Linkage of a candidate gene locus to familial combined hyperlipidemia: lecithin:cholesterol acyltransferase on 16q

Familial combined hyperlipidemia (FCHL) is a common lipid disorder characterized by elevated levels of plasma cholesterol and triglycerides that is present in 10% to 20% of patients with premature coronary artery disease. To study the pathophysiological basis and genetics of FCHL, we previously reported recruitment of 18 large families. We now report linkage studies of 14 candidate genes selected for their potential involvement in the aspects of lipid and lipoprotein metabolism that are altered in FCHL. We used highly polymorphic markers linked to the candidate genes, and these markers were analyzed using several complementary, nonparametric statistical allele-sharing linkage methodologies. This current sample has been extended over the one in which we identified an association with the apolipoprotein (apo) AI-CIII-AIV gene cluster. We observed evidence for linkage of this region and FCHL (P<0.001), providing additional support for its involvement in FCHL. We also identified a new locus showing significant evidence of linkage to the disorder: the lecithin:cholesterol acyltransferase (LCAT) locus (P<0.0006) on chromosome 16. In addition, analysis of the manganese superoxide dismutase locus on chromosome 6 revealed a suggestive linkage result in this sample (P<0.006). Quantitative traits related to FCHL also provided some evidence of linkage to these regions. No evidence of linkage to the lipoprotein lipase gene, the microsomal triglyceride transfer protein gene, or several other genes involved in lipid metabolism was observed. The data suggest that the lecithin:cholesterol acyltransferase and apolipoprotein AI-CIII-AIV loci may act as modifying genes contributing to the expression of FCHL.     

Genetics of familial combined hyperlipidemia

Complex disorders are caused by several environmental factors that interact with multiple genes. These diseases are common at the population level and constitute a major health problem in Western societies. Familial combined hyperlipidemia (FCHL) is characterized by elevated levels of serum total cholesterol, triglycerides, or both. This disorder is estimated to be common in Western populations with a prevalence of 1% to 2%. In addition, 14% of patients with premature coronary heart disease (CHD) have FCHL, making this disorder one of the most common genetic dyslipidemias underlying premature CHD. Both genetic and environmental factors are suggested to affect the complex FCHL phenotype, but no specific susceptibility genes to FCHL have been identified. It is hoped that further analysis of the first FCHL locus and other new loci obtained in genome-wide scans will guide us to genes predisposing to this complex disorder.     

Serum C3 but not plasma acylation-stimulating protein is elevated in Finnish patients with familial combined hyperlipidemia

A trapping defect of fatty acids due to impaired function of acylation-stimulating protein (ASP) has been suggested as one mechanism underlying the metabolic abnormalities in familial combined hyperlipidemia (FCHL). The study aimed at defining the role of ASP and complement C3 in 35 Finnish FCHL families. There was no difference in plasma ASP levels between the 66 hypertriglyceridemic FCHL patients and their 84 normotriglyceridemic relatives. No response in plasma ASP could be observed after a fatty meal in 10 FCHL patients or in 10 control subjects. In familial correlation analyses, C3 exhibited a significant sibling-sibling correlation. The FCHL patients had higher serum C3 levels than their unaffected relatives (P<0.001). Furthermore, serum C3 levels correlated significantly with several lipid parameters. The correlations between ASP and lipid variables were weaker than those of C3. These analyses suggest that common genes might contribute to the regulation of serum C3, triglycerides, HDL-C, free fatty acids, and insulin. The present data do not support the hypothesis that defects of the ASP pathway are reflected in plasma lipoproteins or in impaired plasma lipid clearance postprandially.     

The investigations of genetic determinants of the metabolic syndrome

Metabolic syndrome is the aggregation of cardiovascular risk factors that increases the risk of type 2 diabetes and cardiovascular diseases. Family and twin studies, heritability spectrum for its components and different prevalence among ethnicities, have provided genetic susceptibility to the metabolic syndrome. The investigations of genetic base for the disorder have recognized numerous chromosomes, various DNA polymorphisms in candidate genes and many gene variants, that are associated with metabolic syndrome as an entity or its traits, which mostly are related to lipid metabolism. In addition, recent finding of the role of rare variants, epigenetic mechanisms, non-coding RNAs and evaluating the function of genes in molecular networks have improved our knowledge. However, a common genetic basis explaining the co-occurrence of its components has not been identified and more researches are essential.     

