Maternal apo E genotype is a modifier of the Smith-Lemli-Opitz syndrome.

BACKGROUND: Smith-Lemli-Opitz syndrome (MIM 270400) is an autosomal recessive malformation and mental retardation syndrome that ranges in clinical severity from minimal dysmorphism and mild mental retardation to severe congenital anomalies and intrauterine death. Smith-Lemli-Opitz syndrome is caused by mutations in the Delta7 sterol-reductase gene (DHCR7; EC 1.3.1.21), which impair endogenous cholesterol biosynthesis and make the growing embryo dependent on exogenous (maternal) sources of cholesterol. We have investigated whether apolipoprotein E, a major component of the cholesterol transport system in human beings, is a modifier of the clinical severity of Smith-Lemli-Opitz syndrome. METHOD: Common apo E, DHCR7, and LDLR genotypes were determined in 137 biochemically characterised patients with Smith-Lemli-Opitz syndrome and 59 of their parents. RESULTS: There was a significant correlation between patients' clinical severity scores and maternal apo E genotypes (p = 0.028) but not between severity scores and patients' or paternal apo E genotypes. In line with their effects on serum cholesterol levels, the maternal apo epsilon2 genotypes were associated with a severe Smith-Lemli-Opitz syndrome phenotype, whereas apo E genotypes without the epsilon2 allele were associated with a milder phenotype. The correlation of maternal apo E genotype with disease severity persisted after stratification for DHCR7 genotype. There was no association of Smith-Lemli-Opitz syndrome severity with LDLR gene variation. CONCLUSIONS: These results suggest that the efficiency of cholesterol transport from the mother to the embryo is affected by the maternal apo E genotype and extend the role of apo E and its disease associations to modulation of embryonic development and malformations.

Association of NQO1 polymorphism with spontaneous breast cancer in two independent populations.

Eight different single-nucleotide polymorphisms (SNPs) in six different genes were investigated for possible association with breast cancer. We used a case-control study design in two Caucasian populations, one from Tyrol, Austria, and the other from Prague, Czech Republic. Two SNPs showed an association with breast cancer: R72P inTP53 and P187S in NQO1. Six SNPs, Q356R and P871L in BRCA1, N372H in BRCA2, C112R (E4) and R158C (E2) in ApoE and C825T in GNB3, did not show any sign of association. The P187S polymorphism in NQO1 was associated with breast cancer in both populations from Tyrol and Prague with a higher risk for carriers of the 187S allele. Combining the results of the two populations, we observed a highly significant difference (P=0.0004) of genotype and allele frequencies (odds ratio (OR)=1.46; 95% confidence interval (CI) 1.16-1.85; P=0.001) and of the homozygote ratio (OR=3.8; 95% CI 1.73-8.34; P=0.0001). Combining the two 'candidate' SNPs (P187S and R72P) revealed an increased risk for breast cancer of double heterozygotes (P187S/R72P) of the NQO1 and TP53 genes (OR=1.88; 95% CI 1.13-3.15; P=0.011), suggesting a possible interaction of these two loci.

Gabon black population data on the ten short tandem repeat loci D3S1358, VWA, D16S539, D2S1338, D8S1179, D21S11, D18S51, D19S433, TH01 and FGA.

Allele frequencies for ten short tandem repeat (STR) loci D3S1358, VWA, D16S539, D2S1338, D8S1179, D21S11, D18S51, D19S433, TH01 and FGA were determined in a Black African sample population from Gabon. All loci were highly polymorphic and except for TH01, D21S11 and D16S539, all met Hardy-Weinberg expectations. There was little evidence of association of alleles between the loci in this database. The combined power of exclusion for the ten STR loci was 0.999981. While significant differences between the Gabon population and the Austrian Caucasian population were found at all loci, significant differences were found between the Gabon population and Zimbabweans only for D3S1358 and between the Gabon population and African Americans only for TH01 and D8S1179.

Single nucleotide polymorphisms in exons of the apo(a) kringles IV types 6 to 10 domain affect Lp(a) plasma concentrations and have different patterns in Africans and Caucasians.

