Munetaka Morita

Abnormal Lipoprotein Composition in Normolipidemic Diabetic Patients

To see whether there are any lipoprotein abnormalities in diabetic patients without hyperlipidemia, lipoprotein composition was examined in 75 strictly normolipidemic diabetic patients. Their plasma cholesterol (chol) and triglyceride (TG) were limited to <6.0 and <1.7 mM, respectively. Body-weight- and age-adjusted normolipidemic healthy subjects served as the control group. Plasma total chol and TG and low-density lipoprotein (LDL-) and high-density lipoprotein (HDL-) chol were identical in the diabetic and control subjects. Total apolipoprotein B (apoB) in the plasma of the diabetic subjects was significantly elevated. The chol-apoB ratio in the TG-rich (very-low-density + intermediate-density) lipoprotein fraction (Sf 12-400) of the diabetic subjects was significantly higher than the control value, whereas LDL-apoB levels were increased and chol-apoB ratio in the LDL fraction was significantly suppressed in the diabetic subjects. Because each LDL particle contains only one apoB molecule, apoB and chol-apoB ratio in this fraction can represent particle number and chol loading of the LDL particles, respectively. Thus, these data suggest that LDL particle number is increased, and the particles are chol depleted in diabetic subjects even if they are normolipidemic.

Effect of dietary fructose on triglyceride turnover in streptozotocin-diabetic rats

The effects of fructose or glucose on plasma triglyceride kinetics in streptozotocin (40 mg/kg) diabetic rats were studied using Triton WR1339. To separate groups of diabetic rats fructose or glucose was supplied at 10% in drinking water. Diabetic rats without sugar supplementation (diabetic control) had significantly suppressed triglyceride secretion compared to non-diabetic controls. Neither fructose nor glucose supplementation increased the triglyceride secretion rate in diabetic rats. However, despite reduced secretion rates, plasma triglyceride levels in glucose-supplemented diabetic rats, diabetic controls and non-diabetic controls were essentially identical. This suggested that removal of triglyceride from the circulation was impaired in the diabetic rats. In contrast, fructose supplementation resulted in a more than 150% (significant) increase in the mean plasma triglyceride of diabetic rats. The observation of significant hypertriglyceridemia in spite of low triglyceride secretion rate in fructose-supplemented diabetic rats suggests that dietary fructose, but not glucose, interferes with triglyceride removal from the circulation of streptozotocin-diabetic rats. This impairment by dietary fructose is in addition to the impaired triglyceride removal associated with diabetes alone.

Effect of mild diabetes and dietary fructose on very-low-density lipoprotein triglyceride turnover in rats

Very-low-density lipoprotein (VLDL) triglyceride turnover was examined in mildly streptozotocin (25 mg/kg)-diabetic rats, using Triton WR1339. Diabetic rats fed standard rat chow showed mild hyperglycemia and suppressed levels of plasma insulin. Their triglyceride secretion was significantly suppressed despite an elevated level of plasma free fatty acids. However, the plasma triglyceride level of these diabetic rats was significantly elevated compared with nondiabetic controls. This suggested that the removal of triglyceride from the circulation, as well as its entry into the circulation, was impaired in mildly insulin-deficient rats. Glucose or fructose supplementation (10% in drinking water for 14 days) significantly increased the triglyceride secretion rate of diabetic rats. Especially, fructose supplementation increased plasma insulin to normal levels, but resulted in markedly elevated plasma triglyceride levels (three times higher than glucose-supplemented or chow-fed diabetic rats) despite similar triglyceride secretion rates between the two types of sugar-supplemented diabetic rat groups. This suggested an impairment of triglyceride removal by dietary fructose. The result obtained from chow-fed diabetic rats indicates that mild but significant insulin deficiency resulted in mild hypertriglyceridemia, linked to impaired triglyceride removal rather than to an overproduction of VLDL-triglyceride, despite elevated levels of plasma free fatty acids. Furthermore, fructose feeding induced prominent hypertriglyceridemia not only by stimulating triglyceride secretion, but also by suppressing triglyceride removal from the circulation of mildly diabetic rats.

Protective effect of probucol on alloxan diabetes in rats

The diabetogenic action of alloxan is known to be attenuated by several oxygen radical scavengers. The present study was conducted to see if probucol, a drug with strong free radical scavenger action, can reduce pancreatic B-cell damage induced by alloxan in male Wistar rats. After 2 weeks of a 1% probucol diet, 50 mg/kg alloxan was intravenously injected in rats (group PA, n = 34). Urine glucose of most of the injected rats not pretreated with probucol (group A, n = 22) was positive, while more than half of the rats of group PA failed to show urine glucose. The blood glucose level in group PA was significantly lower than that in group A (326 +/- 25 vs. 487 +/- 28 mg/dl, P less than 0.001). Histological examination revealed that most of the pancreatic islets of group A were degranulated, whereas a lot of islets remained unaffected in group PA. Thus, the in vivo diabetogenic action of alloxan was reduced by pretreatment with probucol, although the effect was incomplete. This effect can be explained by probucols strong free radical scavenger action. Since accumulation of free radicals can be an initial step of B-cell damage in animal models of type 1 (insulin-dependent) diabetes, the drug can be useful for the prevention of type 1 diabetes with its long-term clinical history of safety.

