Fine mapping and association studies of a high-density lipoprotein cholesterol linkage region on chromosome 16 in French-Canadian subjects.

Low levels of high-density lipoprotein cholesterol (HDL-C) are an independent risk factor for cardiovascular disease. To identify novel genetic variants that contribute to HDL-C, we performed genome-wide scans and quantitative association studies in two study samples: a Quebec-wide study consisting of 11 multigenerational families and a study of 61 families from the Saguenay-Lac St-Jean (SLSJ) region of Quebec. The heritability of HDL-C in these study samples was 0.73 and 0.49, respectively. Variance components linkage methods identified a LOD score of 2.61 at 98 cM near the marker D16S515 in Quebec-wide families and an LOD score of 2.96 at 86 cM near the marker D16S2624 in SLSJ families. In the Quebec-wide sample, four families showed segregation over a 25.5-cM (18 Mb) region, which was further reduced to 6.6 Mb with additional markers. The coding regions of all genes within this region were sequenced. A missense variant in CHST6 segregated in four families and, with additional families, we observed a P value of 0.015 for this variant. However, an association study of this single-nucleotide polymorphism (SNP) in unrelated Quebec-wide samples was not significant. We also identified an SNP (rs11646677) in the same region, which was significantly associated with a low HDL-C (P=0.016) in the SLSJ study sample. In addition, RT-PCR results from cultured cells showed a significant difference in the expression of CHST6 and KIAA1576, another gene in the region. Our data constitute additional evidence for a locus on chromosome 16q23-24 that affects HDL-C levels in two independent French-Canadian studies.

The therapeutic potential of high-density lipoprotein mimetic agents in coronary artery disease.

Low levels of high-density lipoprotein cholesterol (HDL-C) represent a major cardiovascular risk factor that is only modestly influenced by currently available drugs. Consequently, there has been interest in developing new therapeutic agents specifically targeting HDL-C to reduce risk in patients with coronary artery disease. One strategy involves the administration of therapies that mimic HDL-C or its properties, including reconstituted HDL, apolipoprotein A-I (apoA-I), apoA-I Milano, and apoA-I mimetic peptides. The atheroprotective effects of reconstituted HDL, apoA-I, and apoA-I Milano have been well documented in animal studies, and two recent clinical trials also provided encouraging results. The most investigated apoA-I mimetic peptide, D-4F, was shown to significantly reduce atherosclerotic lesions in animal models but data in humans are scarce. HDL-C mimetic agents constitute a promising novel strategy to reduce coronary artery disease risk but require further study in larger clinical trials.

Identification of a novel human cellular HDL biosynthesis defect.

AIMS: Severe high-density lipoprotein cholesterol (HDL-C) deficiency is attributed to mutations in several genes and may contribute to the genetic basis of coronary artery disease. To identify the cellular basis of a novel HDL-deficiency phenotype, we screened 54 subjects of French Canadian ancestry with severe HDL deficiency. METHODS AND RESULTS: We excluded individuals with mutations in genes currently associated with low HDL (ABCA1, LCAT, APOA-I, and SMPD1). We identified two patients in which cellular phospholipid efflux in the HDL biosynthesis process is impaired, whereas cholesterol efflux is normal. Two-dimensional gel electrophoresis analysis further showed that the two patients with impaired phospholipid efflux were defective primarily in the larger alpha-HDL subpopulations. In fibroblasts from affected subjects, oxysterol stimulation resulted in increased ABCA1 protein expression and normalized their defective phospholipid efflux defect. CONCLUSION: Our results indicate for the first time in humans that phospholipid and cholesterol efflux are two separate and distinct processes in cellular HDL biosynthesis. They further show for the first time that normal cellular phospholipid efflux is necessary for the formation of larger alpha-HDL particles. The defect in phospholipid efflux is due to defective ABCA1 protein regulation and can be corrected by treatment with physiological oxysterols, a current therapeutic target of interest, that may, with further studies, be used to raise HDL levels in patients with severe HDL deficiencies.

Long-term rates of cardiovascular events in patients with the metabolic syndrome according to severity of coronary-angiographic alterations.

