Regulation of hepatic gluconeogenesis in the guinea pig by fatty acids and ammonia.

Octanoate and L-palmitylcarnitine inhibited the synthesis of P-enolpyruvate from alpha-ketoglutarate and malate by isolated guinea pig liver mitochondria. A 50% reduction in P-enolpyruvate formation was obtained with 0.1 to 0.2 mM octanoate or with 0.06 to 0.10 mM L-palmitylcarnitine. At these concentrations, oxidative phosphorylation remained intact and only much higher concentrations of fatty acids altered this process. The addition of NH4Cl in the presence of malate and increasing concentrations of alpha-ketoglutarate (or vice versa) enhanced the formation of glutamate, aspartate, and P-enolpyruvate. The addition of increasing concentrations of NH4Cl in the presence of fixed amounts of malate and alpha-ketoglutarate had a similar effect. Furthermore, the inhibition of P-enolpyruvate synthesis by fatty acids and the reduction of the acetoacetate to beta-hydroxybutyrate ratio were reversed by the addition of NH4Cl. Cycloheximide, which blocks energy transfer at site 1 of the respiratory chain, decreased P-enolpyruvate formation. When cycloheximide and either octanoate or L-palmitylcarnitine were added together, there was an even greater reduction in P-enolpyruvate synthesis from either malate or alpha-ketoglutarate than was noted with either fatty acid alone. Since cycloheximide lowers the rate of ATP synthesis this may in turn reduce P-enolpyruvate formation by a mechanism independent of changes in the mitochondrial NAD+/NADH ratio caused by fatty acids. In the isolated perfused liver metabolizing lactate, the inhibitory effect of octanoate on gluconeogenesis was partially relieved by the addition of 1 mM NH4Cl, but remained unchanged in the presence of 2 mM NH4Cl, despite a highly oxidized NAD+/NADH ratio in the mitochondria. In contrast to glucose synthesis, urea formation was markedly increased during the infusion of 1 mM as well as 2 mM NH4Cl. After cessation of NH4Cl infusion, there was an increase in glucose production, to a rate as high as that observed in the absence of octanoate. This increase was accompanied by the disappearance of alanine, aspartate, and glutamate which had been stored in the liver during NH4Cl infusion. Urea synthesis also decreased progressively. These results indicate that gluconeogenesis in guinea pig liver is regulated, in part, by alterations in the mitochondrial oxidation-reduction state. However, the modulation of this effect by changing the concentrations of intermediates of the aspartate aminotransferase reaction indicates competition for oxalacetate between the aminotransferase reaction and P-enolpyruvate carboxykinase.     

Regulation of gluconeogenesis from propionate and propanol in the perfused guinea pig liver

• 1.1. Gluconeogenesis from propanol in perfused guinea pig liver is stimulated by aspartate, glutamate and phenazine-methosulfate, and inhibited by octanoate and by aminooxyacetate.
• 2.2. Gluconeogenesis from propionate is inhibited by octanoate and by NH₄⁺, and stimulated by ethanol.
• 3.3. Phosphoenolpyruvate formation from propionate in isolated guinea pig liver mitochondria is inhibited by octanoate and by NH₄⁺ or by both.
• 4.4. The data are discussed in terms of regulation of gluconeogenesis from both substrates in guinea pig liver.

     

Fatty acid effects on gluconeogenesis in goat, calf and guinea pig hepatocytes

1. Regulation of hepatic gluconeogenesis by fatty acid was studied in goat, calf and guinea pig hepatocytes. 2. Fatty acid effects on gluconeogenesis were dependent upon species; fatty acid and gluconeogenic substrate. 3. Oleate and octanoate inhibited gluconeogenesis from propionate in guinea pig hepatocytes and stimulated it in goat hepatocytes. 4. Oleate and octanoate markedly inhibited gluconeogenesis from lactate in guinea pig hepatocytes whereas octanoate, but not oleate, decreased glucose production from lactate in goat hepatocytes. 5. Effects of fatty acids on gluconeogenesis in calf hepatocytes were similar to goat hepatocytes suggesting control of gluconeogenesis is similar among ruminant species but differs from guinea pigs.     

Estrogen sulfotransferase distribution in tissues of mouse and guinea pig: steroidal inhibition of the guinea pig enzyme.

The highest total activity of estrogen sulfotransferase in guinea pig is in liver and the highest specific activities are in the adrenal and the midgestational chorion. Guinea pig gonads contain scarcely detectable activities. In CD-1 mice the highest specific activity is in testis and the highest total activity is in late placenta. Adrenals from both sexes and ovaries contain minimal activities, while liver and fetal membrane activities are remarkably low. In CD-1, DBA, C57BL, and BALB mice, qualitative patterns are similar. Purified or partially purified estrogen sulfotransferase from guinea pig adrenal and chorion were used to study the effect of a number of possible steroidal inhibitors. Considerable structural specificity is evident within a range of steroids, even among some which are not substrates. Pregnenolone is the most effective 21-carbon inhibitor and, in general, more highly hydroxylated forms are less inhibitory. Within a series of 21-, 19- and 18-carbon steroids, the structure of the A ring appears to be extremely important in regard to inhibitory effects.     

