenesis by vasopressin or angiotensin. 5. The potency of the stimulatory effects of vasopressin and angiotensin on hepatic gluconeogenesis suggests they are operative in vivo. Also, the data suggest that Ca2+ plays a role in the stimulation by these hormones.     

Allosteric activation of pyruvate kinase via NAD+ in rat liver cells.

In isolated rat hepatocytes, it has previously been reported that a rise in the ATP content induces a proportional increase in cytosolic NAD+ concentration [Devin, A., Guérin, B. & Rigoulet, M. (1997) FEBS Lett. 410, 329-332]. This occurs under physiological conditions such as various substrates or different energetic states. To investigate the effect of a physiological rise in cytosolic [NAD+] per se on glycolysis and gluconeogenesis, an increase in [NAD+] induced by exogenous nicotinamide addition was obtained without a change in redox potential, ATP/ADP ratio and ATP concentration. Using dihydroxyacetone as substrate, we found that an increase in cytosolic [NAD+] decreases gluconeogenesis and enhances glycolysis without significant alteration of dihydroxyacetone consumption rate. These modifications are the consequence of an allosteric activation of pyruvate kinase via cytosolic NAD+ content. Thus, in addition to the well-known thermodynamic control of glycolysis by pyridine-nucleotide redox status, our study points to a new mechanism of glycolytic flux regulation by NAD+ concentration at the level of pyruvate kinase activity.     

Role of a nonmitochondrial Ca2+ pool in the synergistic stimulation by cyclic AMP and vasopressin of Ca2+ uptake in isolated rat hepatocytes.

The subcellular distribution of 45Ca2+ accumulated by isolated rat hepatocytes exposed to dibutyryl cyclic AMP (dbcAMP) followed by vasopressin (Vp) was studied by means of a nondisruptive technique. When treated with dbcAMP followed by vasopressin, hepatocytes obtained from fed rats accumulated an amount of Ca2+ approximately fivefold higher than that attained under control conditions. Ca2+ released from the mitochondrial compartment by the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) accounted for only a minor portion of the accumulated Ca2+. The largest portion was released by the Ca2+ ionophore A23187 and was attributable to a nonmitochondrial compartment. DbcAMP + Vp-treatment also caused a maximal stimulation of glucose production and a twofold increase in cellular glucose 6-phosphate levels. In hepatocytes obtained from fasted rats, dbcAMP + Vp-stimulated Ca2+ accumulation was lower, although with the same subcellular distribution, and was associated with a minimal glucose production. In the presence of gluconeogenetic substrates (lactate plus pyruvate) hepatocytes from fasted rats were comparable to cells isolated from fed animals. However, Ca2+ accumulation and glucose 6-phosphate production could be dissociated in the absence of dbcAMP, in the presence of lactate/pyruvate alone. Under this condition in fact Vp induced only a minimal accumulation of Ca2+ in hepatocytes isolated from fasted rats, although glucose production was markedly increased. Moreover, treatment of fed rat hepatocytes with 1 mM ATP caused a maximal activation of glycogenolysis, but only a moderate stimulation of cellular Ca2+ accumulation. In this case, sequestration of Ca2+ occurred mainly in the mitochondrial compartment. By contrast, the addition of ATP to dbcAMP-pretreated hepatocytes induced a large accumulation of Ca2+ in a nonmitochondrial pool. Additional experiments using the fluorescent Ca2+ indicator Fura-2 showed that dbcAMP pretreatment can enlarge and prolong the elevation of cytosolic free Ca2+ caused by Vp. A nonmitochondrial Ca2+ pool thus appears mainly responsible for the Ca2+ accumulation stimulated by dbcAMP and Vp in isolated hepatocytes, and cyclic AMP seems able to activate Ca2+ uptake in such a nonmitochondrial pool.     

