Apolipoprotein B gene mutations affecting cholesterol levels.

In the past 5 years, many different mutations in the apolipoprotein (apo) B gene have been described that affect plasma cholesterol levels. More than 20 different mutations in the apoB gene have been shown to cause familial hypobetalipoproteinaemia, a condition characterized by abnormally low plasma concentrations of apoB and LDL cholesterol. Almost all of the mutations are nonsense or frameshift mutations that interfere with the translation of a full-length apoB100 molecule. Many, but not all, of these apoB gene mutations result in the synthesis of a truncated species of apoB that can be detected within the plasma lipoproteins. Familial hypobetalipoproteinaemia heterozygotes are almost always asymptomatic and have LDL cholesterol levels about one-quarter to one-third of those of unaffected family members. Several homozygotes and compound heterozygotes for familial hypobetalipoproteinaemia have been described. In these individuals, the LDL cholesterol levels are extremely low, usually less than 5 or 10 mg dl-1, and the clinical phenotype is variable, ranging from completely asymptomatic to severe problems related to intestinal fat malabsorption. One missense mutation in the apoB gene (an Arg----Gln substitution at apoB amino acid 3500) is associated with very poor binding of apoB100 to the cellular LDL receptor. This syndrome has been designated familial defective apolipoprotein B (FDB). The amino-acid substitution at residue 3500 delays the clearance of LDL from the plasma and results in hypercholesterolaemia. In some Western populations, the frequency of FDB heterozygotes appears to be as high as 1 in 500 individuals.     

Plasma Lp(a) values in familial hypercholesterolemia and its relation to coronary heart disease

BACKGROUND AND AIM: To analyze plasma Lp(a) levels and examine different risk factors and coronary heart disease (CHD) in a sample of genetically diagnosed familial hypercholesterolemia (FH) patients. METHODS AND RESULTS: Ninety heterozygous FH patients and 41 non-FH relatives were enrolled in a study to evaluate their plasma and lipoprotein cholesterol, as well as their triglyceride and Lp(a) levels. We found no differences in plasma Lp(a) levels and log transformed values between 90 FH subjects and their 41 unaffected relatives (22.3 mg/dl +/- 19.4 vs 17.7 mg/dl +/- 21.3 and 1.12 +/- 0.5 vs 0.96 +/- 0.54) nor between null allele and defective allele FH subjects (log Lp (a) levels 2.013 +/- 0.282 vs 1.959 +/- 0.151). FH CHD+ were significantly older, and had higher mean systolic and diastolic blood pressure and higher mean plasma triglyceride levels than FH CHD-. No differences in mean and log transformed Lp(a) plasma concentrations were found. CONCLUSIONS: Plasma Lp(a) levels are not related to LDL receptor status and class mutations, nor to the presence of CHD in FH patients.     

Contribution of receptor negative versus receptor defective mutations in the LDL-receptor gene to angiographically assessed coronary artery disease among young (25-49 years) versus middle-aged (50-64 years) men

