The effect of induced hyperglucagonaemia on the Zucker fatty rat

Age-related changes in insulin receptor mRNA and protein expression in genetically obese Zucker rats

AIM

The mechanisms underlying the age-related decrease in insulin-receptor (IR) binding in genetically obese Zucker rats are not well understood. For this reason, the present study analyzed the expression of IR mRNA and protein in selected tissues from 1- to 4-month-old obese (fa/fa) Zucker rats and lean (Fa/-) age-matched controls.

METHODS

The following parameters were evaluated: (1) IR mRNA level, and proportion of isotypes A (exon 11-) and B (exon 11+) of IR mRNA in liver, brain and kidney; (2) level, molecular size and tyrosine phosphorylation of IR-beta subunit in liver subcellular fractions; and (3) stability of liver IR based on sensitivity in vivo of insulin-binding activity and IR-beta levels in response to tunicamycin, a glycosylation inhibitor.

RESULTS

At one month, IR mRNA level was increased in liver and brain, but decreased in kidneys and, at four months, both mRNA level and isotype B proportion were decreased in liver. From age two months, the following changes in liver IR protein expression were observed: (1) decreased IR-beta level in whole homogenates, but increased IR-beta levels in endosomal fractions; (2) increased IR-beta tyrosine phosphorylation; and (3) at four months, increased levels of both intact IR-beta (95 kDa) and IR-beta fragments (72 and 52 kDa) in lysosomal fractions, along with decreased stability in vivo of the IR.

CONCLUSION

These data show that obese Zucker rats display age-related alterations of IR gene expression at both pre- and post-translational stages and, in particular, increased endocytosis and degradation of IR protein.

Inhibition of hepatic very-low-density lipoprotein secretion in obese Zucker rats adapted to a high-protein diet

The effect of a high-protein (HP) diet on hepatic very-low-density lipoprotein (VLDL) secretion was studied in obese and lean Zucker rats. With the control (C) diet, isolated hepatocytes from obese as compared with lean rats displayed higher uptake of [1-14C]oleate 0.7 mmol/L, 95% of which was esterified to glycerolipids; greater oleate incorporation into VLDL-triacylglycerol (TG); 2.6 times higher total VLDL-TG secretion; and 11-fold higher de novo fatty acid synthesis. Adaptation to HP feeding decreased weight gains in both phenotypes and hepatocyte TG content in obese rats. Oleate uptake by hepatocytes was appreciably reduced in the obese phenotype only. Despite esterification rates similar to those for the C diet, oleate incorporation into VLDL-TG decreased by 34% and 55% in obese and lean rats, respectively. Total (mass) VLDL-TG secretion was drastically decreased by 65% and 48% in obese and lean rat hepatocytes, respectively. HP feeding combined with overnight fasting accentuated the above decreases. Fatty acid synthesis was 50% lower in cells from HP-fed obese rats, but increased 1.7-fold in lean ones. Plasma glucagon increased in both phenotypes under HP feeding, whereas plasma insulin either increased (obese) or decreased (lean), with the insulin to glucagon ratio slightly decreasing. Thus, HP feeding drastically inhibited hepatic VLDL secretion in obese and lean Zucker rats by an undefined mechanism that was apparently related neither to de novo fatty acid synthesis nor to changes in oleate partitioning between esterification and oxidation.

Effect of feed deprivation on hepatic membrane and lipoprotein fluidity and binding of lipoproteins to hepatic membranes in the chick (Gallus domesticus)

1. Male chicks were deprived of feed for 48 hr to study the effect of metabolic stress on hepatic membrane and lipoprotein fluidity and binding of radioiodinated lipoproteins to hepatic membranes. 2. Plasma levels of low density lipoprotein (LDL) and high density lipoprotein (HDL) were markedly and slightly elevated, respectively. 3. There was a reduction in lipoprotein and hepatic membrane fluidity. 4. Binding of [125I]LDL, but not [125I]HDL, to hepatic membranes was decreased. 5. It is suggested that a reduction in the fluidity of LDL and/or hepatic membranes impedes LDL catabolism in vivo.

