P.W. Adams

Integrated regulation of very low density lipoprotein triglyceride and apolipoprotein-B kinetics in man: Normolipemic subjects, familial hypertriglyceridemia and familial combined hyperlipidemia

Turnover kinetics of triglycerides (TG) and apolipoprotein-B (apo-B) of plasma very low density lipoprotein (VLDL) and their relationship to plasma VLDL composition and VLDL apo-B conversion to low density lipoprotein (LDL) were determined in age and weight-matched groups of normolipemic (NL) healthy subjects, patients with familial combined hyperlipidemia (FCHL) and patients with familial hypertriglyceridemia (FHTG). In NL subjects, a significant correlation as observed between VLDL TG or VLDL apo-B turnover rate and its circulating mass, suggesting that the plasma level of VLDL was determined by the secretion rate of VLDL TG and apo-B. The positive significant correlation between VLDL TG and apo-B also suggests that the production of these moieties was integrated at the synthetic and/or secretory sites to maintain the ratio of TG to apo-B in plasma VLDL. In moderately obese NL subjects, proportionate increases in VLDL TG and apo-B turnover rates resulted in enhanced secretion of VLDL particles. Both groups with genetic hypertriglyceridemia had increased VLDL TG and VLDL apo-B turnover rates. This increase accounted for the increase in circulating VLDL TG and apo-B mass. In patients with FCHL, turnover rates of VLDL TG and apo-B were equally increased, hence, the ratios between major VLDL constituents were within normal limits. On the other hand, the increase in VLDL TG turnover in patients with FHTG was disproportionately greater than that of apo-B resulting in a higher ratio of TG to other VLDL components. In NL subjects, approximately 72% of VLDL apo-B released into plasma was converted to LDL. This conversion correlated positively with VLDL apo-B turnover rate and inversely with VLDL TG turnover rate. Formation of LDL from VLDL was significantly greater in the obese individuals. In FCHL, conversion of VLDL to LDL represented the major pathway for VLDL apo-B catabolism. The increased VLDL apo-B load was predominantly catabolized to LDL. The greater increase in VLDL TG turnover relative to apo-B in FHTG, on the other hand, resulted in a smaller fraction of VLDL apo-B recovered in LDL, most of the VLDL apo-B being removed via a pathway that did not involve this conversion. We conclude that the composition and metabolic fate of plasma VLDL may be greatly influenced by the secretion rates of VLDL TG and apo-B. If VLDL conversion to LDL and the subsequent catabolism of the latter provides a major route for delivery of cholesterol ester to peripheral tissues, then the increased LDL production in FCHL compared to FHTG may account for a higher cardiovascular risk.

Integrated Regulation of Very Low Density Lipoprotein Triglyceride and Apolipoprotein-B Kinetics in Non-insulin-dependent Diabetes Mellitus

Turnover rates of plasma very low density lipoprotein (VLDL) triglyceride (TG) and apolipoprotein-B (apo-B) were significantly increased in age- and weight-matched groups of normolipemic and hyperlipemic mild diabetics, and hyperlipemic moderately severe diabetics when compared with normolipemic controls. As in the normolipemic subjects, a significant correlation between VLDL TG and apo-B turnover rates was found in all diabetic groups, suggesting that integration of TG and apo-B production at synthetic and/or secretory sites is retained in diabetes, thus resulting in increased secretion of VLDL particles of normal composition. In normolipemic mild diabetic subjects, the fractional turnover rates of VLDL TG and apo-B were also significantly increased so that increased removal accompanied increased VLDL production. In the hyperlipemic diabetics, however, the fractional turnover rates were significantly reduced, hence the increased in VLDL removal was not sufficient to compensate for enhanced production. In normolipemic mild diabetic patients, low density lipoprotein (LDL) formation was increased, only a small fraction of VLDL apo-B being removed via a non-LDL pathway, presumably as remnant VLDL. In hyperlipemic mild diabetics, removal of VLDL apo-B via both the LDL and non-LDL pathways was increased. In hyperlipemic moderately severe diabetes, LDL formation was not increased; catabolism of VLDL apo-B through the non-LDL route was however, fivefold > normal. We conclude that increased VLDL secretion is a fundamental defect in non-insulin-dependent diabetes. In hyperlipemic individuals, VLDL removal is also impaired. The increase in LDL and/or VLDL remnant formation, regardless of prevailing plasma lipid levels or the severity of diabetes, provides a source of cholesterol which may account for the atherogeneity of this disorder.

Role of insulin resistance in adipose tissue and liver in the pathogenesis of endogenous hypertriglyceridaemia in man.

