Critical evaluation of methods used for the isolation of rat liver hepatocytes for metabolic studies.

Hepatocytes were isolated from normal fed, fasted and alloxan diabetic animals. The best cell preparations were obtained by using low concentrations of collagenase (10–20 mg) and exposing the liver for a very short period of time (10–15 min). Addition of hyaluronidase significantly decreased the glycogen content of the isolated hepatocytes. Glucagon (10⁻¹²M) stimulated glycogenesis in hepatocytes containing high glycogen whereas, in cells containing low glycogen much higher concentration of glucagon was needed (10⁻⁹M). Addition of insulin (100 μunits) stimulated both glycogen and protein synthesis in isolated hepatocytes containing high glycogen. Under these conditions glycogen synthase activity was stimulated by 40%. Incorporation of ¹⁴C phenylalanine into protein was linear for only 3–4 hr in cells containing low glycogen whereas, in cells containing high glycogen incorporating was linear for 8–10 hr. These studies suggest that intracellular glycogen plays an important role in the hormonal regulation of metabolism in hepatocytes.     

Gluconeogenesis in rat liver parenchymal cells in primary culture: Permissive effect of the glucocorticoids on glucagon stimulation of gluconeogenesis

Primary cultures of parenchymal cells isolated from adult rat liver by a collagenase perfusion procedure and maintained as a monolayer in a serum-free culture medium were used to study glucoeogenesis and the role that the glucocorticoids play in the control of this pathway. These cells carried out gluconeogenesis from three-carbon precursors (alanine and lactate) in response to glucagon and dexamethasone added alone or in combination. Maximum glucose production was observed with cells pretreated for several hours with dexamethasone and glucagon prior to addition of substrate and glucagon (8- to 12-fold increase over basal glucose production). Half-maximum stimulation of gluconeogenesis was seen with 3.6 × 10^?10 M glucagon and 3.6 × 10^?8 M dexamethasone. Maximum stimulation was oberved with 10^?7 M glucagon and 10^?6 M dexamethasone. The length of time of dexamethasone pretreatment was found to be important in demonstrating the effect of glucocorticoids on glucagon-stimulated gluconeogenesis. Treeatment of cells with dexamethasone for 2 hours did not result in an increase in glucose production over identical experimental conditions in the absence of dexamethasone, wherease pretreatment for 5 hours (1.2-fold increase) or 15 hours (1.7-fold increase) did result in an increase in glucose production. The results establish that the adult rat liver parenchymal cells in primary culture are a valid model system to study hepatic gluconeogenesis. In addition, we have established directly that the glucocorticoids amplify the glucagon stimulation of gluconeogenesis.     

Stimulation of glycogenolysis by epinephrine and glucagon and its inhibition by insulin in isolated rat liver hepatocytes

Rat liver hepatocytes were isolated by collagenase $\text{in vitro}$ perfusion technique and the effect of epinephrine, glucagon and insulin on glycogenolysis was studied. Both glucagon and epinephrine at the concentration of 10^?6M, stimulated gluconeogenesis by 80–100%. Addition of insulin (33 μUnits/ml) completely abolished the epinephrine-stimulated glycogenolysis whereas only 50% inhibition was observed with insulin in glucagon stimulated glycogenolysis. This stimulation was observed within 2–5 min after the addition of the hormones. These results suggest that hepatocytes isolated with low concentrations of collagenase retain glucagon, epinephrine and insulin receptor sites.     

Interrelationship of insulin and glucagon ratios on carbohydrate metabolism in isolated hepatocytes containing high glycogen.

The effect of physiological concentrations of glucagon and insulin on glycogenolysis was studied in the presence and absence of substrates in isolated hepatocytes containing high glycogen. In the absence of substrates glucagon stimulated glycogenolysis at 10^?14M concentration, and addition of 100 μunits of insulin partially inhibited glucagon stimulated glycogenolysis (10^?14M to 10^?11M). However, in the presence of substrates, insulin completely inhibited glucagon stimulated glycogenolysis (10^?14M to 10^?11M), indicating that molar glucagon and insulin ratios control carbohydrate metabolism in liver. Additional studies showed incorporation of amino acid into protein was linear for only 3 to 4 hr in cells containing low glycogen, whereas in cells containing high glycogen, incorporation was linear for 8 to 10 hr.     