Elevated plasma LDL-cholesterol (LDL-C) levels are associated with an increased risk of coronary artery disease (CAD). Familial hypercholesterolemia (FH), a monogenic trait due to mutations in the LDL-receptor (R) gene is characterized by raised plasma LDL-C levels and premature CAD. The aim of the present investigation, derived from the study of a population of 1465 unrelated men aged 25 to 64 years, was to compare the expression of CAD assessed by coronary angiography in young (aged 25-49 years) versus middle-aged (50-64 years) heterozygous FH patients of French Canadian descent. Furthermore, the relationship of binding-defective versus receptor negative mutations in the LDL-R to premature CAD ( < 50 years) was examined and compared with men displaying a normal plasma lipoprotein-lipid profile. From the original study sample, a total of 100 men met the clinical criteria of heterozygous FH. Among them, 30 were carriers of a receptor negative mutation (deletion > 15 kb or point mutations Y468X or R329X) whereas 64 were carriers of a receptor defective mutation (W66G, E207K or C646Y). As expected, in both age groups (25-49 years vs. 50-64 years), carriers of a receptor negative mutation had higher plasma cholesterol and LDL-C levels than carriers of a defective allele or men with a normal plasma lipoprotein-lipid profile. In addition, the mean number of diseased vessels (with > 50% stenosis) was higher in men aged 50-64 years compared to those aged 25 49 years. In the two age groups, FH patients were characterized by a higher number of stenosed coronary vessels than the normal phenotype group. Within each group (either receptor negative, receptor defective or normal phenotype) plasma cholesterol, LDL-C, HDL-C, triglyceride and apolipoprotein B levels were similar irrespective of age (25 49 years vs. 50-64 years). Finally, multiple logistic regression analyses revealed that compared to non-FH men, the relative odds of being affected by CAD before the age of 50 years was 7.3-fold higher for carriers of a receptor negative mutation and 2.7-fold higher for men with a receptor defective mutation at the LDL-R locus. These results suggest that CAD could be an earlier event among heterozygous FH subjects bearing a receptor negative mutation compared to LDL-R defective patients. It also suggest that the selective screening for mutations in the LDL-R gene may allow a better assessment of the individual risk and facilitate the development of family-based preventive strategies or intervention programs in FH.     

Rapid screening for specific mutations in patients with a clinical diagnosis of familial hypercholesterolaemia.

We describe a rapid screening procedure to identify known DNA sequence changes in individuals diagnosed as having heterozygous familial hypercholesterolaemia (FH). The screening is made possible by combining a rapid DNA extraction protocol and small scale polymerase chain reaction DNA amplification, followed by oligonucleotide melting or restriction enzyme digestion. We have screened for two different mutations; firstly a mutation in the apolipoprotein B (apo B) gene that results in the substitution of glutamine (Gln) for arginine (Arg) at amino acid residue 3500 (apo B3500 mutation). Apo B is the principal component of the protein moiety of low density lipoprotein (LDL) and the mutation reduces the affinity for the LDL receptor (LDL-R). Secondly we have screened for a point mutation in the LDL-R gene itself that creates a new Pst I restriction enzyme site. This mutation in the LDL-R gene (LDL-R664 mutation) results in the substitution of leucine (Leu) for proline (Pro) at amino acid 664 and is known to slow processing of the LDL-R precursor to the mature form and to reduce the affinity of the receptor on the cell surface for LDL. In 77 unrelated patients with a clinical diagnosis of FH two out of 77 (2.6%) were positive for the apo B3500 mutation. Three (3.9%) were positive for the LDL-R664 mutation. Thus these two mutations might account for 5-6% of patients in the U.K. with a clinical diagnosis of FH (5000-6000 people).(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of apolipoprotein B metabolism in familial defective apolipoprotein B and heterogeneous familial hypercholesterolemia

Both defective LDL receptors (familial hypercholesterolaemia, FH) and mutations in apolipoprotein B (apoB) on LDL (familial defective apoB, FDB) give rise to a phenotype of elevated LDL cholesterol. We sought to compare the metabolic basis of the two conditions by examining apoB turnover in FDB and FH subjects. A group comprising three heterozygous and one homozygous FDB subjects were compared with five FH heterozygotes and 17 control subjects using a deuterated leucine tracer. Kinetic parameters were derived by multicompartmental modelling. FH heterozygotes had a reduced delipidation rate for VLDL, which led to a moderate increase in plasma triglyceride. Compared with controls and FH, the FDB subjects converted 44% less IDL to LDL. The LDL FCR was reduced to a similar extent in FDB and FH. In all subjects LDL plasma levels appeared to be regulated by the LDL FCR and the rate of production of small VLDL. We conclude that disturbances in IDL metabolism provide the basis for understanding why FDB is less severe than FH. Our findings suggest that an apoB-LDL receptor interaction is important in the IDL to LDL conversion.     

