Increased large VLDL particles confer elevated cholesteryl ester transfer in diabetes.

BACKGROUND: Plasma cholesteryl ester transfer (CET), reflecting transfer of cholesteryl esters from high density lipoproteins (HDL) towards apolipoprotein B-containing lipoproteins, may promote atherosclerosis development, and is elevated in Type 2 diabetes mellitus (T2DM). We determined the extent to which the relationship of plasma CET with very low density lipoprotein (VLDL) and low density lipoprotein (LDL) subfractions is modified in T2DM. MATERIALS AND METHODS: Plasma CET, cholesteryl ester transfer protein (CETP) mass, as well as VLDL and LDL subfractions (nuclear magnetic resonance spectroscopy) were determined in 62 patients with T2DM and 53 nondiabetic subjects. RESULTS: Plasma CET and CETP mass were increased in T2DM, coinciding higher triglycerides and large VLDL particles (all P < 0·02). Plasma CET was positively related to the VLDL and the LDL particle concentration in age-, sex- and diabetes status-adjusted analysis (both P < 0·001). Multivariable linear regression analysis demonstrated an independent positive interaction between the presence of T2DM and the VLDL concentration on plasma CET (ß = 0·238, P = 0·033). The relationship of plasma CET with the VLDL concentration was also positively modified by plasma glucose (ß = 0·211, P = 0·004) and glycated haemoglobin (ß = 0·190, P = 0·012). Of the individual VLDL subfractions, a positive interaction of diabetes status with large VLDL on plasma CET was observed (ß = 0·280, P = 0·003). Neither the relationship of the LDL particle concentration nor of CETP mass with plasma CET was modified by the presence of T2DM (P > 0·15). CONCLUSION: Abnormalities in the concentration and composition of large VLDL particles are likely to contribute to elevated plasma CET in T2DM.

The role of lipid metabolism in the pathogenesis of alcoholic and nonalcoholic hepatic steatosis.

Hepatic steatosis is now understood to play an important role in the development of advanced liver disease. Alcoholic and nonalcoholic fatty liver each begin with the accumulation of lipids in the liver. Lipid accumulation in the liver can occur through maladaptations of fatty acid uptake (either through dietary sources or from fat tissue), fatty acid synthesis, fatty acid oxidation, or export of lipids from the liver. Alterations in mechanisms of fatty acid uptake through both dietary uptake and lipolysis in adipose tissue can contribute to the pathogenesis of both disorders, as can effects on fatty acid transporters. Effects on lipid synthesis in alcoholic and nonalcoholic fatty liver involve the endoplasmic reticulum (ER) stress response, homocysteine metabolism pathway, and different transcription factors regulating genes in the lipid synthesis pathway. Fatty acid oxidation, through effects on AMP-activated protein kinase (AMPK), adiponectin, peroxisome proliferator-activated receptors (PPARs), and mitochondrial function is predominantly altered in alcoholic liver disease, although studies suggest that activation of this pathway may improve nonalcoholic fatty liver disease. Finally, changes in fatty acid export, through effects on apolipoprotein B and microsomal transport protein are seen in both diseases. Thus, the similarities and differences in the mechanism of fat accumulation in the liver in nonalcoholic and alcoholic liver disease are explored in detail.

The evolution of plasma cholesterol: direct utility or a "spandrel" of hepatic lipid metabolism?

Fats provide a concentrated source of energy for multicellular organisms. The efficient transport of fats through aqueous biological environments raises issues concerning effective delivery to target tissues. Furthermore, the utilization of fatty acids presents a high risk of cytotoxicity. Improving the efficiency of fat transport while simultaneously minimizing the cytotoxic risk confers distinct selective advantages. In humans, most of the plasma cholesterol is associated with low-density lipoprotein (LDL), a metabolic by-product of very-low-density lipoprotein (VLDL), which originates in the liver. However, the functions of VLDL are not clear. This paper reviews the evidence that LDL arose as a by-product during the natural selection of VLDL. The latter, in turn, evolved as a means of improving the efficiency of diet-derived fatty acid storage and utilization, as well as neutralizing the potential cytotoxicity of fatty acids while conserving their advantages as a concentrated energy source. The evolutionary biology of lipid transport processes has provided a fascinating insight into how and why these VLDL functions emerged during animal evolution. As causes of historical origin must be separated from current utilities, our spandrel-LDL theory proposes that LDL is a spandrel of VLDL selection, which appeared non-adaptively and may later have become crucial for vertebrate fitness.

Effects of VLDL and remnant particles on platelets.