Dietary and hormonal regulation of aldolase B gene expression

Aldolase B is an enzyme of the glycolytic pathway whose activity and mRNA levels in the liver fluctuate according to dietary status. Both the enzyme activity and the mRNA concentration decline during fasting and increase four- to eightfold upon refeeding of a carbohydrate-rich diet. The mechanism, however, of the mRNA induction remains unknown. To elucidate the mechanisms that regulate this induction responsive to dietary stimuli, we have studied the roles of hormones and glycolytic substrates on aldolase B gene expression in three tissues that synthesize the enzyme. Using a cDNA probe complementary to rat aldolase B mRNA, we determined the amount of cytoplasmic RNAs in the liver, kidney, and small intestine of normal, adrenalectomized, thyroidectomized, diabetic, and glucagon- or cAMP-treated animals refed either a fructose-rich or a maltose-rich diet. The in vivo hormonal control of gene expression was found to be very different in the three organs tested. In the liver, cortisone and thyroid hormones were required for the induction of the specific mRNA by carbohydrates, while in the kidney none of the hormonal modifications tested altered the level of mRNA induction. In the liver, but not in the kidney, diabetes and glucagon administration abolished the induction of aldolase B mRNAs in animals refed the maltose-rich diets. In the small intestine, only diabetes and thyroidectomy affected the gene expression. Finally, no induction occurred when normal fasted rats were given any of the hormones. Thus, the in vivo hormonal control of liver aldolase B gene expression differs significantly from that of kidney and small intestine. In the liver, the mRNA induction requires the presence of dietary carbohydrates, of permissive hormones, and the cessation of glucagon release, while in the kidney, the induction of the mRNAs by fructose occurs regardless of the hormonal status of the animals. The hormonal control of aldolase B mRNA levels in the small intestine is intermediate.

Suppression of weight gain by glucagon in obese Zucker rats

Glucagon has been shown to lower blood lipids and to decrease food intake and body weight in short-term studies in man and animals. There is evidence of decreased secretion of glucagon in human obesity. The Zucker obese rat suffers from a genetic type of obesity and has an absolute reduction in circulating glucagon concentration. The effect of long-term administration of glucagon on the body weight in obese Zucker rats was studied. Glucagon caused a marked (-20%) reduction of body weight in obese Zucker rats with no change in feed intake. Urine glucose, urea nitrogen, creatinine, and ketone content, as well as serum triglyceride, cholesterol, alkaline phosphatase, creatinine, and insulin levels remained unchanged. Weights of perirenal fat, kidneys, and heart also remained unchanged. However, glucagon injection in obese Zucker rats caused significant decrease in serum glucose, and increases in SGOT, liver weight, and liver lipid and glycogen content. Further investigations are needed concerning the safety of chronic glucagon administration for weight control.

Regulation of hepatic tyrosine aminotransferase in genetically obese rats

The activities of hepatic tyrosine aminotransferase, tryptophan oxygenase and serine dehydratase were increased in obese rats shortly after weaning. Immunotitration experiments showed that the increase in tyrosine aminotransferase activity resulted from an increase in enzyme protein in obese rats. No increase in hepatic tyrosine aminotransferase was observed in suckling pre-obese rats. The post-weaning increase in hepatic tyrosine aminotransferase of obese rats was only observed during the light phase of the diurnal cycle, but was prevented by pair-feeding and by starvation. Tryptophan increased hepatic tyrosine aminotransferase of lean rats to obese levels but had no effect in obese rats until tyrosine aminotransferase levels were reduced by starvation or adrenalectomy. Adrenalectomy abolished the increase in hepatic tyrosine aminotransferase activity in obese rats although serum corticosterone was normal in these animals. Hepatic and brain tyrosine concentrations were decreased in obese rats but normalized after adrenalectomy. The results suggest that the corticosteroid-dependent increase in food and tryptophan intake may be the primary cause of the increased hepatic amino acid catabolism of obese rats.