Characterisation of the lipoprotein structure in the St. Thomas' Mixed Hyperlipidaemic (SMHL) rabbit

Familial combined hyperlipidaemia (FCHL) is a complex genetic disorder of unknown aetiology. Study of this human condition over many decades has been hampered by likely genetic heterogeneity. In order to find better phenotypic markers, we have characterised the structures of VLDL, IDL and LDL in the St. Thomas' Mixed Hyperlipidaemic (SMHL) rabbit--an animal model of FCHL in which the hyperlipidaemia is caused primarily by an increased production rate of apolipoprotein B (apoB)--containing lipoproteins-and compared them with those in the Watanabe Heritable Hyperlipidaemic (WHHL) rabbit, in which hyperlipidaemia is caused mainly by a defect in lipoprotein clearance, and those in the normolipidaemic New Zealand White (NZW) animal. All three rabbit strains were fed a cholesterol-enriched (0.08%, w/w) diet for at least 3 months prior to blood sampling. Both SMHL and WHHL rabbits showed combined hyperlipidaemia as evidenced by significantly increased levels of plasma cholesterol and triglycerides. Raised plasma lipids in the SMHL rabbit were attributable mainly to an overabundance of lipoprotein particles with the same lipid composition as those in NZW rabbits. VLDL and IDL in the SMHL rabbit showed a significantly increased sphingomyelin to phosphatidyl choline ratio. In the WHHL rabbit there was a high concentration of particles that were significantly enriched in cholesteryl esters and depleted in triglycerides. Phospholipids in all lipoprotein fractions from WHHL rabbits contained significantly more sphingomyelin and less phosphatidyl choline resulting in a significantly increased sphingomyelin to phosphatidyl choline ratio. We found that the VLDL of SMHL rabbits could be distinguished from that of NZW rabbits on the basis of the cholesterol:apoB and the sphingomyelin:phosphatidylcholine ratios, and from that of WHHL rabbits by the sphingomyelin:triglyceride ratio. Extrapolating these findings to the human condition, an assessment of particle core composition, together with the proportion of sphingomyelin in phospholipids especially in VLDL might help in the differentiation of the combined hyperlipidaemia of FCHL into disorders of lipoprotein overproduction versus decreased clearance.     

Common variants in the lipoprotein lipase gene,but not those in the insulin receptor substrate-1, the beta3-adrenergic receptor,and the intestinal fatty acid binding protein-2 genes,influence the lipid phenotypic expression in familial combined hyperlipidemia

Familial combined hyperlipidemia (FCHL) is a common, atherogenic lipid disorder characterized by a variable phenotypic expression of hyperlipidemia. Variations in genes regulating fatty acid metabolism must be considered in the search for factors affecting the lipid phenotypic expression of FCHL. Therefore, we have evaluated the association of the common variants in the lipoprotein lipase (LPL) (D9N, N291S, and S447X), insulin receptor substrate-1 (IRS-1) (G972R), fatty acid binding protein-2 (FABP-2) (A54T), and beta3-adrenergic receptor (beta3-AR) (W64R) genes with lipid and lipoprotein levels in 30 Italian FCHL families (195 individuals). The transmission disequilibriun test (TDT) was used to evaluate the association between these variants and the FCHL trait. No significant differences were observed in the frequencies of the common LPL variants between affected and nonaffected FCHL family members. A significantly lower frequency of the LPL447X allele was noted only when members of the FCHL families were compared with normolipemic controls (.06 v.142, respectively; P <.01) suggesting a reduced representation of this LPL variant in FCHL families. The frequencies of variants in the IRS-1, FABP-2, and beta3-AR genes were not significantly different between affected and nonaffected FCHL family members and normolipemic controls. The TDT did not demonstrate any significant association of these gene variants with the FCHL trait. FCHL individuals carrying the LPL N291S gene showed higher plasma lipids and apolipoprotein B (apoB) levels compared with affected noncarriers. Only a marginal effect of the LPL D9N and S447X variants on lipid levels in FCHL individuals was observed. Conversely, the variants in the IRS-1, FABP2, and beta3-AR genes did not show any major influence on lipid and lipoprotein levels in FCHL family members. In conclusion, these results confirmed that none of the investigated genes were major loci for FCHL. Nevertheless, variations in genes affecting the removal rate of triglycerides (TG) from plasma, such as the LPL gene, significantly influence the lipid phenotypic expression of FCHL. Conversely, genetic variants in the IRS-1, FABP-2, and the beta3-AR gene appear not to have a major role as modifier genes in FCHL.     