Vagal inhibition in the antral region of guinea pig stomach

The effects of vagal stimulation in the presence of a muscarinic antagonist were examined on three distinct rhythmically active cells located in guinea pig antrum. Vagal stimulation inhibited contractions of the circular muscle layer but did not change their rate of occurrence. With the use of intracellular recording techniques, these stimuli were found to initiate inhibitory junction potentials in the circular layer but produced smaller potential changes in driving and follower cells. Inhibition of the circular muscle layer involved two separate components. The dominant component was independent of changes in membrane potential and was abolished by nitro-L-arginine. After abolishing Ca(2+) entry into smooth muscle cells with a Ca(2+) antagonist, vagal stimulation continued to inhibit the residual contractions associated with each slow wave. When the cyclic changes in intracellular Ca(2+) concentration associated with each slow wave were measured, they were found to be unchanged by vagal stimulation. The observations suggest that vagal inhibition of stomach movements does not alter pacemaker activity in the stomach; rather, it results from a change in the sensitivity of smooth muscle contractile proteins to Ca(2+).     

Gossypol-induced inhibition of guinea pig sperm capacitation in vitro

The effect of gossypol acetate at various concentrations (10(-6) to 10(-4) M) on guinea pig sperm forward progressive movement, capacitation, and the acrosome reaction was explored in vitro. We found that 10(-4) M gossypol completely abolished the forward progressive motility of the sperm, and that this inhibition of motility was proportional to the concentration of gossypol used. Also, a dose-dependent decrease in acrosome reactions occurred with concentrations of the agent as low as 5.0 X 10(-6) M. However, we observed that such prevention of the acrosome reaction apparently happens at the capacitation stage rather than during the acrosome reaction itself. Inhibition of capacitation by gossypol was reversible--once the spermatozoa were capacitated in gossypol-free medium, the compound did not block the reaction.     

Subcellular localisation of guinea pig hepatic molybdenum hydroxylases.

Molybdenum hydroxylase activity in guinea pig liver has been compared with that of marker enzymes in mitochondria (succinate dehydrogenase), microsomes (glucose-6-phosphatase) and cytosol (lactate dehydrogenase). Aldehyde oxidase activity was highest in the cytosol, with about 10-fold activity of xanthine oxidase. Significant molybdenum hydroxylase activity was found in mitochondria with minimal levels in microsomes. Mitochondrial and cytosolic aldehyde oxidase varied in substrate specificity and electrophoretic mobility with two major bands in each fraction, one of which was common to cytosol and mitochondria.     

The relationship between mitochondrial heterogeneity and gluconeogenesis in liver mitochondria of the rat, pigeon and guinea pig.

Isolated mitochondria of pigeon and guinea pig liver were subjected to zonal centrifugation. With pigeon liver mitochondria there was uniform distribution of pyruvate carboxylase, phosphoenolpyruvate carboxykinase, malate dehydrogenase, aspartate aminotransferase and glutamate dehydrogenase activities. Guinea pig liver mitochondria demonstrated two pyruvate carboxylase and phosphoenolpyruvate carboxykinase maxima but only one maximum with aspartate aminotransferase, malate dehydrogenase and glutamate dehydrogenase. Mitochondrial enzyme levels in rat, pigeon and guinea pig indicate different roles of certain gluconeogenic enzymes in the transport of carbon and hydrogen in and out of mitochondria.     

Cholinergic inhibition of electrogenic sodium absorption in the guinea pig distal colon

Submucosal cholinergic and noncholinergic neurons in intestines have been shown to be involved in regulating epithelial transport functions, particularly stimulating Cl(-) secretion. This study investigates the role of submucosal cholinergic neurons in regulating electrogenic Na(+) absorption in distal colon. Amiloride-sensitive short-circuit current (I(sc)) and (22)Na(+) flux were measured in mucosal and mucosal-submucosal preparations mounted in Ussing chambers. In the mucosal preparation, carbachol (CCh) added to the serosal side inhibited amiloride-sensitive I(sc) and amiloride-sensitive (22)Na(+) absorption. The inhibitory effect of CCh was observed at approximately 0.1 microM, and maximum inhibition of approximately 70% was attained at approximately 30 microM (IC(50) = approximately 1 microM). CCh-induced inhibition of amiloride-sensitive I(sc) was almost totally abolished by 10 microM atropine. Treatment of the tissue with ionomycin markedly reduced amiloride-sensitive I(sc), but a subsequent addition of CCh further decreased it. Also, CCh still had an inhibitory effect, although significantly attenuated, after the tissue had been incubated with a low-Ca(2+) solution containing ionomycin and BAPTA-AM. Applying electrical field stimulation to submucosal neurons in the mucosal-submucosal preparation resulted in inhibition of amiloride-sensitive I(sc), approximately 33% of this inhibition being atropine sensitive. Physostigmine inhibited amiloride-sensitive I(sc), this effect being abolished by atropine. In conclusion, submucosal cholinergic and noncholinergic neurons were involved in inhibiting electrogenic Na(+) absorption in colon. This inhibition by cholinergic neurons was mediated by muscarinic receptor activation.