糖尿病的脂代谢紊乱

糖尿病的心血管并发症是糖尿病患者寿命的严重威胁，其脂肪代谢紊乱可能在动脉粥样硬化的发生，发展中起了重要的作用。糖水病脂代谢紊乱主要表现为甘油三酯（TG）的升高，这与极低密度脂蛋白（VLDL）升高以及高密度脂蛋白（HDL－C）的降低有关，血浆富含TG的脂蛋白的增加与肝内VLDL的产生增加及清除降低有关。脂蛋白质的异常包括：脂蛋白体积的变化（如大的VLDL，小的LDL），载脂蛋白的糖化以及LDL对氧化敏感性的增加，这些脂蛋白的质的异常损害了脂蛋白的正常代谢，并促进动脉粥样硬化。本文重点讨论了脂代谢紊乱对糖尿病及并发症的作用以及糖尿病患者如何控制脂代谢异常等问题。     

Overproduction of very low-density lipoproteins is the hallmark of the dyslipidemia in the metabolic syndrome

Insulin resistance is a key feature of the metabolic syndrome and often progresses to type 2 diabetes. Both insulin resistance and type 2 diabetes are characterized by dyslipidemia, which is an important and common risk factor for cardiovascular disease. Diabetic dyslipidemia is a cluster of potentially atherogenic lipid and lipoprotein abnormalities that are metabolically interrelated. Recent evidence suggests that a fundamental defect is an overproduction of large very low-density lipoprotein (VLDL) particles, which initiates a sequence of lipoprotein changes, resulting in higher levels of remnant particles, smaller LDL, and lower levels of high-density liporotein (HDL) cholesterol. These atherogenic lipid abnormalities precede the diagnosis of type 2 diabetes by several years, and it is thus important to elucidate the mechanisms involved in the overproduction of large VLDL particles. Here, we review the pathophysiology of VLDL biosynthesis and metabolism in the metabolic syndrome. We also review recent research investigating the relation between hepatic accumulation of lipids and insulin resistance, and sources of fatty acids for liver fat and VLDL biosynthesis. Finally, we briefly discuss current treatments for lipid management of dyslipidemia and potential future therapeutic targets.     

Anomalies of lipid metabolism in diabetes mellitus]

Atheroma is by far the most common cause of mortality in diabetic patients (66 to 75% of deaths). Several physiopathological mechanisms are suspected to account for the greater frequency and severity of atheroma in diabetes. Among these, lipid abnormalities hold first rank and include not only quantitative but also qualitative abnormalities of lipoproteins altering their kinetics and bindings to membrane receptors. The main quantitative abnormalities are an increase of triglycerides and very low density lipoproteins (VLDL) and a fall in high density lipoproteins (HDL) and their HDL2 subfraction. Qualitative abnormalities include non-enzymatic glucosylation of apoproteins, changes in lipoprotein size and increase in their triglyceride content, and excessive oxidation of low density lipoproteins (LDL). Both quantitative and qualitative abnormalities of lipoproteins are present in non-insulin-dependent diabetes, whereas only qualitative abnormalities are observed, as a rule, in treated insulin-dependent diabetes. The physiopathology of lipid metabolism disorders is complex, possibly multifactorial and still imperfectly known. However, such factors as modification of insulin status, hyperglycaemia and obesity frequently associated with diabetes, are thought to be involved.     

Diabetic dyslipidemia

Diabetic dyslipidemia is characterized by elevated fasting and postprandial triglycerides, low HDL-cholesterol, elevated LDL-cholesterol and the predominance of small dense LDL particles. These lipid changes represent the major link between diabetes and the increased cardiovascular risk of diabetic patients. The underlying pathophysiology is only partially understood. Alterations of insulin sensitive pathways, increased concentrations of free fatty acids and low grade inflammation all play a role and result in an overproduction and decreased catabolism of triglyceride rich lipoproteins of intestinal and hepatic origin. The observed changes in HDL and LDL are mostly sequence to this. Lifestyle modification and glucose control may improve the lipid profile but statin therapy mediates the biggest benefit with respect to cardiovascular risk reduction. Therefore most diabetic patients should receive statin therapy. The role of other lipid lowering drugs, such as ezetimibe, fibrates, omega-3 fatty acids, niacin and bile acid sequestrants is less well defined as they are characterized by largely negative outcome trials. This review examines the pathophysiology of diabetic dyslipidemia and its relationship to cardiovascular diseases. Management approaches will also be discussed.     