Apolipoprotein H variant modifies plasma triglyceride phenotype in familial hypercholesterolemia: a molecular study in an eight-generation hyperlipidemic family

In the course of investigating familial coronary artery disease in Utah, we studied 196 members of an eight-generation extended family of familial hypercholesterolemia (FH), in which 73 members were affected with type IIa hyperlipoproteinemia (HLPIIa; high plasma cholesterol) and 11 members with type IIb hyperlipoproteinemia (HLPIIb; high plasma cholesterol as well as plasma triglyceride). A splice-site mutation of the LDL receptor (LDLR) gene (IVS14 + G > A) co-segregated with elevated plasma cholesterol among all the members, but not with the elevated plasma triglyceride and VLDL cholesterol levels seen in HLPIIb patients. The apolipoprotein H (apoH) gene plays a role in plasma triglyceride removal and lipoprotein lipase enhancement. Intra-familial correlation analysis of the modifier effect of Val247Leu substitution in the apoH gene was carried out among 84 LDLR-mutation carriers and 112 non-carriers. When plasma triglyceride levels in the LDLR-mutation carriers were compared, the values were lowest among V/V homozygotes (mean +/- SD = 145 +/- 53 mg/dl), highest in L/L homozygotes (277 +/- 177 mg/dl), and intermediate among V/L heterozygotes (191 +/- 102 mg/dl) (p = 0.0015). All eleven patients who presented with HLPIIb had inherited both the defective LDLR allele and an apoH 247Leu allele, whereas all 45 carriers of the defective LDLR allele not carrying the apoH Leu allele presented with HLPIIa but not HLPIIb (p = 0.0001). These results indicate a significant modification of the phenotype of FH with a defective LDLR allele, by apoH Leu variation in our studied family.     

Clinical and biochemical characterisation of patients with autosomal recessive hypercholesterolemia (ARH)

BACKGROUND AND AIM: Inherited hypercholesterolemias are common disorders characterised by elevated LDL-C levels and premature coronary heart disease. We have recently described a recessive form of hypercholesterolemia (autosomal recessive hypercholesterolemia, ARH) in which LDL catabolism is reduced because of a mutation in the gene coding for an adaptor protein that impairs LDL-receptor (LDL-R) activity in the liver. The aim of this study was to characterise in detail the phenotypes of subjects with homozygous and heterozygous ARH. METHODS AND RESULTS: We have so far identified six Italian families with ARH and studied the clinical and biochemical characteristics of 11 homozygotes (age 13-47 years) and 12 obligate heterozygotes (age 42-83 years). The study protocol included an evaluation of the lipoprotein profile, LDL-R activity in fibroblasts, LDL binding activity, and apo E genotype; a structured questionnaire (CHD risk factors, medical history, current medications); a physical examination, resting and stress ECG, ultrasound examinations (heart, carotid arteries, Achilles tendons) and coronary angiography. The pedigrees were characterised by the absence of vertical transmission; consanguinity was documented in two families. Only the two previously described Sardinian mutations, ARH1 (c.432insA) and ARH2 (c.65G > A), were identified in the probands. All of the ARH homozygotes had large tendinous xanthomas, two had exertional angina, and four a positive stress ECG. None had experienced myocardial infarction or stroke. More than half had instrumental signs of atherosclerosis such as a positive stress ECG or positive carotid echo-doppler examination. The ARH heterozygotes were consistently normal and had a normal lipid profile. CONCLUSIONS: The ARH phenotype resembles that of familial hypercholesterolemia (FH) homozygotes, but ARH may be a less serious illness. The absence of vertical transmission, and the presence of mild coronary heart disease and consanguinity, can suggest a possible diagnosis of ARH. ARH might be considered a phenocopy of FH but heterozygous subjects seem to have a consistently normal phenotype.     

Pravastatin in heterozygous familial hypercholesterolemia: low-density lipoprotein (LDL) cholesterol-lowering effect and LDL receptor activity on skin fibroblastS.