OBJECTIVES: To assess the long-term risk of mortality and cardiovascular events, related to metabolic syndrome (MetS), in patients with less, or more severe coronary artery disease (CAD). METHODS: One thousand and eighty patients were divided in four groups, according to severity of CAD (1=less than 50% or nonsignificant stenoses; 2=greater or significant stenoses), and according to MetS (A=no; B=yes). Risk was evaluated with the Cox regression analysis. RESULTS: About 18.9% of patients had less and 81.1% more advanced CAD. MetS was present in 45.1% of the first, and in 52.9% of the second group. At baseline, patients with MetS, or significant stenoses, had less favorable medical, biochemical, and angiographic characteristics. During a follow-up of 12.6+/-3.4 years, group 1B had higher incidence (16.3 vs. 7.1%) and hazard ratio [2.36 (1.001-5.57; P=0.0497)] of myocardial infarction than group 1A; group 2B had a higher incidence (19.0 vs. 11.7%) and hazard ratio [1.67 (1.18-2.37; P=0.0041)] of stroke than group 2A. Groups 2A and 2B, as compared with groups 1A and 1B, had a higher incidence of myocardial infarction (39.1 vs. 7.1; 41.8 vs. 16.3%); group 2B had higher incidence of stroke than group 1B (19.0 vs. 9.8%). After adjustment for common risk factors, group 2B retained an elevated risk of stroke. After additional adjustment for diabetes, no event was significantly related to MetS. CONCLUSION: At baseline, coronary patients with MetS, or significant angiographic alterations, had more cardiovascular risk factors. During follow-up, both MetS and significant CAD increased the risk of cardiovascular morbidity but not of mortality.

Intra-operative echographic localization for radioactive ophthalmic plaques in choroidal melanoma.

The objectives were to evaluate the beneficial effect of intra-operative echographic plaque site localization and to assess the rate of complications of postplaque insertion. This paper is a descriptive study of 48 patients with choroidal melanoma who underwent iodine-125 (I(125)) or ruthenium-106 (Ru(106)) plaque radiotherapy with intra-operative echographic confirmation of plaque placement with the aid of a nonradioactive plaque (dummy) at McGill University Health Centre from 1997 to 2003. Patients' mean age was 63.7 years; 52% (25/48) male, 48% (23/48) female. Twenty-seven percent (13/48) of the tumors were confined to the right eye and 73% (35/48) to the left eye. Forty-eight percent (23/48) of the tumors were located posterior to the equator, 14.6% (7/48) were anterior to the equator, 18.7% (9/48) in posterior pole, and 18.7% (9/48) at equator. Sixty-nine percent (33/48) received I(125) and 31% (15/48) had Ru(106) treatment. Ninety percent of the dummy plaques were initially positioned suboptimally and required repositioning under echographic guidance. At mean follow-up of 18.8 months, there was no tumor-related death or metastasis, but one patient required enucleation. The dummy plaque technique under echographic visualization resulted in reduction of radioactive exposure time during surgery of up to 50%. Intra-operative echographic utilization has the ability to localize precisely the tumor-plaque relationship, thereby optimizing the radiation delivered to the choroidal melanoma, while minimizing the surgeon's exposure time.

Iodine-125 radiotherapy for choroidal melanoma.

The objective was to evaluate the effect of the gender, size, and tumor location at the time of the diagnosis on the regression response of choroidal melanoma following plaque radiotherapy treatment. The paper is a longitudinal prospective study of 28 patients diagnosed with choroidal melanoma at McGill University Health Centre from 1997 to 2002. All patients were treated with episcleral iodine-125 (I(125)) plaque radiotherapy. Plaques were inserted at the tumor site under echographic visualization. All patients had medium-size tumors, except for three. Patients had periodic ophthalmic evaluation at 3 and 6 months post radiation treatment, followed by 6-month intervals thereafter. Patients' mean age was 62 +/- 15 years, 16 males and 12 females. Fifty percent of the tumors were located posterior to the equator with significant reduction in size at 12 months post plaque radiotherapy treatment. Significant regression was observed in all the tumor diameters at 5 years post treatment follow-up. Reduction in the depth diameter was significant (P < 0.01) in both male and female groups post treatment. There was a 25% (P < 0.001) reduction in the medium size of tumors at 5-year follow-up. Tumors located posterior to the equator responded best to I(125) plaque radiotherapy. Male patients responded better than females to treatment. Medium-size melanoma responded well to plaque radiotherapy.