Oxidation and ketogenesis in hepatocytes of lean and obese Zucker rats

Ketone body production and oxidation of 14C fatty acids to CO2 were measured in hepatocytes isolated from lean and obese Zucker rats. The oxidation of [1-14C]octanoate, [1-14C]palmitate and [1-14C]palmitoyl carnitine to 14CO2 was 50%--70% less in obese than in lean rats. Although ketone body production in hepatocytes from both lean and obese rats was increased by fasting, there was a significantly lower rate of ketone body production in hepatocytes from obese rats. Ketone body production was reduced to a comparable extent by increasing the glucose concentration in the incubation media of hepatocytes from both lean and obese rats. Glucagon and carnitine increased ketogenesis and the effect were additive and similar in lean and obese rats. These data suggest that beta-oxidation and ketogenesis are suppressed in the obese Zucker rat, and further that ketone bodies can be modulated similarly in hepatocytes from lean and obese rats by nutritional and hormonal intervention. It is postulated that the decreased beta-oxidation and ketone body production may play a role in the development or maintenance of obesity in the Zucker rat.

Comparative studies on fatty acid synthesis, glycogen metabolism, and gluconeogenesis by hepatocytes isolated from lean and obese Zucker rats

Hepatocytes isolated from genetically obese female Zucker rats and lean female Zucker rats were compared. Hepatocytes from fed obese rats exhibited greater rates of fatty acid synthesis, more extensive accumulation of lactate and pyruvate from their glycogen stores, increased rates of net glucose utilization but produced less ketone bodies from exogenous fatty acids and had lower citrate levels than hepatocytes from lean rats. Lipogenesis was not as sensitive to dibutyryl cyclic AMP (DBcAMP) inhibition in hepatocytes from obese rats but glycogenolysis was stimulated to the same extent by this nucleotide in both preparations. Ketogenesis was less sensitive to stimulation by DBcAMP in hepatocytes from obese rats. A difference in sensitivity of lipogenesis to DBcAMP was not found when lactate plus pyruvate was added to the incubation medium, suggesting that a greater rate of glycolysis by hepatocytes from obese rats accounts for their relative insensitivity to DBcAMP. Citrate levels were elevated by DBcAMP to a greater extent in hepatocytes from obese rats. Hepatocytes prepared from lean rats starved for 48 hr were glycogen depleted and lacked significant capacity for lipogenesis and glycogen synthesis. In contrast, hepatocytes isolated from starved obese rats retained considerable amounts of liver glycogen and exhibited detectable rates of lipogenesis and glycogen synthesis. Hepatocytes prepared from starved lean rats gave faster apparent rates of lactate gluconeogenesis than hepatocytes prepared from starved obese rats. Thus, hepatocytes prepared from obese Zucker rats are more glycogenic, glycolytic, and lipogenic but less ketogenic and glucogenic than hepatocytes prepared from lean rats.

The metabolism of 125I-labelled insulin by isolated Zucker rat hepatocytes

The metabolism of 125I-labelled insulin by hepatocytes isolated from 48-h-starved Zucker lean and obese rats was studied. Hepatocytes from the lean animals bound significantly more 125I-labelled insulin and had a greater receptor number per cell than did cells from obese littermates. Hepatocytes from the lean animals degraded and internalized more hormone than did those from obese ones. Increased degradation and internalization correlated with the increased receptor number.