Plasma lipoprotein abnormalities associated with acquired hepatic triglyceride lipase deficiency

Two enzymes, lipoprotein lipase (LPL) and hepatic triglyceride lipase (HTGL), are released into human plasma after intravenous injection of heparin. LPL is the major enzyme responsible for initiating catabolism of chylomicrons and very-low-density lipoproteins (VLDL). The physiological role of HTGL is less certain. HTGL has been postulated to be an alternate enzyme to LPL in hydrolysis of triglyceride in VLDL and to be an important enzyme for removal of phospholipid from both low-density lipoproteins (LDL) and high-density lipoproteins (HDL). In this latter role, this enzyme would convert larger, lighter lipoprotein particles to smaller denser particles. HTGL deficiency has been found in severe liver disease and with a genetic deficiency of this enzyme. A unique patient is described with acquired hepatic triglyceride lipase deficiency and vitamin A intoxication. This patient developed hypercholesterolemia with an increase in both LDL and HDL. An increased proportion of lighter LDL (LDL1) and HDL (HDL2) was noted. In addition, after administration of heparin there was no shift in the distribution of apoE in plasma fractionated using a column containing 4% agarose. These findings are consistent with a postulated role of HTGL in metabolism of light LDL and HDL particles and some classes of apoE containing lipoproteins.     

Atherogenic role of elevated CE transfer from HDL to VLDL(1) and dense LDL in type 2 diabetes : impact of the degree of triglyceridemia

Plasma cholesteryl ester transfer protein (CETP) facilitates intravascular lipoprotein remodeling by promoting the heteroexchange of neutral lipids. To determine whether the degree of triglyceridemia may influence the CETP-mediated redistribution of HDL CE between atherogenic plasma lipoprotein particles in type 2 diabetes, we evaluated CE mass transfer from HDL to apoB-containing lipoprotein acceptors in the plasma of type 2 diabetes subjects (n=38). In parallel, we investigated the potential relationship between CE transfer and the appearance of an atherogenic dense LDL profile. The diabetic population was divided into 3 subgroups according to fasting plasma triglyceride (TG) levels: group 1 (G1), TG<100 mg/dL; group 2 (G2), 100200 mg/dL. Type 2 diabetes patients displayed an asymmetrical LDL profile in which the dense LDL subfractions predominated. Plasma levels of dense LDL subfractions were strongly positively correlated with those of plasma triglyceride (TG) (r=0.471; P:=0.0003). The rate of CE mass transfer from HDL to apoB-containing lipoproteins was significantly enhanced in G3 compared with G2 or G1 (46.2+/-8.1, 33.6+/-5.3, and 28.2+/-2.7 microg CE transferred. h(-1). mL(-1) in G3, G2, and G1, respectively; P:<0.0001 G3 versus G1, P:=0.0001 G2 versus G1, and P:=0.02 G2 versus G3). The relative capacities of VLDL and LDL to act as acceptors of CE from HDL were distinct between type 2 diabetes subgroups. LDL particles represented the preferential CE acceptor in G1 and accounted for 74% of total CE transferred from HDL. By contrast, in G2 and G3, TG-rich lipoprotein subfractions accounted for 47% and 72% of total CE transferred from HDL, respectively. Moreover, the relative proportion of CE transferred from HDL to VLDL(1) in type 2 diabetes patients increased progressively with increase in plasma TG levels. The VLDL(1) subfraction accounted for 34%, 43%, and 52% of total CE transferred from HDL to TG-rich lipoproteins in patients from G1, G2, and G3, respectively. Finally, dense LDL acquired an average of 45% of total CE transferred from HDL to LDL in type 2 diabetes patients. In conclusion, CETP contributes significantly to the formation of small dense LDL particles in type 2 diabetes by a preferential CE transfer from HDL to small dense LDL, as well as through an indirect mechanism involving an enhanced CE transfer from HDL to VLDL(1), the specific precursors of small dense LDL particles in plasma.     

Effect of low protein diet, plus essential amino acids on lipid metabolism in patients with chronic renal failure

We investigated lipoprotein profile of 18 non-dialysis patients with CRF and 17 patients on hemodialysis, and studied effect of LPD plus EAA on lipid metabolism of 18 non-dialysis patients with CRF. The results revealed that total triglyceride, cholesterol, LDL, VLDL, and semi-quantity of ApoCII, ApoCIII were significantly increased, and HDL, ApoAI ApoAI/ApoB rate, semiquantify of ApoCI were significantly reduced in non-dialysis patients and patients on hemodialysis; VLDL and Ccr were closely negative related in non-dialysis patients. The lipid abnormalities were more severe in non-dialysis patients complicated with hypertension than without hypertension. After 6 to 10 weeks' LPD plus EAA treatment in 18 non-dialysis patients, total triglyceride, cholesterol, LDL, VLDL were significantly reduced, and HDL, ApoAI, ApoAI/ApoB were significantly increased. We conclude that it is characterized by type IV hyperlipidemia in lipid abnormalities of patients with CRF, and LPD plus EAA treatment may improve it effectively.     