Metabolism of adenosine through adenosine kinase inhibits gluconeogenesis in isolated rat hepatocytes

In isolated hepatocytes from fasted rats, 0.5 mM adenosine inhibited gluconeogenesis from glutamine, lactate and pyruvate. This inhibition was due to adenosine conversion through adenosine kinase. An increase in ketone body release was only observed in the presence of lactate or pyruvate, and the two phenomena (i.e. inhibition of gluconeogenesis and increased ketone-body release) were linked. With alanine, dihydroxyacetone or serine as substrates, adenosine did not change gluconeogenesis; however, its conversion through adenosine kinase also inhibited gluconeogenesis. With asparagine as substrate, 0.5 mM adenosine increased gluconeogenesis; this increase was due to adenosine conversion through adenosine deaminase. However, adenosine conversion through adenosine kinase inhibited gluconeogenesis from asparagine. Thus, whatever the substrate used, adenosine conversion through adenosine kinase inhibited gluconeogenesis. The inhibitory effect of adenosine on gluconeogenesis cannot be related to the decrease in Pi concentration and to the increase in ATP pool. Beside its effect on gluconeogenesis, adenosine inhibited ketogenesis measured without added substrate; adenosine conversion through adenosine kinase was also involved in the inhibition of ketogenesis.     

Thyroid hormone and dehydroepiandrosterone permit gluconeogenic hormone responses in hepatocytes

The importance of the sn-glycerol- 3-phosphate (G-3-P) electron transfer shuttle in hormonal regulation of gluconeogenesis was examined in hepatocytes from rats with decreased mitochondrial G-3-P dehydrogenase activity (thyroidectomized) or increased G-3-P dehydrogenase activity [triiodothyronine (T(3)) or dehydroepiandrosterone (DHEA) treated]. Rates of glucose formation from 10 mM lactate, 10 mM pyruvate, or 2.5 mM dihydroxyacetone were somewhat less in hypothyroid cells than in cells from normal rats but gluconeogenic responses to calcium addition and to norepinephrine (NE), glucagon (G), or vasopressin (VP) were similar to the responses observed in cells from normal rats. However, with 2. 5 mM glycerol or 2.5 mM sorbitol, substrates that must be oxidized in the cytosol before conversion to glucose, basal gluconeogenesis was not appreciably altered by hypothyroidism but responses to calcium and to the calcium-mobilizing hormones were abolished. Injecting thyroidectomized rats with T(3) 2 days before preparing the hepatocytes greatly enhanced gluconeogenesis from glyc erol and restored the response to Ca(2+) and gluconeogenic hormones. Feeding dehydroepiandrosterone for 6 days depressed gluconeogenesis from lactate or pyruvate but substantially increased glucose production from glycerol in euthyroid cells and restored responses to Ca(2+) in hypothyroid cells metabolizing glycerol. Euthyroid cells metabolizing glycerol or sorbitol use the G-3-P and malate/aspartate shuttles to oxidize excess NADH generated in the cytosol. The transaminase inhibitor aminooxyacetate (AOA) decreased gluconeogenesis from glycerol 40%, but had little effect on responses to Ca(2+) and NE. However, in hypothyroid cells, with minimal G-3-P dehydrogenase, AOA decreased gluconeogenesis from glycerol more than 90%. Thus, the basal rate of gluconeogenesis from glycerol in the euthyroid cells is only partly dependent on electron transport from cytosol to mitochondria via the malate/aspartate shuttle and almost completely dependent in the hypothyroid state, and the hormone enhancement of the rate in euthyroid cells involves primarily the G-3-P cycle. These data are consistent with Ca(2+) being mobilized by gluconeogenic hormones and G-3-P dehydrogenase being activated by Ca(2+) so as to permit it to transfer reducing equivalents from the cytosol to the mitochondria.     