Regulation of lipid synthesis in hepatocytes from lean and obese Zucker rats

Fatty acid synthesis and CO2 production were evaluated in hepatocytes from lean and obese Zucker rats in the presence of 3H2O, and several carbon precursors. The incorporation of 3H2O into fatty acids was greater in obese compared to lean rats in both the isolated hepatocyte and in vivo. The rates of incorporation of 3H2O into fatty acids and cholesterol in hepatocytes of both lean and obese rats were linear for 2 hr, in the absence or presence of 16.7 mM glucose. Rates of fatty acid synthesis were higher in the presence of 16.7 mM glucose compared to the absence of glucose in both lean and obese while rates of cholesterol synthesis were similar. The incorporation of 3H2O into fatty acids, but not into cholesterol, was correlated with increasing glucose concentration and was 2 to three-fold higher in hepatocytes of obese compared to lean rats in the presence of several carbon precursors. Differences in CO2 production between lean and obese rats suggested increased pentose phosphate shunt activity, decreased pyruvate dehydrogenase activity, and lower tricarboxylic acid cycle activity in obese rats. Fatty acid synthesis and CO2 production from 3H2O and [U-14C]glucose in hepatocytes of lean and obese rats was similarly elevated by insulin and depressed by glucagon at several concentrations, suggesting that hepatocytes of obese animals respond to these hormones. These data indicate that rates of hepatic fatty acid synthesis although higher in obese rats respond to modulation in a fashion which is similar to the response in lean rats. The present studies suggest that the oxidation of several carbon precursors in the tricarboxylic acid cycle is diminished in obese compared to lean rats, but pentose phosphate shunt activity is greater in the obese Zucker rats.

Lipoprotein lipase activities in adipose tissues and muscle in the obese Zucker rat

Activity of lipoprotein lipase (LPL) was determined in whole adipose tissue and isolated adipocytes, and in heart and skeletal muscle that contained predominantly red or white fiber types in lean and obese Zucker rats. In rats of both sexes at 9-11 and 26-30 wk of age, no differences were observed between lean and obese rats when LPL activity of the perirenal (PR), subcutaneous (SC), and mesenteric (M) adipose tissues was expressed per millimole of tissue triglyceride. Within each sex, data relating the LPL content of isolated adipocytes to cell size was a linear function in which data for lean and obese rats fell on the same regression line. Measurement of the distribution of adipose tissue LPL activity between adipocytes and other tissue constituents showed no differences between lean and obese rats, a finding that is inconsistent with the hypothesis that obesity results in part by an alteration in adipose tissue enzyme distribution. Activity of LPL in the myocardium and red fiber types in the younger group of both sexes showed significant decreases in obese animals. This was also true for white fibers of males but not females. No differences in heart or muscle LPL between lean and obese rats were observed in the older group of either sex.

Impairment of hormone-stimulated cardiac adenylate cyclase activity in the genetically obese (fa/fa) Zucker rat

The age-related development of the capacity of the cardiac adenylate cyclase system to be stimulated with secretin, vasoactive intestinal peptide (VIP), glucagon, the beta-adrenergic agonist isoproterenol, Gpp(NH)p, and NaF was compared in obese (fa/fa) Zucker rats and their lean (FA/?) littermates. The obese (fa/fa) Zucker rats tested developed postweaning obesity associated with marked hypertriglyceridemia, mild hyperglycemia, and hyperinsulinism. At 4 weeks, there was already a 57% reduction in secretin-VIP-stimulated adenylate cyclase activity in fa/fa rats. At 12 weeks, the secretin-VIP-stimulation was reduced by 77%, and glucagon- and isoproterenol-stimulations by 16-21%. At 45 weeks, secretin-VIP-stimulation was reduced by 91%, glucagon- and isoproterenol stimulations by 34-42%, and Gpp(NH)p- and NaF-stimulations by 16-23%. The reductions of isoproterenol-, Gpp(NH)p-, and NaF-stimulations were totally or partially reversed in 30-week old fa/fa animals submitted for 5 weeks to severe food restriction that almost normalized the altered blood parameters. In sharp contrast, food restriction imposed a further decrease in secretin-VIP- and glucagon-stimulated adenylate cyclase activities. This pattern of impaired secretin-VIP-stimulated adenylate cyclase activity appeared limited to cardiac membranes in obese animals as the responses of liver, brain and anterior pituitary adenylate cyclase activities to secretin and/or VIP were unaltered. These results suggest that secretin-VIP receptors coupled to adenylate cyclase were rapidly and specifically altered in the heart of fa/fa Zucker rats.