Lipoprotein(a) [Lp(a)] is a complex of apolipoprotein(a) [apo(a)] and low-density lipoprotein which is associated with atherothrombotic disease. Lp(a) plasma levels are controlled to a large extent by the apo(a) gene locus. Known polymorphisms in the apo(a) gene, including the kringle (K) IV-2 variable number of tandem repeats, explain only part of the large interindividual variability and do not explain the differences in Lp(a) concentrations between major human ethnic groups. Here we performed screening for single nucleotide polymorphisms (SNPs) in exons and flanking intron sequences of the apo(a) K IV types 6, 8, 9 and 10 which represent 1.3 kb of coding sequence in two African (Khoi San, Black South Africans) and one Caucasian (Tyroleans) populations and investigated whether they affect Lp(a) levels. Together, 768 alleles were analyzed. We identified 14 SNPs, including 11 non-synonymous SNPs (eight of which involved conserved residues), one splice site and two synonymous base changes. No sequence variants common to Africans and Caucasians were found. Several of the newly identified SNPs showed significant effects on Lp(a) plasma concentrations. The substitutions S37F in K IV-6 and G17R in K IV-8 were associated with Lp(a) levels significantly below average in Africans. In contrast, the R18W substitution in K IV-9, which occurred with a frequency of 8% in Khoi San, resulted in a significantly increased Lp(a) concentration. Together, our data suggest that several SNPs in the coding sequence of apo(a) affect Lp(a) levels. This indicates that many SNPs may have subtle effects on the gene product.

Lipoprotein(a) determination and risk of cardiovascular disease in South African patients with familial hypercholesterolaemia.

OBJECTIVE: A raised plasma level of lipoprotein(a) (Lp(a)) is an established genetic risk factor for coronary heart disease (CHD), particularly in patients with concomitant elevation of low-density lipoprotein (LDL) cholesterol. The current study focused on the comparison of two commercially available Lp(a) assay kits to determine whether differences observed in measured Lp(a) levels could be deemed negligible in CHD risk assessment in familial hypercholesterolaemic (FH) patients. DESIGN: To compare results obtained on duplicate plasma samples using two commercially available Lp(a) measuring kits, the immunoradiometric assay (RIA) and the enzyme-linked immunoabsorbent assay (ELISA). SETTING: Division of Human Genetics, Department of Obstetrics and Gynaecology, University of Stellenbosch, Tygerberg, South Africa and the Institute for Medical Biology and Human Genetics, University of Innsbruck, Austria. SUBJECTS: Plasma samples were obtained from 146 family members of 65 molecularly characterised South African FH families for comparative analysis. RESULTS: Using the RIA method, 34 samples (23%) considered to be in the normal range by the ELISA technique, were placed in the high-risk group (> 30 mg/dl). Only one sample, considered to have a normal Lp(a) level with the RIA method, was categorised by the ELISA technique as high risk. CONCLUSION: Our data demonstrate that measurements of Lp(a) using the RIA method (the only assay available in South Africa at the time of this study) differ significantly from those obtained by the reference ELISA technique, suggesting that misclassification could lead to inaccurate CHD risk assessment. This is an important consideration in Afrikaner FH families, where plasma levels of Lp(a) have been shown to be elevated significantly in FH patients compared with non-FH individuals.

Two novel mutations in the lipoprotein lipase gene in a family with marked hypertriglyceridemia in heterozygous carriers. Potential interaction with the polymorphic marker D1S104 on chromosome 1q21-q23.