Lipid disorders in type 1 diabetes

Patients with type 1 diabetes (T1D) also present with lipid disorders. Quantitative abnormalities of lipoproteins are observed in T1D patients with poor glycaemic control (increased plasma triglycerides and low-density lipoprotein [LDL] cholesterol) or nephropathy (increased triglycerides and LDL cholesterol, low level of high density lipoprotein [HDL] cholesterol). In cases of T1D with optimal glycaemic control, plasma triglycerides and LDL cholesterol are normal or slightly decreased, while HDL cholesterol is normal or slightly increased. Several qualitative abnormalities of lipoproteins, which are potentially atherogenic, are observed in patients with T1D, even in those with good metabolic control. These abnormalities include increased cholesterol-to-triglyceride ratios within very low-density lipoprotein (VLDLs), increased triglycerides in LDLs and HDLs, compositional changes in the peripheral layer of lipoproteins, glycation of apolipoproteins, increased oxidation of LDLs and an increase in small, dense LDL particles. These qualitative changes in lipoproteins are likely to impair their function. In vitro, VLDLs and LDLs from patients with T1D induced abnormal responses in the cellular cholesterol metabolism of human macrophages. HDLs from patients with T1D are thought to be less effective in promoting cholesterol efflux from cells, and have been shown to have reduced antioxidative and vasorelaxant properties. These qualitative abnormalities are not fully explained by hyperglycaemia and may be partly due to peripheral hyperinsulinaemia associated with subcutaneous insulin administration. However, the precise consequences of these qualitative lipid changes on the development of cardiovascular disease in T1D are, as yet, unknown.     

Normal metabolism of apolipoprotein B100-containing lipoproteins despite qualitative abnormalities in type 1 diabetic men

Aims/hypothesis Type 1 diabetic subjects are at increased risk of cardiovascular disease and exhibit multiple qualitative abnormalities of apolipoprotein (apo) B100-containing lipoproteins. This stable isotope kinetic experiment was designed to study whether these abnormalities are associated with changes in the synthesis and fractional catabolic rates of VLDL-, IDL- and LDL-apoB100.Methods Using a bolus followed by a 16-h constant infusion of ¹³C-leucine, we performed a kinetic study in eight men with type 1 diabetes treated with a continuous subcutaneous insulin infusion administered by an external pump and in seven healthy men, in the fed state.Results The mean HbA₁c level in the type 1 diabetic patients was 8.00±1.48%. Plasma triglyceride, and total, LDL and HDL cholesterol levels were similar in patients and control subjects. VLDL were less triglyceride rich in type 1 diabetic patients than in control subjects (VLDL triglyceride : apoB 6.91±0.81 vs 8.29±1.24 mmol/g, p=0.05). Conversely, the IDL and LDL of the type 1 diabetic patients contained relatively higher levels of triglycerides (IDL triglycerides : apoB 2.16±0.36 vs 1.57±0.30 mmol/g, p<0.01; LDL triglycerides : apoB 0.27±0.06 vs 0.16±0.04 mmol/g, p<0.05). The apoB100 pool size, production and fractional catabolic rates in the two groups of subjects were similar for all lipoprotein fractions.Conclusions/interpretation Despite qualitative abnormalities, especially abnormalities of triglyceride content, the metabolism of apoB100-containing lipoproteins is not altered in type 1 diabetic men with fair glycaemic control with continuous subcutaneous insulin infusion. The high risk of atherosclerosis in these patients cannot be explained by kinetic abnormalities of apoB100-containing lipoproteins.     

Lipid composition of serum lipoproteins in patients with primary type IIb and type IV hyperlipoproteinemia.

Cholesterol, triglyceride and phospholipid concentrations of VLDL, LDL and HDL were studied in 20 patients with primary type IIb, 25 patients with primary type IV and in 18 controls. Both types are not only characterized by different concentrations of lipoprotein lipids, but also by their different lipid composition. Type IIb had more triglycerides in the LDL, type IV in the LDL and HDL. The HDL cholesterol content of type IV was decreased. The percent phospholipid concentration of HDL was identical in the 3 groups, demonstrating the constant role of this lipid fraction. The lipid relationships between the lipoproteins showed that the LDL/HDL lipid ratio of type IIb exceeded type IV ratio in spite of normal HDL lipid concentration in type IIb.     