Studies on the lack of glucagon response to clycogenolysis and gluconeogensis and decrease in protein synthesis in isolated hepatocytes from hypophysectomized animals.

Effect of various concentrations of glucagon on gluconeogenesis and glycogenolysis was studied in isolated hepatocytes obtained from normal and hypophysectomized animals. Addition of glucagon (10^?10 to 10^?6M) stimulated glycogenolysis and gluconeogenesis by 2–3 fold in normal hepatocytes. However, this concentration of glucagon had only a slight effect in isolated hepatocytes obtained from hypophysectomized animals. This lack of glucagon response was not due to reduction in glycogen levels in isolated hepatocytes obtained from hypophysectomized animals. Studies on the incorporation of¹⁴C-alanine,¹⁴C-leucine and¹⁴C-valine showed a 3–5 fold decrease in the incorporation of these amino acids into protein in hypophysectomized animals compared to normal controls.     

Effect of starvation of gastric somatostatin release

The present study is an investigation of the effects of 16 and 48 hours starvation on gastric somatostatin release using the isolated perfused rat stomach. Before sacrifice the body weights and blood glucose levels of fasted rats were significantly lower than fed rats. In the presence of 4.4 mM glucose, basal somatostatin concentrations in the stomach perfusate of fasted rats were also significantly lower. Gastric somatostatin release was stimulated in all three groups similarly by 5 × 10^?8 M glucagon when the decrease in basal levels is considered. These results suggest that gastric somatostatin as well as pancreatic somatostatin contributes to nutrient homeostasis and that nutrient homeostasis influences somatostatin levels in turn.     

In vivo and in vitro effects of beta-endorphin on glucose metabolism in the rat

The effects of beta-endorphin (beta-Ep) on plasma glucose levels in rats and on glucose metabolism in isolated rat liver cells were examined. Intravenous injection of beta-Ep (5 micrograms/100 g BW) into ether-anaesthetized rats resulted in prompt and sustained hyperglycaemia with increases in the plasma glucagon and somatostatin levels and decrease in the plasma insulin level. When liver cells isolated from fed rats were incubated in the presence of beta-Ep at concentrations of 6 X 10(-8) M to 6 X 10(-7) M, glucose release into the medium increased within 15 min in a dose-related manner. Time course experiments showed that beta-Ep increased the level of cyclic AMP within 3 min. Significant increase in gluconeogenesis in liver cells isolated from fasted rats was also observed on addition of 10(-7) M beta-Ep in the presence of 10 mM L-lactate. These results suggest that the hyperglycaemia induced by beta-Ep may be caused, at least in part, by the effects of beta-Ep on releases of pancreatic hormones and glucose production in liver cells.     

Effect of chronic alcohol administration on the hormonal sensitivity of isolated perfused rat liver

Acute or chronic alcohol administration (37% totally liquid lowfat Metrecal diet) to rats does not affect the normal rate of lactate gluconeogenesis in the isolated perfused liver. However, under challenging doses of either epinephrine (10^?6M) or glucagon (2×10^?8M), the isolated perfused alcoholic livers showed subnormal percentage stimulation in the rate of gluconeogenesis when compared to the controls. The activities of two key hepatic gluconeogenesis enzymes in the cytosol PEPCK and FDPase, were not appreciably altered by chronic alcohol feeding. These results suggest another of membrane involvement as a consequence of the chronic alcohol feeding in the observed depression of hormonal sensitivity.     