Gluconeogenesis in rabbit liver. III. The influences of glucagon, epinephrine, alpha- and beta-adrenergic agents on gluconeogenesis in isolated hepatocytes

1. Gluconeogenesis from various substrates has been demonstrated in hepatocytes from 48 h fasted rabbits. Maximum rates of gluconeogenesis (expressed as mumol glucose formed/30 min per 10(8) cells) are: D-fructose, 9.86; dihydroxyacetone, 5.28; L-lactate, 5.26; L-lactate/pyruvate, 3.83; pyruvate, 3.32; glycerol, 2.92; L-alanine, 2.24. 2. Gluconeogenesis from L-lactate is enhanced 1.3--1.5-fold over control values by glucagon, L-epinephrine, L-norepinephrine, dibutyryl cyclic AMP, L-phenylephrine and L-isoproterenol. Glucogenesis from both dihydroxyacetone and D-fructose is stimulated 1.7--2.0-fold of control values by glucagon, epinephrine and dibutyryl cyclic AMP. 3. Gluconeogenesis from lactate is enhanced by both alpha- and beta-adrenergic stimulations based on findings with alpha- and beta-agonists and antagonists. 4. Enhancement of gluconeogenesis by epinephrine and norepinephrine is apparently due to both alpha- and beta-adrenergic effects, as either propranolol or phentolamine partially inhibits such enhancement. The consistently more pronounced inhibition produced by propranolol implies that stimulation of glucose formation by catecholamines is more strongly beta-adrenergic related. Epinephrine-induced glycogenolysis in rabbit hepatocytes is severely inhibited by propranolol but insensitive to phentolamine, suggesting that glycogen breakdown is solely beta-adrenergic related. These observations contrast with those of others that stimulation of both gluconeogenesis and glycogenolysis by catecholamines while sensitive to both alpha- and beta-adrenergic stimulation in rats, at least young rats, is primarily alpha-adrenergic mediated, especially in adult rats.     

Is the adenine nucleotide translocator rate-limiting for oxidative phosphorylation?

1. The effects of atractyloside and carboxyatractyloside (between 5 and 40μm) on O₂ uptake, glucose synthesis, urea synthesis, the adenine nucleotide content and the intracellular K⁺ concentration were measured in isolated hepatocytes. 2. Urea synthesis was much less inhibited than glucose synthesis by both atractylosides. Measurements of intermediary metabolites of carbohydrate metabolism in freeze-clamped liver after injection of atractyloside into rats indicate that inhibition of gluconeogenesis is due to interference at the cytosolic reactions requiring ATP (phosphoenolpyruvate carboxykinase and 3-phosphoglycerate kinase). 3. The decrease in [ATP]/[ADP]×[P_i] after addition of atractyloside or carboxyatractyloside was restricted to the cytosol. 4. Dihydroxyacetone can be converted either into glucose with the consumption of 2mol of ATP (per mol of glucose) or into lactate with the production of 2mol of ATP. In the presence of high concentrations of atractyloside and carboxyatractyloside more ATP was produced than was used for the synthesis of glucose from dihydroxyacetone, probably for the maintenance of intracellular [K⁺]. 5. When the rates of respiration were altered by changing substrates, the degrees of inhibition of respiration and translocation by a given concentration of the atractylosides were the same, whereas at a given concentration of HCN the degree of inhibition was high at higher initial rates, and low at lower initial rates. 6. Inhibition of a complex series of reactions by atractyloside does not necessarily indicate that the translocator is a rate-limiting step in that sequence as Th. P. M. Akerboom, H. Bookelman & J. M. Tager [(1977) FEBS. Lett. 74, 50–54] assume. This point is discussed.     