The cholesterol-lowering effect of provastatin, a new competitive inhibitor of 3-hydroxy-3-methyl-glutaryl coenzyme A (HMG-CoA) reductase, was studied in 10 patients with heterozygous familial hypercholesterolemia (FH). Residual low-density lipoprotein receptor (LDL-R) activity was also evaluated in cultured skin fibroblasts prior to treatment, and showed a wide range of reduction from 30% to 70% of the normal value. Treatment with pravastatin 40 mg once daily reduced total and LDL cholesterol (LDL-C) after 6 months by 19.7% and 25.4%, respectively (P less than .001). Serum apolipoprotein (apo) B levels decreased significantly by 29.1% (P less than .001). No significant changes were observed in mean serum total triglycerides or high-density lipoprotein cholesterol (HDL-C) levels. A positive correlation between residual LDL-R activity and maximum percent reduction of LDL-C levels was observed (r = .676, P less than .05). No clinically important side effects were recorded and the treatment was well tolerated. Thus, pravastatin effectively reduces LDL in heterozygous FH, and this effect appears to be related to LDL-R status.     

Familial defective apolipoprotein B versus familial hypercholesterolemia: an assessment of risk

Patients with familial hypercholesterolemia (FH) or familial defective apolipoprotein B (FDB) have severely increased low-density lipoprotein (LDL)-cholesterol levels and increased risk for premature coronary artery disease (CAD). Previous data on FDB patients were collected in patients referred to lipid clinics and were therefore subject to referral bias. We assessed the clinical phenotype of FDB in a population free from selection on CAD to compare the atherosclerotic burden with that of heterozygous FH. The study population was actively recruited in a large-scale screening program for inherited hypercholesterolemia in which FH and FDB heterozygotes were diagnosed by standard molecular techniques. Patients with FH and FDB had significantly higher plasma total cholesterol and LDL-cholesterol levels compared with their unaffected relatives. As with previous findings in FH, in FDB 19% of the carriers and 17% of the noncarriers of apoB mutations would have been misdiagnosed by cholesterol measurement alone, taking the age- and sex-specific 95th percentile as the diagnostic criterion. In FH patients the CAD risk was 8.5 relative to unaffected family members, whereas FDB patients had a 2.7-fold higher risk of CAD than unaffected relatives. FDB patients, free from clinical selection bias, do show lower total and LDL-cholesterol levels and lower CAD risk compared with FH heterozygotes. However, FDB patients are still exposed to a substantially higher CAD risk compared with unaffected relatives.     

Defects in the low density lipoprotein receptor gene affect lipoprotein (a) levels: multiplicative interaction of two gene loci associated with premature atherosclerosis.

The lipoprotein (a) [Lp(a)] contains two nonidentical protein species, apolipoprotein (apo) B-100 and a specific high molecular weight glycoprotein, apo(a). Lp(a) represents a continuous quantitative genetic trait, the genetics of which are only poorly understood. Genetic variation at the apo(a) locus affects plasma Lp(a) levels and explains at least 40% of the variability of this trait. Lp(a) levels were found to be elevated 3-fold in the plasma from patients with the heterozygous form of familial hypercholesterolemia who have one mutant low density lipoprotein receptor gene. This elevation was not due to a higher frequency of those apo(a) types that are associated with high Lp(a) levels in familial hypercholesterolemia patients. Rather Lp(a) levels were elevated for each of the apo(a) phenotypes examined. The effects of the apo(a) and low density lipoprotein receptor genes on Lp(a) levels are not additive but multiplicative. This is a situation not commonly considered in quantitative human genetics. We conclude that Lp(a) levels in plasma may be determined by variation at more than one gene locus.     