Postprandial lipemia: an under-recognized atherogenic factor in patients with diabetes mellitus

Atherosclerotic disease is the leading cause of both morbidity and mortality in patients with type 2 diabetes. In these patients, postprandial dyslipidemia include not only quantitative but also qualitative abnormalities of lipoproteins which are potentially atherogenic and seems to be a significant risk factor for cardiovascular disease since there is evidence that it results in endothelial dysfunction and enhanced oxidative stress. The most common pattern of postprandial dyslipidemia in diabetes consists of high concentrations of triglycerides, higher VLDLs production by the liver and a decrease in their clearance, a predominance of small dense LDL particles, and reduced levels of HDL. The cause of this postprandial dyslipidemia in diabetes is complex and involves a variety of factors including hyperinsulinemia, insulin resistance, hyperglycemia and disturbed fatty acid metabolism. Numerous clinical studies have shown that postprandial dyslipidemia is associated with endothelial dysfunction in type 2 diabetes and with alterations in other surrogate markers in the cascade of atherosclerosis. Current published guidelines indicate that in diabetics the primary lipid target is LDL<100 mg/dL (70 mg/dL in very high-risk patients) and the most appropriate class of drugs are statins although the issue of postprandial dyslipidemia has not been specifically addressed so far. Moreover, several other classes of medications (fibrates, niacin and antidiabetic drugs) as well as non-pharmacological interventions (i.e. diet, smoking cessation and exercise) can be used to treat lipid and lipoprotein abnormalities associated with insulin resistance and type 2 diabetes. These type of interventions may be more appropriate to ameliorate postprandial dyslipidemia. However, this remains to be confirmed on clinical grounds.     

Lipoprotein composition in diabetes mellitus.

Lipoprotein cholesterol and triglyceride levels have been determined in normal and diabetic Pima Indian women aged 20-35, HDL cholesterol levels were lower, LDL cholesterol levels were higher, and the ratio of HDL cholesterol/LDL cholesterol, a reflection of lipoprotein cholesterol distribution, was lower in the diabetics compared to the normals. VLDL triglyceride levels were also elevated in the diabetics. An analysis of lipoprotein composition suggested that these changes primarily reflect changes in numbers of particles, since lipid composition and lipid/protein ratios were similar in lipoproteins isolated from normals and diabetics. The ratio of ester/free cholesterol in LDL and HDL was lower in normal Pima Indians than in a comparable group of Caucasians, although plasma LCAT activity was not significantly different. The data indicate that diabetes may be associated with shifts in distribution of LDL and HDL, as well as with increases in VLDL.     

Gemfibrozil therapy in primary type II hyperlipoproteinemia: effects on lipids, lipoproteins and apolipoproteins

Gemfibrozil lowers triglycerides, low density lipoprotein (LDL) and very low density lipoprotein (VLDL) cholesterol. It also promotes a significant increase of high density lipoprotein (HDL) cholesterol. It has been established that normalization of apolipoproteins is an important protective factor against atherosclerosis. The present report examines the effectiveness of 12 months of gemfibrozil treatment on plasma lipids and apolipoproteins in types IIa (VLDL 18 +/- 2 mg cholesterol/dL) and IIb (VLDL 58 +/- 7 mg cholesterol/dL) hypercholesterolemic patients. Gemfibrozil lowered plasma triglycerides, VLDL cholesterol and apolipoprotein B (apoB), increased HDL cholesterol and apoAI levels in both groups, and induced a very substantial reduction in LDL cholesterol in type IIa patients only. Even though HDL particles were enriched in cholesterol, indicating improvement in the reverse cholesterol transport and lower risk of atherosclerosis in both groups, it is important to note that production of cholesterol-poor LDL particles and reduction in LDL cholesterol and the LDL/HDL cholesterol ratio were observed only in the normotriglyceride group (type IIa). Due to the initially elevated concentration of plasma triglycerides and VLDL in type IIb patients and the increased catabolism of VLDL to LDL during gemfibrozil therapy, this drug has a more efficient regulating effect on LDL particles in type IIa compared with type IIb hyperlipidemia.     