Evidence of insulin resistant lipid metabolism in adipose tissue in familial combined hyperlipidemia,but not type 2 diabetes mellitus

In patients with familial combined hyperlipidemia (FCHL) and type 2 diabetes (DM2) organ-specific differences in insulin resistance may exist. In FCHL and DM2 in vivo insulin mediated muscle glucose uptake and inhibition of lipolysis were studied by euglycemic hyperinsulinemic clamp. Insulin mediated glucose uptake was impaired to the same extent in both FCHL and DM2. Only FCHL subjects showed no reduction in plasma glycerol concentrations during insulin infusion and incomplete suppression of plasma free fatty acid (FFA) concentrations combined. This finding indicated that insulin-induced suppression of lipolysis, or glycerol/FFA utilization, or both, were impaired in FCHL, in contrast to DM2 or control subjects. To analyze these possibilities in more detail, control, FCHL, and DM2 adipocytes were studied in vitro. In contrast to adipocytes from DM2 or control subjects, no reduction in medium FFA concentration was detected with FCHL adipocytes after incubation with insulin. This finding indicated impaired intracellular FFA utilization, most likely impaired FFA re-esterification. Genetic linkage analysis in 18 Dutch families with FCHL revealed no evidence for involvement of LIPE, the hormone sensitive lipase gene, indicating that genetic variation in adipocyte lipolysis by LIPE is not the key defect in FCHL. In conclusion, FCHL as well as DM2 subjects exhibited in vivo insulin resistance to glucose disposal, which occurs mainly in muscle. FCHL subjects showed insulin resistant adipose tissue lipid metabolism, in contrast to DM2 and controls. The different pattern of organ-specific insulin resistance in FCHL versus DM2 advances our understanding of differences and similarities in phenotypes between these disorders.     

C3, hormone-sensitive lipase, and peroxisome proliferator-activated receptor gamma expression in adipose tissue of familial combined hyperlipidemia patients

This study aimed to assess the role of complement C3, hormone-sensitive lipase (HSL), and peroxisome proliferator-activated receptor gamma (PPARgamma) gene expression in familial combined hyperlipidemia (FCHL). mRNA expression of these 3 determinants of adipose tissue fatty acid (FA) metabolism was quantified in subcutaneous adipose tissue of 41 Finnish FCHL patients and 14 normolipidemic control subjects. No difference in steady-state mRNA expression level of C3, HSL, or PPARgamma mRNA was detected between the FCHL patients and the control subjects. Adipose tissue C3 mRNA expression level correlated with the area under the curve (AUC) for glucose and for insulin in FCHL patients and control subjects. HSL mRNA level was positively correlated with waist-to-hip ratio in patients, whereas the correlation was negative in control subjects. A significant correlation was observed for PPARgamma with free FA (FFA)-AUC in the FCHL group, and an inverse correlation with serum triglycerides (TG) in the control subjects. Although no difference in adipose tissue gene expression of C3, HSL, or PPARgamma was observed between the FCHL patients and the control subjects, several significant correlations were observed between the mRNA levels and FCHL-related metabolic parameters. Thus, the genes of C3, HSL, and PPARgamma may exert a modifying effect on lipid and glucose metabolism in FCHL. However, defects in adipose tissue expression of these genes are not likely to play a primarily role in the pathogenesis of FCHL in Finnish FCHL families.     