Effects of fenofibrate on apolipoprotein kinetics in patients with coexisting dysbetalipoproteinemia and heterozygous familial hypercholesterolemia

Dysbetalipoproteinemia (dysb) and familial hypercholesterolemia (FH) are two genetic disorders giving rise to severe disturbances of lipid homeostasis and premature atherosclerosis. The co-occurrence of both metabolic abnormalities is very rare and is estimated to affect 1 individual per 2,500,000 in the general population. However, the relative contribution of these two dyslipidemias to the combined lipoprotein phenotype is unknown. The two objectives of this study were (1) to compare the in vivo kinetics of triglyceride-rich lipoprotein (TRL) apolipoprotein (apo) B48, VLDL, IDL and LDL apo B100 as well as plasma apo A-l labelled with a stable isotope (l-(5,5,5-D3) leucine) in two subjects presenting both heterozygous FH and dysbetalipoproteinemia (FH+/dysb+), in six FH heterozygotes and in five normolipidemic controls, and (2) to examine the impact of a 6-week treatment with micronized fenofibrate 200 mg/d on apolipoprotein kinetics in FH+/dysb+. As compared with FH heterozygotes and controls, the two FH+/dysb+ subjects showed elevated TRL apo B48 and VLDL, IDL apo B100 pool sizes (PS) mainly due to lower fractional catabolic rates (FCR). Moreover, as compared with FH heterozygotes, FH+/dysb+ subjects presented lower LDL apo B100 PS due to a higher FCR. Pool size, FCR and production rate (PR) of apo A-l were higher in FH+/dysb+ subjects than in FH heterozygotes. In FH+/dysb+ subjects, fenofibrate treatment was associated with a decreased TRL apo B48 PS (-52 and -61%), VLDL apo B100 (-61 and -63%) and IDL apo B100 (-37 and -16%) and an increased FCR of TRL apo B48 (10 and 67%), VLDL apo B100 (123 and 57%) and IDL apo B100 (29 and 10%). Fenofibrate also increased LDL apo B100 PS (3 and 57%) due to an increase in PR (80 and 26%) but had divergent effects on LDL apo B100 FCR. These results indicate that the coexistence of dysbetalipoproteinemia and heterozygous FH results in a mixed lipoprotein phenotype that is intermediate between the two pure phenotypes and that fenofibrate treatment partially reverses lipoprotein abnormalities, mostly through changes in PR and FCR of apo B48- and B100-containing lipoproteins.     

Lipoprotein Lp(a) in homozygous familial hypercholesterolemia: density profile, particle heterogeneity and apolipoprotein(a) phenotype.

Homozygous familial hypercholesterolemia (FH) is a genetic disorder featuring a functional defect in cellular LDL receptors, marked elevation in circulating LDL concentrations, and premature atherosclerosis. The potential atherogenic role of apo B-containing lipoproteins other than LDL in this disease is indeterminate. We describe the quantitative and qualitative characteristics of Lp(a) as a function of apo(a) phenotype in a group of eight, unrelated homozygous FH patients. Plasma Lp(a) levels were significantly elevated (2.5-fold; mean 50 +/- 32 mg/dl) as compared to those in healthy subjects. The S2 isoform of apo(a) occurred most frequently (6 of eight patients); the rare B isoform presented in three patients. Plasma Lp(a) levels in homozygous FH did not correspond to those predicted by apo(a) phenotype. Analyses of the density distribution of Lp(a) and of Lp(a) particle size and heterogeneity as a function of density did not reveal any anomalies characteristic of homozygous FH. However, comparison of the hydrated density of Lp(a) particles as a function of apo(a) isoform content revealed a clear influence of isoform on this parameter; thus, in a B/S2 heterozygous patient, the density distribution of Lp(a) fractions containing isoform B alone, B and S2, and S2 alone, demonstrated that the apparent molecular weight of apo(a) plays a determining role in controlling the hydrated density and size of the resulting Lp(a) particle. Indeed, patients expressing the high molecular weight, S2 isoform uniformly displayed a dense form of Lp(a) (hydrated density approximately 1.055 g/ml). In subjects presenting two apo(a) isoforms, each isoform resided on distinct lipoprotein particles; in such cases, the plasma levels of the denser isoform predominated, suggesting differences in rates of formation, or rates of tissular catabolism, or in the plasma stability of the particles, or a combination of these mechanisms. Considered together, our data may be interpreted to suggest that the elevated circulating levels of Lp(a) in homozygous FH patients may reflect either an increased biosynthesis, or diminished catabolism via the cellular LDL receptor pathway, or a combination of both.     