The secretory response in dissociated acini from the rat submandibular gland

Rat submandibular gland was dissociated by enzymatic digestion with collagenase and hyaluronidase, followed by mild mechanical shearing and filtration through a nylon mesh. The dissociated cell populations contained predominantly groups of acinar cells which maintained their acinar arrangement. The morphological and functional viability of the cells was confirmed by electron microscopic examination and a normal secretory response to β-adrenergic or cholinergic stimulation was observed. Both isoproterenol (IPR) and carbachol caused the fusion of secretory granules into large vacuoles which were also continuous with the lumen, and into which the secretory product was released. Secretion was assessed quantitatively from the incorporation of ¹⁴C-glucosamine into the acinar cells and its subsequent release into the culture medium as labelled glycoprotein. IPR stimulated secretion to 125% of untreated controls in the concentration range 5 × 10^?5 to 5 × 10^?7 M, and to 110% of controls at 5 × 10^?8 M, after 40 min incubation. Carbachol stimulated secretion to 131% of controls at 5 × 10^?5 M and to 115% at 5 × 10^?6 M but had no effect at 5 × 10^?7 or 5 × 10^?8 M. The secretory response was blocked by the respective β-adrenergic and cholinergic antagonists, propranolol and atropine. These findings show that dissociated rat submandibular acinar cells provide a useful in vitro model for the study of mucus synthesis and secretion.     

Effect of ethanol on hepatic phosphatidate phosphohydrolase: dose-dependent enzyme induction and its abolition by adrenalectomy and pyrazole treatment

Protein synthesis, measured as the incorporation of [¹⁴C]valine into cell proteins and into proteins secreted into the medium, and albumin production were studied in isolated rat liver hepatocytes. Protein synthesis was substantially higher in cells from fed rats than in cells from fasted rats. Addition of carbohydrates or amino acids increased protein synthesis in cells from fasted rats, whereas no effect was seen in cells from fed rats. Addition of oleate had no effect on protein synthesis. Ethanol inhibited protein synthesis in cells from fasted rats, whereas no or only small effect was seen in cells from fed rats. Simultaneous addition of carbohydrates diminished the inhibitory effect of ethanol, whereas addition of oleate increased the inhibitory effect of ethanol. It is suggested that the rate of protein synthesis in cells from fasted rats could be restricted by lack of precursors for synthesis of nonessential amino acids. The effect of ethanol is explained by an inhibition of gluconeogenesis.     

The permissive effects of glucocorticoid on hepatic gluconeogenesis. Glucagon stimulation of glucose-suppressed gluconeogenesis and inhibition of 6-phosphofructo-1-kinase in hepatocytes from fasted rats

Production of [14C]glucose from [14C]lactate in the perfused livers of 24-h fasted adrenalectomized rats was not stimulated by 1 nM glucagon but was significantly increased by 10 nM hormone. Crossover analysis of glycolytic intermediates in these livers revealed a significant reduction in glucagon action at site(s) between fructose 6-phosphate and fructose 1,6-bisphosphate as a result of adrenalectomy. Site(s) between pyruvate and P-enolpyruvate was not affected. In isolated hepatocytes, adrenalectomy reduced glucagon response in gluconeogenesis while not affecting glucagon inactivation of pyruvate kinase. A distinct lack of glucagon action on 6-phosphofructo-1-kinase activity was noted in these cells. When hepatocytes were incubated with 30 mM glucose, lactate gluconeogenesis was greatly stimulated by glucagon. A reduction in both sensitivity and responsiveness to the hormone in gluconeogenesis was seen in the adrenalectomized rat. These changes were well correlated with similar impairment in glucagon action on 6-phosphofructo-1-kinase activity and fructose 2,6-bisphosphate content in hepatocytes from adrenalectomized rats incubated with 30 mM glucose. These results suggest that adrenalectomy impaired the gluconeogenic action of glucagon in livers of fasted rats at the level of regulation of 6-phosphofructo-1-kinase and/or fructose 2,6-bisphosphate content.     

Cyclic AMP stimulated phosphorylation of liver pyruvate kinase in hepatocytes.

The addition of glucagon (10^?6 M) to an incubation mixture containing ³²Pi and hepatocytes isolated from livers of rats fed $\text{ad libitum}$ results in both a 3-fold increased incorporation of ³²P into L-type pyruvate kinase and a decreased catalytic activity. The ³²P incorporated into pyruvate kinase was covalently bound to the enzyme as evidenced by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. In addition, exogenous cyclic AMP (10^?3 M) stimulated the phosphorylation and the suppression of catalytic activity to a similar extent. On the other hand, insulin (10^?7 M) had essentially no effect on the incorporation of ³²P into pyruvate kinase or on its catalytic activity under the conditions used in this study. These results suggest that phosphorylation of pyruvate kinase $\text{invivo}$ is stimulated by glucagon via cyclic AMP and cyclic AMP-dependent protein kinase and that the activity of the enzyme is, at least in part, regulated by a phosphorylation-dephosphorylation mechanism.     

