Betsie Boucher

Mutations in the ABC1 gene in familial HDL deficiency with defective cholesterol efflux

BACKGROUND A low concentration of HDL cholesterol is the most common lipoprotein abnormality in patients with premature atherosclerosis. We have shown that Tangier disease, a rare and severe form of HDL deficiency characterised by a biochemical defect in cellular cholesterol efflux, is caused by mutations in the ATP-binding-cassette (ABC1) gene. This gene codes for the cholesterol-efflux regulatory protein (CERP). We investigated the presence of mutations in this gene in patients with familial HDL deficiency. METHODS Three French-Canadian families and one Dutch family with familial HDL deficiency were studied. Fibroblasts from the proband of each family were defective in cellular cholesterol efflux. Genomic DNA of each proband was used for mutation detection with primers flanking each exon of the ABC1 gene, and for sequencing of the entire coding region of the gene. PCR and restriction-fragment length polymorphism assays specific to each mutation were used to investigate segregation of the mutation in each family, and to test for absence of the mutation in DNA from normal controls. FINDINGS A different mutation was detected in ABC1 in each family studied. Each mutation either created a stop codon predicted to result in truncation of CERP, or altered a conserved aminoacid residue. Each mutation segregated with low concentrations of HDL-cholesterol in the family, and was not observed in more than 500 control chromosomes tested. INTERPRETATION These data show that mutations in ABC1 are the major cause of familial HDL deficiency associated with defective cholesterol efflux, and that CERP has an essential role in the formation of HDL. Our findings highlight the potential of modulation of ABC1 as a new route for increasing HDL concentrations.

Age and residual cholesterol efflux affect HDL cholesterol levels and coronary artery disease in ABCA1 heterozygotes

We and others have recently identified mutations in the ABCA1 gene as the underlying cause of Tangier disease (TD) and of a dominantly inherited form of familial hypoalphalipoproteinemia (FHA) associated with reduced cholesterol efflux. We have now identified 13 ABCA1 mutations in 11 families (five TD, six FHA) and have examined the phenotypes of 77 individuals heterozygous for mutations in the ABCA1 gene. ABCA1 heterozygotes have decreased HDL cholesterol (HDL-C) and increased triglycerides. Age is an important modifier of the phenotype in heterozygotes, with a higher proportion of heterozygotes aged 30-70 years having HDL-C greater than the fifth percentile for age and sex compared with carriers less than 30 years of age. Levels of cholesterol efflux are highly correlated with HDL-C levels, accounting for 82% of its variation. Each 8% change in ABCA1-mediated efflux is predicted to be associated with a 0.1 mmol/l change in HDL-C. ABCA1 heterozygotes display a greater than threefold increase in the frequency of coronary artery disease (CAD), with earlier onset than unaffected family members. CAD is more frequent in those heterozygotes with lower cholesterol efflux values. These data provide direct evidence that impairment of cholesterol efflux and consequently reverse cholesterol transport is associated with reduced plasma HDL-C levels and increased risk of CAD.

Cellular Cholesterol Transport and Efflux in Fibroblasts Are Abnormal in Subjects With Familial HDL Deficiency

Familial high density lipoprotein (HDL) deficiency (FHD) is a genetic lipoprotein disorder characterized by a severe decrease in the plasma HDL cholesterol (-C) level (less than the fifth percentile). Unlike Tangier disease, FHD is transmitted as an autosomal dominant trait. FHD subjects have none of the clinical manifestations of Tangier disease (lymphoid tissue infiltration with cholesteryl esters and/or neurological manifestations). Plasmas from FHD subjects contain pre-beta-migrating HDLs but are deficient in alpha-migrating HDLs. We hypothesized that a reduced HDL-C level in FHD is due to abnormal transport of cellular cholesterol to the plasma membrane, resulting in reduced cholesterol efflux onto nascent HDL particles, leading to lipid-depleted HDL particles that are rapidly catabolized. Cellular cholesterol metabolism was investigated in skin fibroblasts from FHD and control subjects. HDL3- and apolipoprotein (apo) A-I-mediated cellular cholesterol and phosphatidylcholine efflux was examined by labeling cells with [3H]cholesterol and [3H]choline, respectively, during growth and cholesterol loading during growth arrest. FHD cells displayed an approximately 25% reduction in HDL3-mediated cellular cholesterol efflux and an approximately 50% to 80% reduction in apoA-I-mediated cholesterol and phosphatidylcholine efflux compared with normal cells. Cellular cholesterol ester levels were decreased when cholesterol-labeled cells were incubated with HDL3 in normal cells, but cholesterol ester mobilization was significantly reduced in FHD cells. HDL3 binding to fibroblasts and the possible role of the HDL binding protein/vigilin in FHD were also investigated. No differences were observed in 125I-HDL3 binding to LDL-loaded cells between FHD and control cells. HDL binding protein/vigilin mRNA levels and its protein expression were constitutively expressed in FHD cells and could be modulated ( approximately 2-fold increase) by elevated cellular cholesterol in normal cells. In conclusion, FHD is characterized by reduced HDL3- and apoA-I-mediated cellular cholesterol efflux. It is not associated with abnormal cellular HDL3 binding or a defect in a putative HDL binding protein.