WW-domain-containing oxidoreductase is associated with low plasma HDL-C levels.

Low serum HDL-cholesterol (HDL-C) is a major risk factor for coronary artery disease. We performed targeted genotyping of a 12.4 Mb linked region on 16q to test for association with low HDL-C by using a regional-tag SNP strategy. We identified one SNP, rs2548861, in the WW-domain-containing oxidoreductase (WWOX) gene with region-wide significance for low HDL-C in dyslipidemic families of Mexican and European descent and in low-HDL-C cases and controls of European descent (p = 6.9 x 10(-7)). We extended our investigation to the population level by using two independent unascertained population-based Finnish cohorts, the cross-sectional METSIM cohort of 4,463 males and the prospective Young Finns cohort of 2,265 subjects. The combined analysis provided p = 4 x 10(-4) to 2 x 10(-5). Importantly, in the prospective cohort, we observed a significant longitudinal association of rs2548861 with HDL-C levels obtained at four different time points over 21 years (p = 0.003), and the T risk allele explained 1.5% of the variance in HDL-C levels. The rs2548861 resides in a highly conserved region in intron 8 of WWOX. Results from our in vitro reporter assay and electrophoretic mobility-shift assay demonstrate that this region functions as a cis-regulatory element whose associated rs2548861 SNP has a specific allelic effect and that the region forms an allele-specific DNA-nuclear-factor complex. In conclusion, analyses of 9,798 subjects show significant association between HDL-C and a WWOX variant with an allele-specific cis-regulatory function.

Sphingomyelin phosphodiesterase-1 (SMPD1) coding variants do not contribute to low levels of high-density lipoprotein cholesterol.

BACKGROUND: Niemann-Pick disease type A and B is caused by a deficiency of acid sphingomyelinase due to mutations in the sphingomyelin phosphodiesterase-1 (SMPD1) gene. In Niemann-Pick patients, SMPD1 gene defects are reported to be associated with a severe reduction in plasma high-density lipoprotein (HDL) cholesterol. METHODS: Two common coding polymorphisms in the SMPD1 gene, the G1522A (G508R) and a hexanucleotide repeat sequence within the signal peptide region, were investigated in 118 unrelated subjects of French Canadian descent with low plasma levels of HDL-cholesterol (< 5th percentile for age and gender-matched subjects). Control subjects (n = 230) had an HDL-cholesterol level > the 25th percentile. RESULTS: For G1522A the frequency of the G and A alleles were 75.2% and 24.8% respectively in controls, compared to 78.6% and 21.4% in subjects with low HDL-cholesterol (p = 0.317). The frequency of 6 and 7 hexanucleotide repeats was 46.2% and 46.6% respectively in controls, compared to 45.6% and 49.1% in subjects with low HDL-cholesterol (p = 0.619). Ten different haplotypes were observed in cases and controls. Overall haplotype frequencies in cases and controls were not significantly different. CONCLUSION: These results suggest that the two common coding variants at the SMPD1 gene locus are not associated with low HDL-cholesterol levels in the French Canadian population.

Surgical strategies for severe calcification of the aorta (porcelain aorta) in two patients with homozygous familial hypercholesterolemia.

Homozygous familial hypercholesterolemia (HzFH) is a rare genetic defect caused predominantly by mutations at the low-density lipoprotein receptor. Until recent advances in the management of this complex disorder, patients affected by HzFH rarely survived beyond 30 years of age. Two patients with HzFH who survived to adulthood and developed cardiovascular complications requiring surgery are reported. In these patients, a porcelain aorta complicated surgical management. Lipid profile, mutational analysis and pathological assessment of the aorta were performed in two patients referred for cardiac surgery. The first patient was a 46-year-old man with a history of coronary artery bypass grafting (CABG) and recurrent severe angina who, because of a heavily calcified ascending aorta, required a complex repeat CABG. The second patient was a 42-year-old woman who underwent CAGB at 28 years of age and presented 13 years later with aortic stenosis. The extensive calcifications of the whole aortic root required performance of a modified Cabrol procedure. A porcelain aorta appears to be a feature of HzFH. This has an important impact on surgical planning and management and on possible pathophysiological processes related to the cardiovascular complications of HzFH.