SummaryStudies were performed to evaluate the relative importance of enhanced adipose tissue lipolysis and increased insulin levels in modulating hepatic VLDL production in patients with endogenous hypertriglyceridaemia. Eight control subjects and nine patients with hypertriglyceridaemia were investigated. The latter group comprised four patients with idiopathic hypertriglyceridaemia, three maturity onset diabetics, and two siblings with diabetic lipodystrophy. Each individuals plasma VLDL was selectively labelled with I131 in the apoprotein moiety and then reinjected to assess the turnover of these molecules. This was correlated with the insulin response to an oral glucose load and with the plasma FFA flux measured by a continuous infusion of14C palmitate. In the patients with idiopathic hypertriglyceridaemia and in the adult onset diabetics, plasma VLDL-apoprotein turnover was increased suggesting enhanced hepatic production of these molecules. Although the insulin levels in these patients were higher than normal, no significant correlation was demonstrable between the plasma insulin and the turnover of VLDL-B-apoprotein. Furthermore, in the two patients with lipo-dystrophy the turnover of plasma VLDL was within the normal range, whereas the plasma insulin responses were the highest among all the patients. These results suggest that hyperinsulinaemia alone is not sufficient to account for the increased VLDL production seen in some of our patients. The plasma FFA flux was raised in the patients with idiopathic hypertriglyceridaemia and in the maturity onset diabetics, and was within the normal range in the two patients with lipodystrophy. Indeed, in all the subjects studied a significant correlation was observed between the turnover of plasma VLDL-B-apoprotein and the plasma FFA flux. The results thus indicate that the rate of FFA release to plasma constitutes the predominant factor in determining hepatic output of VLDL and that in the majority of patients with endogenous hypertriglyceridaemia the increased FFA flux resulting from insulin resistance in adipose tissue could effectively increase VLDL production. This process appears to be independent of the prevailing insulin levels, and could occur in the presence of insulin resistance in the liver. The latter, however, could be responsible for the impaired glucose tolerance observed in some patients.

COMPARISON OF EFFECTS OF DIFFERENT COMBINED ORAL-CONTRACEPTIVE FORMULATIONS ON CARBOHYDRATE AND LIPID METABOLISM

Oral glucose-tolerance tests were performed and fasting serum cholesterol and triglyceride levels measured in 1628 Caucasian women taking combined oestrogen/progestagen oral contraceptives (o.c.) and 577 women not taking O.C. The former were divided into six groups according to the composition of the O.C Glucose tolerance deteriorated in all O.C. groups containing oestrane progestagens (nortestosterone-derived) or the gonane, norgestrel, but was unaltered by O.C. containing a pregnane progestagen (derived from progesterone). The greatest deterioration was with O.C. containing 75 microgram or more oestrogen, and this was associated with impairment of the early insulin response to glucose. In O.C. containing a pregnane progestagen insulin secretion was unaffected. In the remaining O.C. groups insulin secretion was increased; this was most pronounced with the O.C. containing a gonane progestagen. Serum-cholesterol was elevated only with O.C. containing 75 microgram or more oestrogen and an oestrane progestagen and tended to be lower in O.C. containing a gonane progestagen. O.C.-induced hypertriglyceridaemia was oestrogen-dose-related, and this effect was potentiated by the pregnane progestagen. The gonane progestagen antagonised oestrogen-induced hypertriglyceridaemia.

Inter-relationship between insulin secretion and plasma free fatty acid and triglyceride transport kinetics in maturity onset diabetes and the effect of phenethylbiguanide (Phenformin)

SummaryThe plasma free fatty acid and triglyceride transport kinetics in 16 non-obese and 7 obese maturity onset diabetics with hypertriglyceridaemia have been compared with results obtained in 27 control subjects. Changes in glucose and insulin responses were evaluated in relation to the lipid parameters. All the diabetics showed elevated plasma FFA levels and turnover rates. In the non-obese diabetics the plasma triglyceride turnover rate was within the normal range and their hypertriglyceridaemia was due to impaired triglceride clearance. In the obese diabetics the plasma triglyceride turnover rate was increased and they also had some impairment of triglyceride clearance, so that in them a double mechanism was observed to account for their hypertriglyceridaemia. The insulin levels in the diabetics were similar to, or greater than, those found in the controls. Our results suggested that the enhanced lipolysis and impaired triglyceride clearance observed in the diabetic patients were a manifestation of insulin unresponsiveness in adipose tissue and that the changes in insulin and glucose relationship could be secondary to elevated FFA and triglyceride levels. Further confirmation was obtained by the finding of an exaggerated insulin response to a glucose challenge in normal subjects infused with Intralipid. Treatment with phenethylbiguanide (Phenformin) significantly lowered the plasma FFA and triglyceride concentration in both diabetic groups. This was associated with normalisation of both plasma FFA turnover and triglyceride clearance. It also reduced the triglyceride turnover rate to the normal range in the obese diabetics. These changes were associated with a fall of plasma glucose and insulin levels to within the normal range. These results suggested an effect of Phenformin in reducing the rate of lipolysis leading to improved glucose tolerance.