Tetradecanoyl phorbol acetate stimulates latent collagenase production by cultured human endothelial cells

Angiogenesis is associated with the fragmentation of blood vessel basement membranes. Since collagen is a major constituent of basement membranes, cultured human endothelial cells derived from umbilical cord veins were assayed for their ability to produce collagenase. Unstimulated cultured human endothelial cells did not secrete detectable levels of active collagenase into the culture medium. However, if the post-culture medium was treated with trypsin or plasmin, low levels of collagenolytic activity were detected, indicating that endothelial cells secrete small amounts of latent collagenase. Addition of the tumor promoter 12-O-tetradecanoyl phorbol-13-acetate (TPA) to the culture medium stimulated the secretion of collagenase by endothelial cells 5–30 fold. More than 90% of the collagenase was secreted in the latent form. Stimulation of collagenase production was detected at 10^?9 M TPA and was maximal at 10^?8 M TPA. An increase in the rate of collagenase production could be detected within 3 hr after the addition of TPA, and full induction occurred by 12 hr. Cycloheximide (3 μg/ml) or actinomycin D (0.1 μg/ml) inhibited both basal levels of collagenase production and the stimulation of collagenase production by TPA. Phorbol-12,13-didecanoate (PDD), a tumor-promoting analog of TPA, also stimulated collagenase production when administered at the same concentrations that were effective for TPA. However, 4-O-methyl TPA and 4-αPDD, two analogs of TPA which are not tumor promoters, did not stimulate collagenase production at concentrations up to 10^?7 M. The collagenase produced by endothelial cells was a typical vertebrate collagenase as judged by the following criteria: it cleaved collagen into only two fragments which were three quarters and one quarter of the length of the intact molecule; it was inhibited by EDTA and human serum; it was not inhibited by inhibitors of serine, thiol or aspartate proteases. Thus TPA causes an increase in the production of latent collagenase by cultured human endothelial cells.     

Gluconeogenesis in isolated intact lamb liver cells. Effects of glucagon and butyrate.

1. Isolated lamb liver cells were prepared from 24-h-starved animals by venous perfusion of the excised caudate lobe with buffer containing collagenase. On the basis of Trypan-Blue exclusion, rate of O2 uptake, adenine nucleotide content and retention of constitutive enzymes, these cells were judged to be intact. 2. Isolated caudate-lobe liver cells showed rates of gluconeogenesis from 10 mM-propionate and 10 mM-lactate that compared favourably with rates determined in isolated median-lobe cells and with rates determined with the isolated perfused lamb liver. 3. The gluconeogenic potential of substrates tested depended on the lamb's age. Cells prepared from suckling lambs (up to 20 days of age and essentially non-ruminant) showed highest rates from galactose, serine and alanine; those prepared from post-weaned lambs (older than 30 days of age and ruminant) showed highest rates from propionate, lactate and fructose. 4. Gluconeogenic rates from endogeneous precursors, 10 mM-propionate and 10mM-galactose, were linear for 1 h and were both stimulated by 1 muM-glucagon. Provided the endogenous rate of gluconeogenesis remained unchanged after substrate addition, glucagon caused a net stimulation of gluconeogenesis from each of these substrates. 5. Gluconeogenic capacity and glucagon sensitivity were examined in cells maintained in substrate-free oxygenated buffer at 37 degrees, 22 degrees and * degrees C. Even under the best of the three conditions of storage that were tested (i.e. at 22 degrees C in gelatin-containing buffer) deterioration of the lamb cells proceeded rapidly, and loss of glucagon responsiveness preceeded the loss of ability to convert precursor into glucose. 6. n-Butyric acid, 2-methylpropanoic acid and 3-methylbutanoic acid at concentrations comparable with those found in lamb portal-vein blood each stimulated gluconeogenesis from 10mM-galactose or 10mM-propionate; gluconeogenesis from galactose was stimulated to the greater extent. 7. The regulatory effects of glucagon and sodium butyrate on lamb liver-cell gluconeogenesis and glycogenolysis were compared. Glucagon (1 muM) and 2mM-butyrate accelerated the rate of glucose formation of liver cells of 24h-starved animals from lactate+pyruvate or fructose. Insulin (20nM) decreased both gluconeogenesis and the efficacy of 1 muM-glucagon. For lactate+pyruvate as substrate, the stimulatory effect of butyrate was additive to that of 1muM-glucagon and for both lactate+pyruvate and fructose the stimulatory effect of butyrate was not influenced by 20nM-insulin. In contrast with glucagon, which stimulated the rate of glycogenolysis in cells prepared from fed lambs, butyrate (0.1-20mM) had no effect. 8. It is concluded that glucagon and butyrate stimulate lamb liver-cell gluconeogenesis by different mechanisms.     