Effect of a 3-hydroxy-3-methylglutaryl coenzyme a reductase inhibitor on triglyceride kinetics in chronically streptozotocin-diabetic rats

The effect of simvastatin (MK-733, Banyu, Tokyo, Japan), a new inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase on triglyceride kinetics, was studied in chronically streptozocin-diabetic rats. Diabetic rats, in whom diabetes was induced by a single intravenous injection of streptozotocin (40 mg/kg body weight) 2 months before the experiment, had significantly higher plasma glucose, triglyceride, and cholesterol levels compared with nondiabetic control rats, but triglyceride secretion rate was not increased. Both triglyceride secretion rate and plasma triglyceride level were significantly suppressed under nonfasting conditions in diabetic rats fed a (0.1%) simvastatin-containing diet for 10 days. After an overnight fast, their triglyceride secretion rate was not suppressed by this diet. However, their plasma triglyceride level was significantly (50%) suppressed, suggesting improved triglyceride removal from the circulation. In diabetic rats, the newly secreted triglyceride-rich lipoprotein particles were significantly cholesterol-enriched, but simvastatin had no effect on their lipid composition. These results suggest that the hypertriglyceridemia seen in chronically diabetic rats is mainly due to a triglyceride-removal defect, and that simvastatin reduces plasma triglyceride levels in these rats both by stimulating triglyceride removal and by reducing its entry into the circulation.

Effect of long-term insulin deficiency and insulin treatment on the composition of triglyceride-rich lipoproteins and triglyceride turnover in rats

The effect of long-term (4 months) insulin deficiency on triglyceride turnover was examined using Triton WR1339 in rats. Triglyceride secretion rate was estimated in rats 2 weeks and 4 months after induction of diabetes with 40 mg/kg of streptozotocin. By the second week diabetic rats showed prominent hyperglycemia and the plasma insulin level was very low. In spite of a lower triglyceride secretion rate compared to non-diabetic control rats, diabetic rats showed normotriglyceridemia. Thus, the estimated fractional catabolic rate for plasma triglyceride was decreased in the diabetic rats of 2 weeks duration. By the fourth month diabetic rats still showed a suppressed triglyceride secretion rate but plasma triglyceride was markedly higher than in the non-diabetic control rats. Therefore, their estimated fractional catabolic rate for plasma triglyceride was severely suppressed. They also showed hyperglycemia and hypercholesterolemia. The triglyceride-rich lipoprotein particles obtained after Triton injection in long-term diabetic rats were significantly cholesterol-enriched and triglyceride-depleted compared to control rats. These changes were already present in 2-week diabetic rats but the magnitude was significantly smaller that those in long-term diabetic rats. All of these abnormalities (including triglyceride turnover and the particle composition) were almost normalized by 2 weeks of insulin treatment (6 units/day). Thus, it was concluded from the present data that duration of insulin deficiency is an important determinant of triglyceride removal rate from the circulation in rats. Further modification of lipid composition of triglyceride-rich lipoprotein particles by long-term insulin-deficiency could be one of the reasons for this removal defect.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of probucol on triglyceride turnover in streptozotocin-diabetic rats

The long-term effect of probucol on triglyceride turnover was examined in streptozotocin (40 mg/kg) diabetic rats. Two diabetic groups were prepared: one group received a probucol-containing (1%) diet (probucol-treated diabetic) and the other standard diet (diabetic control). After 4 months of probucol diet, triglyceride turnover was estimated using Triton WR1339. In diabetic control rats, glucose, triglyceride and cholesterol concentrations in plasma and in the very low density lipoprotein (VLDL) fraction were markedly elevated and plasma insulin was suppressed compared to non-diabetic control rats. There was no significant difference in body weight, plasma glucose and insulin between the 2 diabetic groups. However, the probucol-treated diabetic group showed significantly suppressed levels of triglyceride and cholesterol in total plasma and in the VLDL fraction compared to each corresponding diabetic control value. On the other hand, there were no significant differences in triglyceride secretion rate between the 2 diabetic groups. Newly secreted VLDL particles after Triton injection from diabetic control rats were significantly cholesterol-enriched and triglyceride-depleted compared to those from non-diabetic control rats. However, the composition of those from probucol-treated diabetic rats was similar to that of non-diabetic control group. Prominent hypertriglyceridemia without increase in triglyceride secretion rate in diabetic control group indicates triglyceride removal defect in diabetic rats. Significant suppression of plasma triglyceride level without changes in the triglyceride secretion rate in the probucol-treated diabetic group suggests that probucol stimulated triglyceride removal in diabetic rats. Thus, probucol might normalize VLDL composition, thereby contributing to accelerated triglyceride removal from the circulation of streptozotocin diabetic rats without affecting glucose metabolism.

The role of insulin in triglyceride turnover in rats

Exogenously induced hyperinsulinemia can increase in vivo triglyceride production in rats receiving dietary fructose, either as monosaccharide or as sucrose, but not in those receiving only glucose. Thus, in the presence of fructose, but not glucose, insulin stimulates triglyceride production. Dietary fructose can also impair the removal of circulating triglyceride. Exogenous insulin overcomes this fructose-associated impairment of triglyceride removal. On the other hand, streptozotocin-diabetic rats showed a suppressed triglyceride secretion rate (TgSR) but their plasma triglyceride level was unchanged. Therefore, insulin deficiency may result in not only decreased production of triglyceride but also impaired triglyceride removal from the circulation. Fructose-fed diabetic rats showed higher plasma triglyceride levels than chow-fed diabetic rats without a concomitant increase in TgSR, suggesting impaired triglyceride removal from the circulation induced by fructose in diabetic rats. Glucose-fed diabetic rats did not differ in TgSR or plasma triglyceride level from chow-fed diabetic rats. These observations indicate that circulating insulin and dietary fructose, but not glucose, have a key role in very-low-density lipoprotein triglyceride turnover in rats.