Plasma low density lipoprotein transport kinetics in noninsulin-dependent diabetes mellitus.

Plasma low density lipoprotein (LDL) transport kinetics were determined from the disappearance of 125I-LDL injected into age- and weight-matched groups of 13 normal subjects, 20 mild diabetics, and 8 moderately severe diabetic patients (fasting plasma glucose less than 150 and greater than 150 mg/100 ml, respectively). In mild diabetics, LDL apo-lipoprotein-B (apo-B) synthetic rate (SR) was significantly greater than normal. The fractional catabolic rate (FCR), however, was also increased so that plasma LDL concentration remained normal. In moderately severe diabetics, LDL SR was normal but FCR was reduced resulting in increased plasma LDL cholesterol and apo-B concentrations. In normal subjects, moderate obesity was associated with increased LDL secretion. In diabetic subjects, however, changes in LDL turnover were of equal magnitude in obese and nonobese patients. In normolipemic and hyperlipemic mild diabetic subjects with equal degrees of glucose intolerance, both LDL apo-B SR and FCR were greater than normal. The magnitude of these increases, however, was lower in the hyperlipemic individuals. Stepwise regression analysis revealed that both LDL SR and FCR correlated positively and linearly with insulin response to glucose loading, but negatively and curvilinearly with fasting plasma glucose and glucose response. We propose that in noninsulin-dependent diabetes, mild hyperglycemia is accompanied by increased LDL turnover, despite normal plasma LDL levels, whereas moderately severe hyperglycemia is associated with decreased LDL catabolism, resulting in increased plasma LDL levels. These changes cannot be attributed to the presence of obesity or hypertriglyceridemia, and may relate to varying degrees of insulin resistance and decreased insulin secretion affecting plasma very low density lipoprotein (VLDL) secretion, VLDL conversion to LDL, and LDL catabolism. Both increased LDL turnover in mild diabetes and delayed removal of LDL in moderately severe diabetes could increase cholesterol ester availability to peripheral tissues, and may result in an increased risk of atherosclerosis.

The Mechanism of Action of Clofibrate and Tetranicotinoylfructose (Bradilan) on the Kinetics of Plasma Free Fatty Acid and Triglyceride Transport in Type IV und Type V Hypertriglyceridaemia

Abstract. The kinetics of plasma free fatty acid and triglyceride transport were assessed in 20 patients with idiopathic hypertriglyceridaemia. These patients were subdivided according to lipoprotein pattern into Type IV and Type V patients. The effects of clofibrate therapy on plasma free fatty acid and triglyceride kinetics were assessed in these patients. Clofibrate produced a marked reduction in serum triglyceride associated with a significant reduction in triglyceride turnover as well as enhancement of triglyceride clearance. The reduction in triglyceride concentration produced by clofibrate was found to correlate with the reduction in free fatty acid turnover indicating that this drug decreased the availability of free fatty acid turnover indicating that this drug decreased the availability of free fatty acids for hepatic esterification. Clearance of endogenous plasma triglyceride was markedly enhanced in those patients in whom it was markedly impaired before treatment. – Having discontinued clofibrate for six weeks the same patients received bradilan (tetranicotinoylfructose) and kinetic measurements were repeated. It was evident that bradilan had a greater hypotriglyceridaemic effect than clofibrate in both groups of patients. The effect of bradilan was the result of inhibition of free fatty acid turnover and consequently a marked reduction in triglyceride turnover. Bradilan, unlike clofibrate, did not affect the mechanisms responsible for the clearance of plasma triglycerides.

Transport kinetics of plasma free fatty acid, very low density lipoprotein triglycerides and apoprotein in patients with endogenous hypertriglyceridaemia Effect of 2,2-dimethyl, 5(2,5-xylyloxy) valeric acid therapy

The effects of C1-719 on plasma lipid and lipoprotein concentrations have been examined in four patients with endogenous hypertriglyceridaemia maintained on an isocaloric diet for a period of 6 months. During therapy (400 mg/day) the mean plasma triglyceride and cholesterol concentrations were reduced by 35% and 15% respectively, while the administration of 800 mg/day reduced these by 49% and 31%. This hypolipidaemic effect was due to a reduction in the circulating level of very low density lipoproteins (VLDL) without a change in their composition. Before treatment the plasma VLDL triglyceride turnover, and FFA flux, were higher than that of normal subjects maintained on a similar diet. The plasma VLDL B-apoprotein turnover was similarly higher than in the controls. Administration of C1-719 decreased the plasma VLDL triglyceride turnover, FFA flux and VLDL B-approtein turnover. The drug reduced the insulin response following a glucose load with some decrease in glucose levels. The results suggest that the increase in plasma triglyceride concentration in patients with endogenous hypertriglyceridaemia is due to increased production of plasma VLDL triglyceride and its apoptein associated with an enhanced supply of FFA for hepatic triglyceride synthesis. C1-719 exerts a hypolipidaemic effect through a reduction of VLDL production, consequent upon inhibition of lipolysis as well as decreased synthesis of the apoprotein carrier. These effects could in part be explained by an improvement in peripheral tissue responsiveness to insulin and decreased exposure of the liver to high levels of insulin. However, a direct effect of the drug on adipose tissue and liver metabolism has to be considered.