Coexisting dysbetalipoproteinemia and familial hypercholesterolemia. Clinical and laboratory observations

Type III dysbetalipoproteinemia and familial hypercholesterolemia (FH) are two metabolic disorders giving rise to severe disturbances of lipid homeostasis and premature atherosclerosis. Both metabolic abnormalities have a genetic basis and co-occurrence in the same patient has seldom been described. Because of the unique structure of the French Canadian population, there was an opportunity to observe patients with both dysbetalipoproteinemia (E2/2 homozygotes) and FH (N=14) and to compare their clinical data with that of patients with type III (N=75), patients with FH (N0.7 and the presence of beta-VLDL on electrophoresis. Presence of a low density lipoprotein receptor, LDL-R, mutation should be suspected in a type III patient with a LDL-C level above 3.0 mmol/l and a family history of premature CAD. In the group of patients studied, the coexistence of dysbetalipoproteinemia and heterozygous FH does not appear to increase the prevalence of cardiovascular complications above that observed among control type III or control E3/3-FH patients. Thus, the presence of two epsilon2 alleles in these patients affects the expression of the abnormal LDL-R allele and the resulting phenotype substantiates the non additive effects of alleles at these two loci (epistasis).     

Lipoprotein(a) in subjects with familial defective apolipoprotein B100.

The plasma lipoprotein(a) (Lp(a)) concentration and apolipoprotein(a) (apo(a)) phenotype were determined in the members of two families affected with familial defective apo B100 (FDB), resulting from the Arg3500----Gln mutation in apo B that disrupts binding to LDL receptors. Eleven different phenotypic species of apo A were identified, five of which were present in both families. Although there was a general increase in Lp(a) concentration as the size of the predominant apo(a) component decreased, there was considerable variability and in three clear instances the concentration of an inherited phenotypic species was atypically low. In five cases where a direct comparison could be made, the plasma Lp(a) concentration was significantly higher in heterozygous FDB subjects than in their non-FDB siblings or close relatives with the same phenotype. However, in vitro competition studies using purified Lp(a) that had been reduced with dithiothreitol to remove the apo(a) component, indicated that the Lp(a) from FDB heterozygotes contained a smaller proportion of defective particles than their LDL. Lp(a) particles containing normal and binding-defective apo B were present at approximately the same concentration, suggesting that the increase in Lp(a) concentration observed in FDB subjects could not be explained by the inability of the particles containing the defective apo B100 to be cleared through LDL-receptor mediated processes.     

Fish intake, independent of apo(a) size, accounts for lower plasma lipoprotein(a) levels in Bantu fishermen of Tanzania: The Lugalawa Study.

Plasma lipoprotein(a) [Lp(a)] levels are largely genetically determined by sequences linked to the gene encoding apolipoprotein(a) [apo(a)], the distinct protein component of Lp(a). Apo(a) is highly polymorphic in length due to variation in the numbers of a sequence encoding the apo(a) kringle 4 domain, and plasma levels of Lp(a) are inversely correlated with apo(a) size. In 2 racially homogeneous Bantu populations from Tanzania differing in their dietary habits, we found that median plasma levels of Lp(a) were 48% lower in those living on a fish diet than in those living on a vegetarian diet. Considering the relationship between apo(a) size and Lp(a) plasma concentration, we have extensively evaluated apo(a) isoform distribution in the 2 populations to determine the impact of apo(a) size in the determination of Lp(a) values. The majority of individuals (82% of the fishermen and 80% of the vegetarians) had 2 expressed apo(a) alleles. Additionally, the fishermen had a high frequency of large apo(a) isoforms, whereas a higher frequency of small isoforms was found in the vegetarians. When subjects from the 2 groups were matched for apo(a) phenotype, the median Lp(a) value was 40% lower in Bantus on the fish diet than in those on the vegetarian diet. A significant inverse relationship was also found between plasma n-3 polyunsaturated fatty acids and Lp(a) levels (r=-0.24, P=0.01). The results of this study are consistent with the concept that a diet rich in n-3 polyunsaturated fatty acids, and not genetic differences, is responsible for the lower plasma levels of Lp(a) in the fish-eating Bantus and strongly suggest that a sustained fish-based diet is able to lower plasma levels of Lp(a).     