Genetics of high-density lipoproteins.

PURPOSE OF REVIEW: High-density lipoproteins have multi-factorial anti-atherosclerosis properties: they have potent anti-oxidant effects and prevent the oxidation of low-density lipoproteins; they have anti-inflammatory effects; they modulate vascular endothelial cell function and transport cholesterol back to the liver for excretion into the bile - a process called reverse cholesterol transport. The present review focuses on genetic aspects of high-density lipoprotein metabolism, with genomic approaches used to identify genes that regulate high-density lipoproteins in humans. RECENT FINDINGS: Disorders of the many genes that code for proteins, including transporters, enzymes, receptors, transfer proteins and lipases, involved in high-density lipoprotein metabolism have been identified in humans as causing extremes of high-density lipoprotein cholesterol, and provide potential novel therapeutic avenues. These, however, explain fewer than 5% of the causes of low high-density lipoprotein cholesterol in the general population. SUMMARY: Genome-wide linkage studies of large cohorts, with discrete as well as quantitative trait loci analyses, followed by association studies have enabled the identification of large chromosomal regions that may harbor genes that modulate high-density lipoprotein cholesterol levels in humans. Using mouse genetics, the results of the HapMap project and novel genetic approaches will allow the discovery of novel genes in high-density lipoprotein metabolism.

New insights into the biogenesis of human high-density lipoproteins.

PURPOSE OF REVIEW: The interest for the human HDL system was recently revived by the identification of the ABCA1 as a critical component in the formation and maintenance of plasma HDL levels. The present review focuses on recent progress in our understanding of the basic mechanisms underlying HDL biogenesis pathways. RECENT FINDINGS: Several novel mechanisms governing ABCA1/apoA-I interactions have recently been identified: apolipoprotein A-I activates ABCA1 phosphorylation through the cAMP/protein kinase A-dependent pathway; the majority of ABCA1 exists as a tetramer in human living cell, supporting the concept that the homotetrameric ABCA1 complex constitutes the minimum functional unit for the formation of nascent HDL particles; apolipoprotein A-I has been shown to have a recycling retroendocytic pathway with uptake and resecretion of the lipidated nascent HDL particles by the cell, most likely through the ABCA1 transporter pathway; there is evidence that the speciation of nascent HDL into pre-beta and alpha-HDL is linked to specific cell lines, and occurs by both ABCA1-dependent and independent pathways. SUMMARY: The fundamental mechanisms underlying the biogenesis, speciation and maturation of HDL remain complex and not well understood. Understanding the mechanisms governing HDL genesis at the cellular level could provide novel insights into the human atheroprotective system in health and disease.

Identification of a novel C5L2 variant (S323I) in a French Canadian family with familial combined hyperlipemia.

OBJECTIVE: A functional acylation stimulating protein (ASP) receptor, C5L2, has been recently identified in ASP-responsive cells. Impaired ASP-mediated triglyceride synthesis has previously been described in a subset of hyperapolipoprotein B/familial combined hyperlipidemia subjects. METHODS AND RESULTS: DNA sequencing of C5L2 coding region in 61 unrelated probands identified a heterozygous variant (G968-->T) in 1 subject, resulting in Ser323-->Ile substitution in the carboxyl terminal region. This variant was not detected in 2176 additional chromosomes by restriction fragment length polymorphism or fluorescence polarization genotyping. Eight family members of the proband were identified with one altered (+/-)C5L2 allele. Nine other family members had the wild-type (+/+)C5L2 sequence. The abnormal allele was associated with increased plasma triglyceride, plasma cholesterol, low-density lipoprotein (LDL) cholesterol, apolipoprotein B and ASP. Of 23 subjects tested in cell-based ASP bioactivity assays, those with C5L2(+/-) variant (n = 2) had a 50% reduction in ASP-stimulated triglyceride synthesis, glucose transport and marked reduction in maximal binding (B(max)). By contrast, a C5L2(+/+) family member responded normally, as did hyperapolipoprotein B normal ASP subjects compared with C5L2(+/+) controls (n = 6). CONCLUSIONS: The S323I variant may alter C5L2 function and might be one molecular basis contributing to familial combined hyperlipidemia.