Effects of atorvastatin on the clearance of triglyceride-rich lipoproteins in familial combined hyperlipidemia

Familial combined hyperlipidemia (FCHL) patients have an impaired catabolism of postprandial triglyceride (TG)-rich lipoproteins (TRLs). We investigated whether atorvastatin corrects the delayed clearance of large TRLs in FCHL by evaluating the acute clearance of Intralipid (10%) and TRLs after oral fat-loading tests. Sixteen matched controls were included. Atorvastatin reduced fasting plasma TG (from 3.6 +/- 0.4 to 2.5 +/- 0.3 mM; mean +/- SEM) without major effects on fasting apolipoprotein B48 (apoB48) and apoB100 in large TRLs. Atorvastatin significantly reduced fasting intermediate density lipoprotein (Svedberg flotation, 12-20)-apoB100 concentrations. After Intralipid, TG in plasma and TRL showed similar kinetics in FCHL before and after atorvastatin treatment, although compared with controls, the clearance of large TRLs was only significantly slower in untreated FCHL, suggesting an improvement by atorvastatin. Investigated with oral fat-loading tests, the clearance of very low density lipoprotein (Sf20-60)-apoB100 improved by 24%, without major changes in the other fractions. The most striking effects of atorvastatin on postprandial lipemia in FCHL were on hepatic TRL, without major improvements on intestinal TRLs. Fasting plasma TG should be reduced more aggressively in FCHL to overcome the lipolytic disturbance causing delayed clearance of postprandial TRLs.     

Mutations in Japanese subjects with primary hyperlipidemia--results from the Research Committee of the Ministry of Health and Welfare of Japan since 1996--

Primary hyperlipidemia is caused by various molecular defects in lipid metabolism. The Research Committee on Primary Hyperlipidemia organized by the Ministry of Health and Welfare of Japan (present: the Ministry of Health, Labour and Welfare) has investigated reported mutations in Japanese patients with primary hyperlipidemia and related disorders (including hypolipidemia), and has created a database based on the questionnaire sent to the members of council board of the Japan Atherosclerosis Society. Mutations in the following genes were investigated: low density lipoprotein receptor, lecithin: cholesteryl acyltransferase, lipoprotein lipase (LPL), hepatic lipase, apolipoproteins A-I, A-II, A-IV, B, C-II, C-III and E, microsomal triglyceride transfer protein, and cholesterol ester transfer protein (CETP). Until 1998, 922 patients with primary hyperlipidemia and related disorders has been registered with the Research Committee, and 190 mutations in 15 genes had been reported, showing a marked variation in Japanese patients with primary hyperlipidemia and related disorders. So-called "common mutations" have been described in Japanese patients with familial hypercholesterolemia, LPL deficiency and CETP deficiency. The genetic defect of familial combined hyperlipidemia (FCHL) is still unknown although FCHL is speculated to be the most prevalent genetic hyperlipidemia, and further investigations should be performed to elucidate the molecular mechanisms of FCHL     

Delayed and exaggerated postprandial complement component 3 response in familial combined hyperlipidemia