3-Aminopicolinate inhibits phosphoenolpyruvate carboxykinase in hepatocytes and increases release of gluconeogenic precursors from peripheral tissues

3- Aminopicolinate , a hyperglycemic agent that activates purified phosphoenolpyruvate carboxykinase in the presence of Fe2+, inhibits glucose synthesis from lactate, pyruvate, asparagine, monomethyl succinate, or glutamine but does not affect that from fructose, dihydroxyacetone, sorbitol, or glycerol in hepatocytes isolated from rats fasted for 24 h. Lactate production from monomethyl succinate by hepatocytes is also inhibited by 3- aminopicolinate . This compound elevates the concentrations of pyruvate, malate, and aspartate but decreases that of phosphoenolpyruvate in hepatocytes incubated with lactate plus pyruvate. In rats, the ability of 3- aminopicolinate to elevate blood glucose concentration is unimpaired by renalectomy . The drug does not significantly affect glycemia in functionally hepatectomized rats but accelerates blood lactate and pyruvate accumulation to higher maximum concentrations even when kidney function is also ablated. It is concluded that 3- aminopicolinate inhibits phosphoenolpyruvate carboxykinase in hepatocytes, that the reported stimulation of renal glutaminase and glutamine gluconeogenesis by this compound does not contribute significantly to its hyperglycemic property, and that the drug increases gluconeogenic substrate supply from peripheral tissues.     

Development of gluconeogenesis from dihydroxyacetone in rat hepatocytes during a feeding cycle and starvation.

Pyruvate kinase activity and the rates of gluconeogenesis and glycolysis in rat hepatocytes were evaluated by production of glucose and lactate + pyruvate from dihydroxyacetone during a feeding cycle or progressive starvation. In fed rats, during daylight (low food intake) and until darkness, gluconeogenesis progressively increased and glycolysis decreased slightly, but gluconeogenesis never exceeded glycolysis. During nocturnal feeding, gluconeogenesis and glycolysis returned to their morning rates. After 8 h starvation, an equal proportion of dihydroxyacetone was converted into glucose and into lactate + pyruvate. When glycogen was depleted (11 h of starvation), gluconeogenesis was maximal and glycolysis minimal. In fed and starved rats, the concentration of fructose 1,6-bisphosphate was the same. The activity ratio of pyruvate kinase (ratio of velocity at 0.5 mM-phosphoenolpyruvate to the maximum catalytic activity obtained with 4mM-phosphoenolpyruvate) was high in crude extracts of cells incubated with dihydroxyacetone and low in (NH4)2SO4-treated extracts, but remained unchanged during the whole experiment. There was no correlation between the rates of gluconeogenesis and glycolysis from dihydroxyacetone and the activity ratio of pyruvate kinase.     

Control of gluconeogenesis in rat liver cells. I. Kinetics of the individual enzymes and the effect of glucagon

Control of gluconeogenesis from lactate was studied by titrating rat liver cells with lactate and pyruvate in a ratio of 10:1 in a perifusion system. At different steady states of glucose formation, the concentration of key gluconeogenic intermediates was measured and plotted against gluconeogenic flux (J glucose). Complete saturation was observed only in the plot relating J glucose to the extracellular pyruvate concentration. Measurement of pyruvate distribution in the cell showed that the mitochondrial pyruvate translocator operates close to equilibrium at high lactate and pyruvate concentrations. It can therefore be concluded that pyruvate carboxylase limits maximal gluconeogenic flux. Addition of glucagon did not cause a shift in the plots relating J glucose to glucose 6-phosphate, dihydroxyacetone phosphate, 3-phosphoglycerate, and phosphoenolpyruvate. It can thus be concluded that glucagon does not affect the kinetic parameters of the enzymes involved in the conversion of phosphoenolpyruvate to glucose. Addition of glucagon led to a shift in the curves relating J glucose to the concentration of cytosolic oxalacetate and extracellular pyruvate. The shift in the curve relating J glucose to oxalacetate is due to glucagon-induced inhibition of pyruvate kinase. The stimulation of gluconeogenesis by glucagon can be accounted for almost completely by inhibition of pyruvate kinase. There was almost no stimulation by glucagon of pyruvate carboxylation. In the absence of glucagon, control on gluconeogenesis from lactate is distributed among different steps including pyruvate carboxylase and pyruvate kinase. Assuming that in the presence of glucagon all pyruvate kinase flux is inhibited, the control of gluconeogenesis in the presence of the hormone is confined exclusively to pyruvate carboxylase.