There is a considerable body of evidence supporting an association between hypertriglyceridaemia, a hypercoagulable state and atherothrombosis. A disorder of triglyceride metabolism is a key feature of the metabolic syndrome that increases risk of both ischaemic heart disease and type 2 diabetes approximately 3-fold. An increasing prevalence of obesity and metabolic syndrome is likely to contribute markedly to the prevalent ischaemic heart in the foreseeable future, and therefore it is crucial to understand mechanisms linking hypertriglyceridaemia and a hypercoagulable state. Activation of platelets and the coagulation cascade are intertwined. VLDL and remnant lipoprotein concentrations are often increased with the metabolic syndrome. These lipoproteins have the capacity to activate platelets and the coagulation pathway, and to support the assembly of the prothrombinase complex. VLDL also upregulates expression of the plasminogen activator inhibitor-1 gene and plasminogen activator inhibitor-1 antigen and activity, a process accompanied by platelet aggregation and clot formation. The surface membrane of activated platelets also supports the assembly and activity of the prothrombinase complex, resulting in further thrombin generation and amplification of the coagulation cascade. Fibrinolysis is also less efficient when thrombin is generated. Thrombin induces thrombin activatable fibrinolysis inhibitor. Thrombin activatable fibrinolysis inhibitor is a carboxypeptidase that cleaves the carboxylic lysine residues on fibrin, thereby abolishing the critical binding site for tPA-plasminogen decreasing plasmin formation. Thus the evidence is supportive of dysregulated coagulation, and impaired fibrinolysis with a predisposition to atherothrombosis, in conditions such as the metabolic syndrome, in which there are increased concentrations of VLDL and remnant lipoproteins. The purpose of this review is to describe the current evidence supporting a procoagulant state induced by VLDL and remnant lipoproteins. The role of these lipoprotein classes in (1) platelet activation; (2) the intrinsic coagulation cascade, and (3) clot formation and fibrinolysis is discussed.

Does statin monotherapy address the multiple lipid abnormalities in type 2 diabetes?

Lipid abnormalities, which are common in type 2 diabetes, predispose to a greatly increased risk of coronary heart disease. This characteristic dyslipidaemia includes decreased concentrations of high-density lipoprotein cholesterol (HDL-C), elevated triglycerides, and a small, dense, atherogenic form of low-density lipoprotein cholesterol (LDL-C). Insulin resistance and obesity, which is commonly present in type 2 diabetes, act in concert to disrupt normal lipoprotein metabolism; reverse cholesterol transport in particular. The proatherogenic changes, which result from this process include enrichment of very-low-density lipoprotein with cholesteryl esters and enrichment of LDL with triglycerides. Results from both the Pravastatin Pooling Project and the Heart Protection Study demonstrate that, although people with diabetes obtain the same relative risk reduction with statin therapy, the absolute benefit derived is much lower than for comparable individuals without diabetes. In order to achieve improved outcomes in diabetes patients, it will be important to address other abnormalities in their lipid profiles, including elevated triglycerides and low HDL-C.

The physiology of lipoproteins.

The seminal studies of Brown and Goldstein (Science 1986;232:34-47) coupled with the findings of the Framingham study revolutionized our understanding of the metabolic basis for vascular disease. These studies led to the widespread use of the coronary risk lipid profile, which uses the total cholesterol/high-density lipoprotein (HDL) ratio (or low-density lipoprotein [LDL]/HDL ratio) in predicting risk for vascular disease and as a tool for therapeutic management of patients at risk for vascular disease. However, although these methods are predictive of coronary artery disease (CAD) in general, it is also well known that the extent of occlusive disease and CAD varies greatly between individuals with similar cholesterol and HDL lipid profiles. For this reason, the National Cholesterol Education Program Expert Panel revised these guidelines and now recommends monitoring LDL and HDL cholesterol in the context of coronary heart disease risk factors and "risk equivalents." In addition, more recent findings indicate that specific alterations in individual lipoprotein subclasses may account for the variations in CAD in subjects with similar lipid profiles. For example, a preponderance of small, dense LDL particles correlates with a marked increase in risk for myocardial infarction independent of LDL levels. In particular, the association of small, dense LDL with elevated triglycerides (large, less dense VLDL) and reduced HDL has been defined as the atherogenic lipoprotein profile, and the key metabolic defect driving this profile may be elevated levels of triglycerides, specifically large, less dense VLDL. In an attempt to explain the physiologic basis for lipoprotein variations, this review describes the basic metabolic scheme underlying the traditional view of lipoprotein metabolism and physiology. It then examines the identity and role of the various lipoprotein subfractions in an attempt to distill a working model of how lipoprotein abnormalities might account for vascular disease in general and the metabolic syndrome in particular.

Postprandial lipid handling.

The etiological importance of postprandial lipid metabolism in the development of coronary artery disease is now well established. Since then, the work of Patsch and others has helped to establish the etiological importance of postprandial lipid metabolism in the development of coronary artery disease. Dietary and pharmacological interventions have been shown to produce dramatic improvement in postprandial lipid handling in high risk groups and have potential to prevent coronary artery disease through these effects. Research effort continues to focus on the complex mechanisms which underlie defects in postprandial lipid handling, with a view to understanding how lifestyle variables such as diet can be modified to prevent coronary artery disease.

Identification of lipid components of human serum lipoproteins involved in the inhibition of Sindbis virus infectivity, hemagglutination, and hemolysis.

Human serum high density lipoproteins (HDL), low density lipoproteins (LDL) and very low density lipoproteins (VLDL) were isolated and tested for their ability to inhibit Sindbis virus infectivity, hemagglutination and hemolysis. VLDL and LDL produced a strong reduction on both viral infectivity on Vero cell monolayers and attachment and fusion with erythrocytes, whereas HDL appeared to be only a weak inhibitor. Lipid and protein components were extracted from each class of lipoproteins to identify the molecules responsible for the inhibiting activity. Only the lipid moiety was found to inhibit Sindbis virus biological activities. Among the individual lipid components of lipoproteins, neutral lipids (cholesterol, oleic acid and palmitic acid) and negatively charged phospholipids (phosphatidylserine and phosphatidylinositol) and glycolipids (GM 3 ganglioside and cerebroside sulphate) were able to neutralize the virus suggesting that either hydrophobic or electrostatic interactions are involved in the inhibition.