Cellular cholesterol homeostasis in vascular endothelial cells.

Atherosclerosis is a disease of blood vessel walls that is thought to be initiated as a reaction of insults to the endothelium. The complex sequence of cellular events that begins with focal inflammation leads to the accumulation of leukocytes in the subendothelial layer and unrestricted uptake of oxidized lipoproteins by macrophages and smooth muscle cells, leading to foam cell formation. Vascular endothelial cells do not undergo the foam cell transformation and do not accumulate cholesterol in atherosclerotic plaques to the same extent as macrophages or smooth muscle cells. However, vascular endothelial cells express receptors for oxidized lipoproteins, and have the biochemical pathways for sterol synthesis and receptor-mediated endocytosis of lipoproteins. Data from the authors' laboratory show that high density lipoproteins but not lipid-free apolipoprotein A-I promote cellular cholesterol efflux in human umbilical vascular endothelial cells and human aortic endothelial cells. Gene expression microarrays were used to examine the differential expression of genes after cholesterol loading. While sterol regulatory element-binding protein-sensitive genes were downregulated, the authors identified a novel transporter, the ATP-binding cassette G1 (ABCG1) to be highly expressed in response to both cellular cholesterol loading and stimulation with the liver X receptor agonist 22-hydroxycholesterol. The ABCA1 gene and protein, the major modulator of cellular cholesterol efflux in macrophages and in peripheral and hepatic tissues, are only weakly expressed in human umbilical vascular endothelial cells and human aortic endothelial cells. These data suggest that endothelial cells maintain cholesterol homeostasis by downregulating cholesterol synthesis and low density lipoprotein receptors and by a cellular cholesterol efflux mechanism onto low-affinity but high-capacity high density lipoproteins. The role of ABC-type transporters, including ABCG1, requires further examination.

Evidence for a gene influencing high-density lipoprotein cholesterol on chromosome 4q31.21.

OBJECTIVE: A low level of plasma high-density lipoprotein cholesterol (HDL-C) is a major risk factor for coronary atherosclerosis. To identify novel genes regulating plasma HDL-C levels, we investigated 13 multigenerational French Canadian families with an average of 12 affected individuals per family for genome-wide signals, which we subsequently fine mapped. METHODS AND RESULTS: We genotyped a total of 362 individuals, including 151 affected subjects for 485 autosomal microsatellite markers. In parametric 2-point linkage analyses, the highest 2-point logarithm of odds (lod) score of 4.6 was observed with marker D4S424 on chromosome 4q31.21 (at approximately 142 Mb). The multipoint analysis of this region resulted in a lod score of 3.8 and a lod -1 region of 12.2 cM, containing 40 known genes. The results were obtained by allowing for genetic heterogeneity among these extended pedigrees, and approximately 50% of families were linked to this region with the highest single-pedigree lod score being 3.6. We further restricted the linked region from 12.2 to 2.9 cM (2.37 Mb) by genotyping 15 additional markers in the 3 families with the highest lod scores. We sequenced 4 genes with a likely role in lipid metabolism as well as 2 genes residing directly under the linkage peak but found no evidence for a causative variant. None of the genes residing in the significantly restricted 2.37-Mb region has been associated previously with HDL-C metabolism. CONCLUSIONS: This study provides significant evidence for a gene influencing HDL-C on chromosome 4q31.21.

Functional mutations of the ABCA1 gene in subjects of French-Canadian descent with HDL deficiency.