Catabolism of lipoprotein(a) in familial hypercholesterolaemic subjects.

The in vivo turnover of autologous lipoprotein(a) (Lp(a)) was studied in four heterozygous familial hypercholesterolaemic (FH) subjects and four subjects who were hyperlipidaemic but not FH. Each of the FH subjects exhibited a much lower fractional catabolic rate (FCR) for LDL than each of the non-FH subjects. Lp(a) was purified by sequential density gradient centrifugations and was radio-iodinated. The labelled Lp(a) ran as a single band on electrophoresis in gradient polyacrylamide gels. Less than 5% of the label was in lipid, with about 40% of the remainder on apolipoprotein B (apo B) and 60% on apo(a). Labelled and unlabelled Lp(a) competed equally poorly with LDL for binding to LDL receptors on cultured fibroblasts. The FCR of Lp(a), calculated from the decay of the specific radioactivity of the Lp(a) isolated from the daily blood samples, was the same in FH subjects as in non-FH subjects. There was no consistent relationship between Lp(a) FCR and the plasma Lp(a) concentration or between FCR and the Lp(a) phenotype, at least within this sample of subjects. There was a strong association between Lp(a) concentration and production rate, with values for non-FH and FH subjects falling on the same line. The rate of decline of radioactivity in whole plasma was consistently slower than the fall in specific radioactivity of the isolated Lp(a). This difference was more marked in FH subjects than in non-FH subjects and resulted from the accumulation of radioactivity derived from the injected Lp(a) at a lower density than Lp(a), in the fractions containing LDL. The amount of radioactivity in this fraction increased for the first few days after injection and then fell, the fall being more rapid in non-FH than in FH subjects. These results provide no evidence for the involvement of LDL receptors in the catabolism of Lp(a) itself but suggest that they could be responsible for some of the clearance of the lipid and apo B components after removal of apo(a) in the circulation.     

Plasma lipoprotein(a) concentration in familial hypercholesterolemic patients without coronary artery disease.

Familial Hypercholesterolemia (FH) is a condition characterized by markedly elevated blood cholesterol, low-density lipoproteins (LDL), and apolipoprotein B-100 (apo B). The molecular basis of this monogenic disease is the defective functioning of the cellular receptor for LDL that recognizes apo B. Lipoprotein(a) [Lp(a)] is a circulating lipoprotein that is structurally related to LDL, as it also contains apo B. To assess the impact of the LDL receptor deficiency on the plasma Lp(a) concentration, we measured Lp(a) in 28 FH patients and in 31 unaffected relatives. Because elevation of Lp(a) concentration in plasma of patients with coronary artery disease (CAD) appears to occur independently from plasma cholesterol levels, to avoid potentially confounding problems, members of the families chosen had no history for the disease. Whereas apo B clearly showed a bimodality of distribution by being significantly higher in the FH patients (166 +/- 38 mg/dL) than in the unaffected relatives (92 +/- 18 mg/dL), Lp(a) concentration did not differ in the two groups of patients (30 +/- 24 mg/dL in the FH patients v 31 +/- 23 in the normolipidemic relatives). Similar results were obtained when only siblings were further considered. We conclude that although Lp(a) is closely related to LDL structurally, its level in plasma is not significantly affected by the LDL receptor activity.     