The effect of high dose atorvastatin therapy on lipids and lipoprotein subfractions in overweight patients with type 2 diabetes

Few data are available on the effects of high dose statin therapy on lipoprotein subfractions in type 2 diabetes. In a double blind randomised placebo-controlled trial we have studied the effects of 80 mg atorvastatin over 8 weeks on LDL, VLDL and HDL subfractions in 40 overweight type 2 diabetes patients. VLDL and LDL subfractions were prepared by density gradient ultracentrifugation. Triglycerides, cholesterol, total protein and phospholipids were measured and mass of subfractions calculated. HDL subfractions were prepared by precipitation. Atorvastatin 80 mg produced significant falls in LDL subfractions (LDL(1) 66.2 mg/dl:36.6 mg/dl, LDL(2) 118:56.6 mg/dl, LDL(3) 36.9:19.9 mg/dl all P < 0.01 relative to placebo) and VLDL subfractions (VLDL(1) 55:22.1 mg/dl, VLDL(2) 40.1:19.1 mg/dl, VLDL(3) 52.6:30 mg/dl all P < 0.01 relative to placebo). There was no change in the proportion of LDL present as LDL(3). There was a reduction in the proportion of VLDL as VLDL(1) and a reciprocal increase in the proportion as VLDL(3). Changes in VLDL subfractions were associated with changes in lipid composition, particularly a reduction in cholesterol ester and a reduction in the cholesterol ester/triglyceride ratio. Effects on HDL subfractions were largely neutral. High dose atorvastatin produces favourable effects on lipoprotein subfractions in type 2 diabetes which may enhance antiatherogenic potential.     

Lipoprotein subfraction composition in non-insulin-dependent diabetes treated by diet, sulphonylurea, and insulin

Lipoprotein abnormalities may predispose to an increased risk of coronary heart disease in type II (non-insulin-dependent) diabetes mellitus. To investigate the effects of different treatment modalities, the composition and concentrations of fasting plasma lipoproteins were determined in a cross-sectional study of patients with type II diabetes at diagnosis, treated by diet alone, treated by diet + glibenclamide (2.5 to 15 mg/d for 6 to 48 months), and treated by diet + insulin (25 to 65 U/d for 8 to 144 months). Compared with normal subjects matched for sex, age, body mass index, exercise, alcohol consumption and smoking, type II patients at diagnosis showed increased concentrations of nonesterified and esterified cholesterol, triglyceride, phospholipid, and protein in the very low density lipoprotein (VLDL) fraction. However, the only alteration in VLDL composition was a small decrease in the relative proportion of phospholipid. Apolipoprotein-B and low density lipoprotein (LDL) cholesterol concentrations were also raised in type II patients at diagnosis. Plasma concentrations of high density lipoprotein (HDL) nonesterified and esterified cholesterol, phospholipid, and apo-AI were lower in type II patients at diagnosis. This was largely accounted for by reduced concentrations of these components in the HDL2 subfraction, which retained a normal composition. Type II patients treated by diet alone and diet + glibenclamide exhibited similar abnormalities of plasma lipoprotein concentrations, which are associated with premature coronary disease, to the type II patients at diagnosis. However, in type II patients treated with insulin, plasma lipoprotein concentrations and composition were normal, except LDL cholesterol, which was lower than normal in insulin-treated patients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanisms of disease: lessons from ethnicity in the role of triglyceride metabolism in ischemic heart disease

Mean risk factor levels in various ethnic groups illustrate the potential importance of triglyceride metabolism in the risk for ischemic heart disease (IHD). Serum triglyceride concentrations are a surrogate for a range of potentially atherogenic disturbances in lipoprotein species, including increased concentrations of remnants of VLDL and chylomicron metabolism, increased small, dense LDL concentrations and reduced HDL concentrations. Differences between at-risk groups in lipoprotein profiles reflect alterations in the metabolism of triglycerides that might be greater than differences observed when only circulating triglyceride concentrations are measured. This atherogenic lipoprotein profile is typically found in association with increased visceral fat, insulin resistance and type 2 diabetes and might be a characteristic of Asian Indian ethnicity. By contrast, despite being relatively insulin resistant, Afro-Caribbean men in the UK have a low risk of IHD and lack the adverse lipoprotein profile. This could result from secretion of relatively large proportions of their VLDL as small, triglyceride-poor particles, levels of which are not augmented in response to loss of insulin action. These considerations re-endorse the potential importance of triglyceride metabolism in IHD and present opportunities for identifying useful areas in which drug targets for reducing IHD risk can be sought.     

Lipid-lowering therapy in diabetes mellitus.