Decreased cellular cholesterol efflux is a common cause of familial hypoalphalipoproteinemia: role of the ABCA1 gene mutations

BACKGROUND High density lipoproteins (HDL) are complex lipoprotein particles involved in reverse cholesterol (C) transport and are negatively associated with the risk for coronary artery disease (CAD). We have described a disorder of familial HDL deficiency (FHD) due to abnormal cellular cholesterol efflux. In the present study, we investigated cellular cholesterol efflux on skin fibroblast from 15 probands with moderate to severe hypoalphalipoproteinemia, including one subject with Tangier disease (TD). We performed family studies on eight of these probands (269 individuals) with familial hypoalphalipoproteinemia (defined as a HDL-C <5th%, and with no known cause of HDL deficiency). We have previously shown that four of our FHD patients and patients with TD have mutations at the ABC1 gene, demonstrating that FHD is a heterozygous form of TD. METHODS On each subject, we carried out detailed biochemical analysis and determined apoA-I-mediated cellular cholesterol efflux using 3H-cholesterol labeled skin fibroblasts from study subjects compared with controls. TD has also been associated with abnormal cellular cholesterol efflux. Cell fusion experiments with polyethylene glycol (PEG) were carried out with fibroblasts from a subject with TD and one with FHD in order to determine whether the Tangier cells can complement the FHD defect. In all subjects with a reduced cellular cholesterol efflux, exons of the ABCA1 gene were sequenced. RESULTS Familial forms of HDL deficiency, defined as HDL-C levels <5th percentile, are a heterogeneous group of lipoprotein disorders. A reduced cellular cholesterol efflux has been identified in eight subjects from seven kindred (7/14 or 50% of probands tested), being reduced by a mean 59% of controls (range 49-63%). In four of these subjects, a mutation at the ABCA1 gene locus was identified. In three other subjects an efflux defect was idenfified but no critical mutation at the ABCA1 gene locus has been identified. In the remaining subjects, (7/14), no efflux defect was identified. Complementation studies reveal that the FHD defect is not corrected by Tangier cells, confirming that FHD and TD represent a spectrum of the same genetic defect. CONCLUSION Familial hypoalphalipoproteinemia syndromes are phenotypically heterogeneous; one form is associated with abnormal cellular cholesterol efflux caused by heterozygous mutations at the ABCA1 gene, that defines familial HDL Deficiency while homozygous mutations or compound heterozygocity causes TD. Other forms are primary hypoalphalipoproteinemia of unknown cause, while the remaining cases are associated with hypertriglyceridemia with or without elevated apoB levels. We conclude that a cellular cholesterol defect is a relatively frequent cause of familial HDL deficiency and that a mutation at the ABCA1 gene can be identified in half of these patients.

Fenofibrate raises plasma homocysteine levels in the fasted and fed states

The effect of fenofibrate (FEN), compared with placebo (PL), on total plasma homocysteine (tHcy) levels in the fasted and fed states has been examined. Twenty men with established coronary artery disease (CAD) or with at least two cardiovascular risk factors, who had elevated plasma triglyceride levels (> 2.3 mmol/l) and reduced HDL-C levels (< 0.91 mmol/l), and in whom a fibric acid derivative was clinically indicated were studied. The study was a randomized, PL controlled, double-blind study designed to test the effect of micronized FEN on postprandial lipemia. Plasma tHcy levels were investigated as a post-hoc analysis. After a 4-week dietary stabilization period, patients were randomized to PL or FEN (200 mg/day) for 8 weeks, followed by an 8-h postprandial study, consisting of 1 g fat/kg body weight (35% cream). The methionine content of cream was approximately 0.53 mg/ml. A 5-week washout period was then followed by a second 8-week treatment period (FEN or PL), at the end of which a second postprandial study was undertaken. Blood was sampled in the fasted state (0 h) and postprandially at 2, 4, 6 and 8 h. Plasma was stored at -80 degrees C for homocysteine, vitamins B(6), B(12) and folate measurements. FEN caused a marked decrease in all triglyceride-rich lipoprotein parameters, no change in LDL-C, and an increase in HDL-C levels. Fen treatment was associated with an increase in fasting tHcy (PL: 10.3+/-3.3 micromol/l to FEN: 14.1+/-3.8 micromol/l, 40.4+/-20.5%, P < 0.001) and fed tHcy levels 6 h post-fat load (PL: 11.6+/-3.3 micromol/l vs. FEN: 17.1+/-5.4 micromol/l, P < 0.001). Homocysteine levels were increased by the fat load; PL: 14% (P < 0.001) and FEN: 21%, P < 0.001 at the 2, 4, 6 and 8 h time points. Change in tHcy level on FEN was not associated with changes in plasma levels of folate, vitamins B(6) or B(12) or creatinine. Amino acid analysis revealed that methionine and cysteine were significantly increased on FEN (P < 0.005). The incidence of hyperhomocysteinemia (defined as tHcy level >14 micromol/l) was PL: 2/20 (10%) and FEN: 9/20 (45%) (chi(2) = 4.51, P = 0.034). There was no correlation between changes in plasma triglyceride levels and tHcy levels. Since tHcy is considered an emerging cardiovascular risk factor, the ability of FEN to increase plasma tHcy levels could potentially mitigate the potential of this drug to protect against cardiovascular disease.