家族性高胆固醇血症家系低密度脂蛋白受体活性及其基因突变分析

目的:对1例临床诊断为家族性高胆固醇血症(FH)纯合子患者家系进行低密度脂蛋白受体(LDL-R)活性研究及其基因突变分析,旨在探讨其分子病理机制。方法:对先证者及其父母进行血脂、颈动脉超声等检查;采用流式细胞仪检测先证者及其父母外周血淋巴细胞LDL-R表达量和功能;以先证者基因组DNA为模板,扩增载脂蛋白B100(ApoB100)基因3500区域片断,PCR产物进行核苷酸序列分析,排除由该突变导致家族性ApoB100缺陷症;用降落式PCR方法,在同一程序中分别扩增LDL-R基因的启动子和全部18个外显子片段,扩增产物进行核苷酸序列分析;发现突变后验证其父母是否存在相同基因突变。结果:先证者血清TC和LDL水平明显升高、颈动脉内中膜明显增厚;LDL-R的表达量和结合功能显著下降(分别为正常人的13.6%和21.1%);ApoB100基因3500区域未见突变,LDL-R基因第1864位碱基T取代了G发生纯合错义突变,导致第601位氨基酸天冬氨酸变成脯氨酸(D601Y)。其父母LDL-R基因发现了相同的杂合突变,经检索该突变在我国未见报道。结论:证实家系先证者存在LDL-R基因突变,分别来源于父系和母系的遗传,该突变可能是家系发病的分子基础;D601Y也可能是我国FH患者LDL-R基因一种新的突变类型。     

A form of familial hypobetalipoproteinaemia not due to a mutation in the apolipoprotein B gene

Familial hypobetalipoproteinaemia (FHBL) is a dominant disorder of lipoprotein metabolism characterized by levels of apolipoprotein B-carrying lipoproteins (VLDL, IDL and LDL) which are 50% of the normal levels in the heterozygotes and almost absent in the homozygotes. Several reports have recently shown that the underlying defect in FHBL involves different mutations in the apo B gene which lead to reduced levels of apo B mRNA or to the production of truncated forms of apo B having either a lower synthetic rate or a higher catabolic rate than normal apo B. We here present a three-generation family with several FHBL members in which the linkage analysis shows absence of co-segregation between apo B gene alleles and the hypocholesterolaemic phenotype. We conclude that a dominantly transmitted mutation in a gene other than that for apo B is responsible for the low plasma cholesterol levels.     

The apolipoprotein B R3500Q gene mutation in Spanish subjects with a clinical diagnosis of familial hypercholesterolemia

Familial hypercholesterolemia (FH) and familial defective apolipoprotein B-100 (FDB) are autosomal codominant diseases characterized by elevated LDL cholesterol levels and premature coronary artery disease. Mutations of the LDL-receptor and apolipoprotein B genes, which affect the binding domains of their protein products, are the causal defects. Securing the diagnosis of these conditions by molecular assays is important because it mandates early intervention for coronary risk reduction. DNA screening for apolipoprotein B R3500Q gene mutation was performed in 913 unrelated Spanish individuals with a clinical diagnosis of FH using a modified polymerase chain reaction protocol and restriction enzyme genotyping. Thirteen FDB heterozygotes were identified (frequency of 1.4% in subjects with a clinical diagnosis of FH). The prevalence of hypercholesterolemic subjects with FDB in the general Spanish population was estimated to be as low as 2.8 x 10(-5) (95% CI, -3.1 x 10(-4) to 3.7 x 10(-4)). The ancestors of 11 out of 13 FDB carriers were from Galicia, a region of Celtic ancestry in Northwestern Spain. As the series included 100 unrelated subjects of Galician ancestry, FDB appears to be an important genetic cause of hypercholesterolemia in this region. All the R3500Q mutations were found on the same allele, assigned to haplotype XbaI-/MspI+/EcoRI-/3HVR48, suggesting that the mutant alleles are identical by descent in people from Spain, as observed in other Caucasian populations. In conclusion, the R3500Q mutation of the apolipoprotein B gene, a common cause of FH in central Europe, is infrequent in the general Spanish population, but it is common in Galicia.