Very low density lipoprotein overproduction is the major metabolic characteristic in familial combined hyperlipidemia (FCHL). Peripheral handling of free fatty acids (FFAs) in vitro may be impaired in FCHL by decreased action of acylation-stimulating protein (ASP), which is identical to the immunologically inactive complement component 3a (C3adesArg). Because decreased FFA uptake by impaired complement component 3 (C3) response (as the precursor for ASP) may result in enhanced FFA flux to the liver in FCHL, we have evaluated postprandial C3 changes in vivo in FCHL patients. Accordingly, 10 untreated FCHL patients and 10 matched control subjects underwent an oral fat loading test. Fasting plasma C3 and ASP levels were higher in FCHL patients (1.33+/-0.09 g/L and 70.53+/-4.37 mmol/L, respectively) than in control subjects (0.91+/-0.03 g/L and 43.21+/-8.96 mmol/L, respectively; P=0.01 and P<0.05). In control subjects, C3 concentrations increased significantly after 4 hours (to 1.03+/-0.04 g/L). In FCHL, plasma C3 was unchanged after 4 hours. The earliest postprandial C3 rise in FCHL patients occurred after 8 hours (1.64+/-0.12 g/L). The maximal apolipoprotein B-48 concentration was reached after 6 hours in FCHL patients and control subjects. Postprandial FFA and hydroxybutyric acid (as a marker of hepatic FFA oxidation) were significantly higher in FCHL patients than in control subjects, and the early postprandial C3 rise was negatively correlated with the postprandial FFA and hydroxybutyric acid concentrations. The present data suggest an impaired postprandial plasma C3 response in FCHL patients, most likely as a result of a delayed response by C3, as the precursor for the biologically active ASP, acting on FFA metabolism. Therefore, an impaired postprandial C3 response may be associated with impaired peripheral postprandial FFA uptake and, consequently, lead to increased hepatic FFA flux and very low density lipoprotein overproduction.     

Genetically determined apo B levels and peak LDL density predict angiographic response to intensive lipid-lowering therapy

OBJECTIVE: Lipid-lowering therapy (LL-Rx) reduces coronary artery disease (CAD) but the response varies amongst individuals. We investigated the contribution of three genetic forms of dyslipidaemia characterized by elevated plasma apo B, familial hypercholesterolaemia (FH), familial combined hyperlipidaemia (FCHL), and elevated Lp(a), to the angiographic response with LL-Rx. METHODS AND RESULTS: Fifty-one men, with premature CAD and elevated plasma apo B, were selected in whom a genetic diagnosis was based on lipid phenotypes in relatives. Subjects received conventional (diet +/- colestipol) or intensive LL-Rx (niacin or lovastatin plus colestipol). Clinical parameters and CAD severity were measured before and after 2 years of treatment. Twenty-seven patients had FCHL, 12 FH and 12 elevated Lp(a). Regression of coronary stenosis was dependent on the effect of therapy (P < 0.001), genetic form of dyslipidaemia (P = 0.004) and the interaction between the two variables (P = 0.02). Significant regression of coronary stenosis occurred only in FCHL and Lp(a) (P = 0.03, vs. control groups); CAD progression was only slowed in FH. CONCLUSIONS: Three genetic forms of dyslipidaemia were associated with different angiographic outcomes during intensive LL-Rx. Different forms of dyslipidaemia therefore may require different lipid-lowering strategy. Patients with FH and buoyant LDL require more aggressive reduction of LDL cholesterol whilst those with either FCHL or elevated Lp(a) with dense LDL need LDL cholesterol reduction as well as therapies aimed at reduction of the small, dense LDL particles.     

Origins of metabolic diversity: Evolutionary divergence by sequence repetition

Recurring patterns of primary structure have been observed in enzymes that mediate sequential metabolic reactions in bacteria. The enzymes, muconolactone Delta-isomerase [(+)-4-hydroxy-4-carboxymethylisocrotonolactone Delta(2)-Delta(3)-isomerase, EC 5.3.3.4] and beta-ketoadipate enol-lactone hydrolase [4-carboxymethylbut-3-enolide(1,4)enol-lactone-hydrolase, EC 3.1.1.24], have been coselected in bacterial populations because the isomerase can confer no nutritional advantage in the absence of the hydrolase. Similar amino acid sequences recur within the structure of the isomerase, and the amino-terminal amino acid sequence of the isomerase from Pseudomonas putida appears to be evolutionarily homologous with the corresponding sequence of a beta-ketoadipate enol-lactone hydrolase from Acinetobacter calcoaceticus. One interpretation of the sequence repetitions is that they reflect tandem duplication mutations that took place early in the evolution of the proteins. According to this view, the mutations caused elongation of structural genes and the creation of duplicated genes as the metabolic pathways evolved. A review of the sequence data calls attention to a different hypothesis: repeated amino acid sequences were introduced in the course of the proteins' evolution by substitution of copies of DNA sequences into structural genes. Our observations are interpreted on the basis of a model proposing genetic exchange between misaligned DNA sequences. The model predicts that misalignments in one chromosomal region can influence the nature of mutations in another region. Thus, as often has been observed, the mutability of a base pair will be determined by its location in a DNA sequence. Furthermore, the intrachromosomal recombination of DNA sequences may account for complex genetic modifications that occur as new pathways evolve. The model provides an interpretation of an apparent paradox, the rapid creation of new metabolic traits by bacterial genomes that are remarkably resistant to genetic drift.     