Mutations in the ABCA1 gene cause defective cellular lipid efflux and severe familial HDL deficiency. We examined the prevalence of mutations at the ABCA1 gene in 58 unrelated probands of French-Canadian descent with HDL deficiency (HDL-C<5th percentile). A defective cellular cholesterol or phospholipid efflux (<75% and <70% of normal controls, respectively) was identified in 14/58 (24%) of subjects. Using direct sequencing of the ABCA1 gene, we found mutations in 12/58 ( approximately 20%) of subjects. Four probands were previously identified with diverse ABCA1 gene defects. However, we identified a novel frameshift mutation (F1840L, L1869X); a proband was heteroallelic for the N1800H mutation, previously reported in a case of Tangier disease, and a novel missense mutation (Q2210H); a novel variant (G616V), predicted to impart a functional defect in the protein, was also found in another proband. Three probands had the S1731C mutation, while two others had the R1851X and K776N documented mutations, respectively. Taken together, these data suggest that approximately 20% of French-Canadian patients with severe HDL deficiency are associated with a defective ABCA1. Interestingly, in two families studied, mutations in the ABCA1 gene did not segregate with the lipid efflux defect, suggesting that other proteins are involved in the ABCA1-mediated cellular lipid efflux.

Increased sphingomyelin content impairs HDL biogenesis and maturation in human Niemann-Pick disease type B.

We previously reported that human Niemann-Pick Disease type B (NPD-B) is associated with low HDL. In this study, we investigated the pathophysiology of this HDL deficiency by examining both HDL samples from NPD-B patients and nascent high density lipoprotein (LpA-I) generated by incubation of lipid-free apolipoprotein A-I (apoA-I) with NPD-B fibroblasts. Interestingly, both LpA-I and HDL isolated from patient plasma had a significant increase in sphingomyelin (SM) mass ( approximately 50-100%). Analysis of LCAT kinetics parameters (V(max) and K(m)) revealed that either LpA-I or plasma HDL from NPD-B, as well as reconstituted HDL enriched with SM, exhibited severely decreased LCAT-mediated cholesterol esterification. Importantly, we documented that SM enrichment of NPD-B LpA-I was not attributable to increased cellular mass transfer of SM or unesterified cholesterol to lipid-free apoA-I. Finally, we obtained evidence that the conditioned medium from HUVEC, THP-1, and normal fibroblasts, but not NPD-B fibroblasts, contained active secretory sphingomyelinase (S-SMase) that mediated the hydrolysis of [(3)H]SM-labeled LpA-I and HDL(3). Furthermore, expression of mutant SMase (DeltaR608) in CHO cells revealed that DeltaR608 was synthesized normally but had defective secretion and activity. Our data suggest that defective S-SMase in NPD leads to SM enrichment of HDL that impairs LCAT-mediated nascent HDL maturation and contributes to HDL deficiency. Thus, S-SMase and LCAT may act in concert and play a crucial role in the biogenesis and maturation of nascent HDL particles.

A novel nonsense apolipoprotein A-I mutation (apoA-I(E136X)) causes low HDL cholesterol in French Canadians.

The molecular causes of severe high-density lipoprotein cholesterol (HDL-C) deficiency was examined in a group of 54 unrelated French Canadian subjects. The lecithin:cholesterol acyl transferase (LCAT) and apolipoprotein (apo) A-I gene were analyzed in all probands by direct DNA sequencing. While no LCAT mutation was detected, a novel nonsense apoA-I mutation (E136X) was found in 3/54 probands. Genetic analysis of two kindreds showed a strong co-segregation of the apoA-I locus with the low HDL-C trait. The E136X mutation was detected in families by MaeI restriction digestion. E136X carriers (n=17) had marked HDL-C deficiency; among the nine carriers > or = 35 years old, five men had developed premature coronary artery disease (CAD). A peptide of apparent molecular weight of 14 kDa was identified in fresh plasma, the HDL fractions and lipoprotein deficient plasma from the three probands but not in normal controls (n=3), suggesting that the mutant apoA-I peptide is secreted and binds lipids. The mutation was not observed in an additional 210 chromosomes from unrelated subjects of French Canadian descent, < 60 years of age, with CAD and low HDL-C levels. We conclude that apoA-I (E136X) is a cause of HDL-C deficiency in the French Canadian population and is associated with premature CAD.

Effect of fenofibrate on plasma lipoprotein composition and kinetics in patients with complete hepatic lipase deficiency.