The Kinetics of Plasma Free Fatty Acid and Triglyceride Transport in Patients with Idiopathic Hypertriglyceridaemia and Their Relation to Carbohydrate Metabolism

Abstract. Plasma free fatty acid and triglyceride transport kinetics were assessed in 20 patients with idiopathic hypertriglyceridaemia. None of these patients had abnormal glucose tolerance. They included 10 patients in whom the serum triglyceride elevation was due to an increase in the circulating VLDL (Fredrickson Type IV) and 10 in whom the increase in plasma VLDL was associated with hyperchylomicronaemia (Fredrickson Type V). These were compared with a control group of 27 normal subjects.–Increased plasma triglyceride turnover with normal clearance was observed in the Type IV patients suggesting that the hypertriglyceridaemia in these patients was predominantly due to enhancement of plasma triglyceride production. The plasma triglyceride concentration correlated closely with the changes in triglyceride turnover rate.–Studies performed in the Type V patients showed an increase in the plasma triglyceride turnover rate in only 3 subjects, while in the remaining patients the turnover values were similar to those of the control subjects. The increase in serum triglyceride concentration found in some of the patients was due to an increase in plasma triglyceride production. However, in the majority of patients in this group impairment of plasma triglyceride clearance was the predominant abnormality.–In both hypertriglyceridaemic groups the plasma FFA flux was markedly increased and correlated significantly with the degree of hypertriglyceridaemia. The increase in triglyceride turnover observed in Type IV patients and some of the Type V patients correlated closely with the enhancement of plasma FFA flux suggesting that the increase in triglyceride production in these patients was secondary to enhanced lipolysis.–The plasma insulin response to an oral glucose load was markedly increased in both groups of hypertriglyceridaemic patients and correlated significantly with the elevation in serum triglyceride concentration. The plasma insulin response also correlated with the plasma free fatty acid turnover.–The results suggest that the initial lesion in these patients was related to insulin unresponsiveness in adipose tissue resulting in enhanced lipolysis with secondary changes in insulin secretion and plasma triglyceride transport kinetics.

The metabolic fate of plasma lipoproteins in normal subjects and in patients with insulin resistance and endogenous hypertriglyceridaemia.

SummaryUsing I131 VLDL selectively labelled in the B-apoprotein and I125 LDL injected simultaneously into the patient we have derived some quantitative measures of VLDL and LDL metabolism in man. The effects of insulin resistance, associated with idiopathic hypertriglyceridaemia, adult onset diabetes and diabetic lipodystrophy on the metabolic behaviour of these molecules were also assessed. In the normal subjects 72–83% of the total daily plasma VLDL B-apoprotein flux was metabolised via a pathway which involved its ultimate conversion to plasma LDL, while 21–28% was degraded without such conversion. The amount of B-apoprotein metabolised by either of these routes was proportionate to the flux rate and the two pathways accounted for the total VLDL B-apoprotein removed from the plasma. In patients with idiopathic hypertriglyceridaemia and in the adult onset diabetics the total plasma VLDL B-apoprotein flux was higher than normal, indicating increased production of this apoprotein. On the other hand, the flux rate of plasma VLDL B-apoprotein in the patients with diabetic lipodystrophy was normal, suggesting that the increase in the circulating mass of these molecules was due to impaired clearance. In all the patients, however, the fractions of the total flux either converted to LDL or degraded were lower than normal, suggesting that insulin resistance limited the removal of this apoprotein by these pathways. The results also indicate that a fraction of the total VLDL removed from the plasma has been retained in an extravascular compartment, possibly representing VLDL molecules trapped in the vascular structures. In the control and the insulin resistant subjects the quantity of LDL apoprotein catabolised per day agreed closely with the amount derived from VLDL B-apoprotein conversion, suggesting that VLDL-B-apoprotein serves as the main source of LDL apoprotein. In patients with idiopathic hypertriglyceridaemia and in adult onset diabetics the absolute turnover rate of plasma LDL apoprotein was higher than normal, while in the lipodystrophic patients it was reduced. It is suggested that the increase in LDL turnover seen in the former groups could be an additive factor in the deposition of lipid rich material in arterial walls.