Pioglitazone added to conventional lipid-lowering treatment in familial combined hyperlipidaemia improves parameters of metabolic control: relation to liver, muscle and regional body fat content

Familial combined hyperlipidaemia (FCHL) is a complex genetic disorder conferring high risk of premature atherosclerosis, characterized by high cholesterol and/or triglyceride, low high density lipoprotein (HDL) cholesterol and insulin resistance. We examined whether pioglitazone, added to conventional lipid-lowering therapy, would favourably affect metabolic parameters and alter body fat content. We undertook a randomized, double blind, placebo-controlled study in 22 male patients with FCHL treated with pioglitazone or matching placebo 30 mg daily for 4 weeks, increasing to 45 mg for 12 weeks. Magnetic resonance imaging and proton magnetic resonance spectroscopy were performed to measure adipose tissue (AT) body content as well as intrahepatocellular lipids (IHCL) and intramyocellular lipids (IMCL) at baseline and after treatment. Significantly improved in the pioglitazone group were: triglyceride/HDL (atherogenic index of plasma) -32.3% (p=0.002), plasma glucose -4.4% (p=0.03), alanine-aminotransferase (ALT) -7.7% (p=0.005) and adiponectin 130.1% (p=0.001). Pioglitazone treatment resulted in a significant increase in total (5.3%, p=0.02) and subcutaneous (7.1%, p=0.003) adipose tissue as well as in soleus-IMCL levels (47.4%, p=0.02) without alteration in intra-abdominal AT or IHCL. Changes in ALT and AST and IHCL were strongly correlated (r=0.72, p<0.01; r=.0.86, p<0.01, respectively). In patients with FCHL on conventional lipid-lowering therapy, the addition of pioglitazone acts favourably on several metabolic parameters.     

Alanine and aspartate aminotransferase and glutamine-cycling pathway: their roles in pathogenesis of metabolic syndrome

Although new research technologies are constantly used to look either for genes or biomarkers in the prediction of metabolic syndrome (MS), the pathogenesis and pathophysiology of this complex disease remains a major challenge. Interestingly, Cheng et al recently investigated possible pathways underlying MS by high-throughput metabolite profiling in two large and well characterized community-based cohorts. The authors explored by liquid chromatography and mass spectrometry the plasma concentrations of 45 distinct metabolites and examined their relation to cardiometabolic risk, and observed that metabolic risk factors such as obesity, insulin resistance (IR), high blood pressure, and dyslipidemia were associated with several metabolites, including branched-chain amino acids, other hydrophobic amino acids, tryptophan breakdown products, and nucleotide metabolites. In addition, the authors found a significant association of IR traits with glutamine, glutamate and the glutamine-to-glutamate ratio. These data provide new insight into the pathogenesis of MS-associated phenotypes and introduce a crucial role of glutamine-cycling pathway as prominently involved in the development of metabolic risk. We consider that the hypothesis about the role of abnormal glutamate metabolism in the pathogenesis of the MS is certainly challenging and suggests the critical role of the liver in the global metabolic modulation as glutamate metabolism is linked with aminotransferase reactions. We discuss here the critical role of the "liver metabolism" in the pathogenesis of the MS and IR, and postulate that before fatty liver develops, abnormal levels of liver enzymes, such as alanine and aspartate aminotransferases might reflect high levels of hepatic transamination of amino acids in the liver.     