Dyslipidemia emerges as an important modifiable risk factor for cardiovascular disease in diabetes mellitus, especially as part of the metabolic syndrome in type 2 diabetes. In type 1 diabetes mellitus, tight glucose regulation usually will correct dyslipidemia. Both total cholesterol and triglyceride levels predict cardiovascular disease in diabetes, and HDL-cholesterol may prove to be an even better predictor. In type 2 diabetes, increased triglyceride and reduced HDL-cholesterol levels are the key characteristics of dyslipidemia. Increased hepatic VLDL production and impaired catabolism of triglyceride-rich particles contribute to hypertriglyceridemia. Subsequent formation of small dense LDL particles leads to increased atherogenicity. Small dense LDL particles have a longer circulation time, are susceptible to glycoxidation, and are taken up by macrophages and the vessel wall. Post-hoc analysis of diabetic subgroups in primary and secondary prevention trials suggest that individuals with diabetes may enjoy substantial cardiovascular risk reduction from lipid-lowering therapy. Trials prospectively addressing the benefit of lipid lowering therapy in diabetes are under way. Target levels for lipid lowering therapy in diabetes at present stem from pathophysiological plausibility rather than from clinical proof. Intensive lipid-lowering with a statin in adequate dosage or a combination of a statin and a fibrate may be used to lower LDL-cholesterol levels to values < 2.6 mmol/l and triglyceride levels to < 1.7 mmol/l, a value at which few small dense LDL particles remain in circulation. Effective medication to raise HDL-cholesterol levels adequately are not yet available for clinical use. Treatment of diabetic dyslipidemia should be as simple as possible, given the polypharmacy that is often necessary for the patient with diabetes. Therefore, single treatment with a statin in adequate dosage is the first choice.     

Higher blood pressure in normoalbuminuric type 1 diabetic patients with a familial history of type 2 diabetes

BACKGROUND: To address whether type 1 diabetic patients with type 2 diabetic first degree relatives are different from others in terms of cardiovascular risk factors, insulin resistance and daily insulin dosage. METHODS: We studied 18 type 1 diabetic patients with type 2 diabetic first degree relatives and 36 type 1 diabetic patients without such relatives. Patients with diabetic complications (including microalbuminuria) were excluded. The groups were similar in terms of baseline characteristics. We measured systolic and diastolic blood pressures, body mass index, waist circumference, total cholesterol, triglycerides, LDL, VLDL, HDL, daily insulin dosage and insulin sensitivity. Insulin sensitivity was tested using insulin tolerance test. RESULTS: Type 1 diabetic patients having first degree relatives with type 2 diabetes had significantly higher systolic and diastolic blood pressures (although within the normal range) than others (p < 0.001). They were more insulin resistant according to insulin tolerance test and were using higher daily insulin dosages. In this group, waist circumference, triglyceride and VLDL levels also tended to be higher, but differences were not significant statistically. Total cholesterol, LDL and HDL levels were similar in both groups. CONCLUSION: Family history of type 2 diabetes increases blood pressure and decreases insulin sensitivity in type 1 diabetic patients. Thus such patients should be treated more aggressively in terms of both cardiovascular risk factors and glucose control.     

Lipoprotein lipase in diabetes

Lipoprotein lipase has a central role in the metabolism of both triglyceride-rich particles and high density lipoproteins, and it is one determinant of both serum triglyceride and HDL concentrations. In man the enzyme activity in both adipose tissue and skeletal muscle is insulin dependent, and therefore it varies in diabetes according to ambient insulin level and insulin sensitivity. In insulin deficiency (untreated Type 1 diabetes) the enzyme activity in both adipose tissue and muscle tissue is low but increases upon insulin therapy. In chronically insulin-treated patients with good control, the enzyme activity in postheparin plasma is increased. In untreated Type 2 diabetic patients, the average enzyme activity in adipose tissue and postheparin plasma is normal or subnormal. Therapy with oral agents or insulin, resulting in good glycemic control, is followed by an increase of LPL activity in both adipose tissue and postheparin plasma. In both Types 1 and 2 diabetes, changes of LPL activity are associated with relevant alterations in lipoprotein pattern. In insulin deficiency with low LPL, serum total and VLDL triglyceride levels are elevated, and HDL concentration is reduced. In chronically insulin-treated patients with high LPL activity, VLDL triglyceride concentrations are normal or subnormal, and HDL level is increased. In untreated Type 2 diabetic patients subnormal LPL activity may contribute to the elevation of serum triglycerides and to the reduction of HDL level.