OBJECTIVE: The goal of this study was to characterize the effect of microcoated fenofibrate (160 mg/day for 6 months) on plasma lipoprotein composition and kinetics in 2 patients with complete hepatic lipase (HL) deficiency. METHODS AND RESULTS: Fenofibrate treatment normalized the plasma lipoprotein profile of patients with complete HL deficiency, as evidenced by significant reductions in the plasma concentration of cholesterol (-49%) and triglycerides (-82%) and a significant increase in low-density lipoprotein (LDL) size (251.5+/-1.8 versus 263.5+/-0.7 A). The in vivo kinetics of very low-density lipoprotein (VLDL), intermediate-density lipoprotein (IDL), and LDL apolipoprotein (apo)B-100 and plasma apoA-I and apoA-II were studied using a primed-constant infusion of L-[5,5,5-D3]-leucine for 12 hours in the fasted state. Fenofibrate treatment in complete HL-deficient patients substantially decreased plasma concentrations of VLDL, IDL, and LDL apoB-100 attributable to important increases in VLDL (+325%), IDL (+129%), and LDL (+218%) apoB-100 fractional catabolic rates (FCR). IDL apoB-100 FCR nevertheless remained 60% lower after treatment compared with values obtained in controls (n=5). The kinetics of plasma apoA-I and apoA-II as well as the capacity of total plasma and of high-density lipoprotein particles to efflux cellular cholesterol from normal human skin fibroblasts was not altered by fenofibrate. CONCLUSIONS: Fenofibrate therapy exerts a pronounced antiatherogenic effect on triglyceride-rich lipoproteins even in the complete absence of HL.

Biogenesis and speciation of nascent apoA-I-containing particles in various cell lines.

It is generally thought that the large heterogeneity of human HDL confers antiatherogenic properties; however, the mechanisms governing HDL biogenesis and speciation are complex and poorly understood. Here, we show that incubation of exogenous apolipoprotein A-I (apoA-I) with fibroblasts, CaCo-2, or CHO-overexpressing ABCA1 cells generates only alpha-nascent apolipoprotein A-I-containing particles (alpha-LpA-I) with diameters of 8-20 nm, whereas human umbilical vein endothelial cells and ABCA1 mutant (Q597R) cells were unable to form such particles. Interestingly, incubation of exogenous apoA-I with either HepG2 or macrophages generates both alpha-LpA-I and prebeta1-LpA-I. Furthermore, glyburide inhibits almost completely the formation of alpha-LpA-I but not prebeta1-LpA-I. Similarly, endogenously secreted HepG2 apoA-I was found to be associated with both prebeta1-LpA-I and alpha-LpA-I; by contrast, CaCo-2 cells secreted only alpha-LpA-I. To determine whether alpha-LpA-I generated by fibroblasts is a good substrate for LCAT, isolated alpha-LpA-I as well as reconstituted HDL [r(HDL)] was reacted with LCAT. Although both particles had similar V(max) (8.4 vs. 8.2 nmol cholesteryl ester/h/microg LCAT, respectively), the K(m) value was increased 2-fold for alpha-LpA-I compared with r(HDL) (1.2 vs. 0.7 microM apoA-I). These results demonstrate that 1) ABCA1 is required for the formation of alpha-LpA-I but not prebeta1-LpA-I; and 2) alpha-LpA-I interacts efficiently with LCAT. Thus, our study provides direct evidence for a new link between specific cell lines and the speciation of nascent HDL that occurs by both ABCA1-dependent and -independent pathways.

Genetic lipoprotein disorders and coronary atherosclerosis.

Familial lipoprotein disorders are seen frequently in subjects with premature coronary artery disease. The genetic basis for several dyslipoproteinemias has been elucidated in the past two decades. The majority of lipoprotein disorders result from a combination of polygenic predisposition and poor lifestyle habits, including physical inactivity, increased visceral adipose tissue, increased caloric intake, and cigarette smoking. Monogenic disorders are seen in approximately 5% of premature coronary artery disease cases, and this prevalence is higher in populations with the Founder effect. Unraveling the genetic basis of many lipoprotein disorders has allowed fundamental discoveries in molecular cellular physiology and has paved the way for novel therapeutic approaches.