Fatty liver--based identification of two distinct hypertriglyceridemic subgroups in familial combined hyperlipidemia

The present study was conducted to investigate whether the fatty liver phenotype could be helpful in the identification of subgroups with distinct metabolic properties and lipid profiles within familial combined hyperlipidemia (FCHL). One hundred eighty-five FCHL family members participated in the current study; 38 subjects were found to be hypertriglyceridemic, of whom 66% showed evidence of fatty liver as measured with ultrasound. A detailed comparison between the hypertriglyceridemic FCHL subjects with (n = 25) and without (n = 13) fatty liver revealed that, despite very similar plasma triglyceride levels (3.5 vs 3.2 mmol/L in subjects with and without fatty liver, respectively), the fatty liver subgroup presented with significantly higher body mass index, visceral adipose tissue (ultrasound), insulin, and alanine aminotransferase levels. Moreover, very low-density lipoprotein (VLDL) subclass analysis showed that the VLDL2 fraction of the fatty liver subgroup contained significantly less cholesterol and triglycerides (P = .02 for both parameters), which was likely explained by a decreased VLDL2 particle number because VLDL2 apolipoprotein B levels tended to be lower (P = .08). These data indicate that hypertriglyceridemic FCHL subjects may belong to metabolically distinct subgroups and suggest that a refinement of the hypertriglyceridemic FCHL phenotype by adding information on fatty liver will eventually facilitate the elucidation of its complex genetic background.     

Effect of statins on LDL particle size in patients with familial combined hyperlipidemia: a comparison between atorvastatin and pravastatin

BACKGROUND AND AIM: Elevation of plasma cholesterol and/or triglycerides, and the prevalence of small dense low density lipoproteins (LDL) particles remarkably increase the risk in patients with familial combined hyperlipidemia (FCHL). There are, at present, inconsistent data on the effects of different treatments on size and density of LDL particles in FCHL patients. METHODS AND RESULTS: A multicenter, randomized, double-blind, double-dummy, parallel group study was designed to evaluate the effect of 3 months' treatment with atorvastatin (10mg/day) or pravastatin (20mg/day) on the lipid/lipoprotein profile and LDL size in a total of 86 FCHL patients. Both statins significantly lowered plasma total and LDL cholesterol, with a significantly higher hypocholesterolemic effect observed with atorvastatin (-26.8+/-11.1% and -35.9+/-11.1%, respectively) compared to pravastatin (-17.6+/-11.1% and -24.5+/-10.2%). The percent decrease in plasma triglycerides was highly variable, but more pronounced with atorvastatin (-19.8+/-29.2%) than with pravastatin (-5.3+/-48.6%). Opposite changes in LDL size were seen with the 2 treatments, with increased mean LDL particle diameter with atorvastatin, and decreased diameter with pravastatin, and significant between treatment difference in terms of percent modification vs baseline (+0.5+/-1.6% with atorvastatin vs -0.3+/-1.8% with pravastatin). CONCLUSIONS: The present results support the evidence indicative of a greater hypocholesterolemic effect of atorvastatin compared to pravastatin, and in addition show a raising effect of atorvastatin on the size of LDL particles in FCHL patients.     

Pharmacokinetic considerations in abuse liability evaluation

The behavioral effects of a drug are related to three factors: its intrinsic pharmacological activity, its physicochemical properties, and its pharmacokinetic parameters. In many cases differences in absorption, distribution, metabolism, and elimination may explain the different abuse liability profiles of drugs from within the same pharmacological class. Rapid absorption rate and high lipid solubility are the most important factors contributing to early drug concentrations in the brain. Differences in drug metabolism may be related to dose-dependent kinetics, first-pass metabolism, and variations in genetic traits (e.g. poor or extensive metabolizers). Metabolic pathways may produce active metabolites with similar or greater pharmacological activity than the parent substance. Drugs with a rapid elimination rate have been associated with greater self-administration and with early emergence of withdrawal symptoms. More pharmacokinetic studies are needed in human drug abuse liability evaluations. Knowledge of the plasma concentrations of drugs and their pharmacokinetic parameters can be essential to interpret differences among similar drugs in human abuse liability assessments.