Effects of hormones and of ethanol on the fructose 6-P-fructose 1,6-P2 futile cycle during gluconeogenesis in the liver

Carbon-14 was incorporated into C-6 of glucose from [1-¹⁴C]galactose during gluconeogenesis from dihydroxyacetone in liver cells from fasted rats, proving the existence of a futile cycle between fructose-6-P and fructose-1,6-P₂ under the conditions used. Using a steady-state model and assumed values for the rates of aldolase and glucose-6-P isomerase, the rates of phosphofructokinase were estimated, ranging from about 15% to nearly 40% of the net rate of gluconeogenesis. Glucagon depressed the rate of phosphofructokinase by as much as 85% and increased the rate of gluconeogenesis by up to 45%. l-epinephrine in the range from 10 to 100 μm also depressed phosphofructokinase, being nearly as effective as glucagon only at high concentrations. The effect of epinephrine was only partially reversed by 10 μm dl-propranolol. Ethanol (10 mm) depressed phosphofructokinase flux nearly as well as glucagon, but had no significant effect on the rate of gluconeogenesis from dihydroxyacetone.     

The time course of glucagon action on the utilization of [U-14C]palmitate by isolated hepatocytes

The time course of glucagon action on the utilization of [U-¹⁴C]palmitate by isolated hepatocytes was studied. Ten minutes incubation of the cells after hormone addition was required in order to observe increased oxidation and decreased esterification of the labeled palmitate. The acid-soluble, labeled oxidation products could be separated into two main fractions, glucose and ketone bodies. Initially, glucagon directed the flux of radioactivity toward glucose and CO₂. After prolonged incubation in the presence of glucagon, labeled ketone bodies, as well as labeled glucose and ¹⁴CO₂, were increased. This effect was most marked as regards glucose. The results indicate that glucagon induces a rapidly onset stimulation of the rates of Krebs cycle and gluconeogenesis, while increased oxidation and decreased esterification of palmitate are time-delayed corresponding to the establishment of a lower level of glycerophosphate. About 10% of the glucose carbon formed by gluconeogenesis originated from the fatty acid when cells from fasted rats were incubated in the presence of alanine and [U-¹⁴C]palmitate.     

Purification and properties of a peptic heme peptide from cytochrome c1.

Highly purified mouse liver plasma membranes have been used to define the properties of an NADH dehydrogenase activity associated with plasma membrane. The NADH indophenol reductase activity is two-fold stimulated at 5 × 10^?8 M glucagon and the stimulation is inhibited by atebrin. Corresponding activity in endoplasmic reticulum is not stimulated by glucagon. The NADH indophenol reductase is 90% inhibited by insulin at 7 × 10^?11M and shows a return to the original activity at higher insulin concentrations. NADH dehydrogenase activity in endoplasmic reticulum is inhibited up to 50% by insulin at a similar concentration. Triiodothyronine at 10^?7M also inhibits the plasma membrane dehydrogenase whereas thyroxine has little effect. The response of this dehydrogenase to hormones suggests a role in regulation of cellular function.