Two novel mutations in the lipoprotein lipase (LPL) gene are described in an Austrian family: a splice site mutation in intron 1 (3 bp deletion of nucleotides -2 to -4) which results in skipping of exon 2, and a missense mutation in exon 5 which causes an asparagine for histidine substitution in codon 183 and complete loss of enzyme activity. A 5-year-old boy who exhibited all the clinical features of primary hyperchylomicronemia was a compound heterozygote for these two mutations. Nine other family members were investigated: seven were heterozygotes for the splice site mutation, one was a heterozygote for the missense mutation, and one had two wild-type alleles of the LPL gene. LPL activity in the post-heparin plasma of the heterozygotes was reduced to 49;-79% of the mean observed in normal individuals. Two of the heterozygotes had extremely high plasma triglyceride levels; in three of the other heterozygotes the plasma triglycerides were also elevated. As plasma triglycerides in carriers of one defective LPL allele can be normal or elevated, the heterozygotes of this family have been studied for a possible additional cause of the expression of hypertriglyceridemia in these subjects. Body mass index, insulin resistance, mutations in other candidate genes (Asn291Ser and Asp9Asn in the LPL gene, apoE isoforms, polymorphisms in the apoA-II gene and in the apoAI-CIII-AIV gene cluster, and in the IRS-1 gene) could be ruled out as possible factors contributing to the expression of hypertriglyceridemia in this family. A linkage analysis using the allelic marker D1S104 on chromosome 1q21;-q23 suggested that a gene in this region could play a role in the expression of hypertriglyceridemia in the heterozygous carriers of this family, but the evidence was not sufficiently strong to prove this assumption. Nevertheless, this polymorphic marker seems to be a good candidate for further studies.

Mutational spectrum in the Delta7-sterol reductase gene and genotype-phenotype correlation in 84 patients with Smith-Lemli-Opitz syndrome.

Smith-Lemli-Opitz syndrome (SLOS), an autosomal recessive malformation syndrome, ranges in clinical severity from mild dysmorphism and moderate mental retardation to severe congenital malformation and intrauterine lethality. Mutations in the gene for Delta7-sterol reductase (DHCR7), which catalyzes the final step in cholesterol biosynthesis in the endoplasmic reticulum (ER), cause SLOS. We have determined, in 84 patients with clinically and biochemically characterized SLOS (detection rate 96%), the mutational spectrum in the DHCR7 gene. Forty different SLOS mutations, some frequent, were identified. On the basis of mutation type and expression studies in the HEK293-derived cell line tsA-201, we grouped mutations into four classes: nonsense and splice-site mutations resulting in putative null alleles, missense mutations in the transmembrane domains (TM), mutations in the 4th cytoplasmic loop (4L), and mutations in the C-terminal ER domain (CT). All but one of the tested missense mutations reduced protein stability. Concentrations of the cholesterol precursor 7-dehydrocholesterol and clinical severity scores correlated with mutation classes. The mildest clinical phenotypes were associated with TM and CT mutations, and the most severe types were associated with 0 and 4L mutations. Most homozygotes for null alleles had severe SLOS; one patient had a moderate phenotype. Homozygosity for 0 mutations in DHCR7 appears compatible with life, suggesting that cholesterol may be synthesized in the absence of this enzyme or that exogenous sources of cholesterol can be used.

Lipoprotein(a) in homozygous familial hypercholesterolemia.

Lipoprotein(a) [Lp(a)] is a quantitative genetic trait that in the general population is largely controlled by 1 major locus-the locus for the apolipoprotein(a) [apo(a)] gene. Sibpair studies in families including familial defective apolipoprotein B or familial hypercholesterolemia (FH) heterozygotes have demonstrated that, in addition, mutations in apolipoprotein B and in the LDL receptor (LDL-R) gene may affect Lp(a) plasma concentrations, but this issue is controversial. Here, we have further investigated the influence of mutations in the LDL-R gene on Lp(a) levels by inclusion of FH homozygotes. Sixty-nine members of 22 families with FH were analyzed for mutations in the LDL-R as well as for apo(a) genotypes, apo(a) isoforms, and Lp(a) plasma levels. Twenty-six individuals were found to be homozygous for FH, and 43 were heterozygous for FH. As in our previous analysis, FH heterozygotes had significantly higher Lp(a) than did non-FH individuals from the same population. FH homozygotes with 2 nonfunctional LDL-R alleles had almost 2-fold higher Lp(a) levels than did FH heterozygotes. This increase was not explained by differences in apo(a) allele frequencies. Phenotyping of apo(a) and quantitative analysis of isoforms in family members allowed the assignment of Lp(a) levels to both isoforms in apo(a) heterozygous individuals. Thus, Lp(a) levels associated with apo(a) alleles that were identical by descent could be compared. In the resulting 40 allele pairs, significantly higher Lp(a) levels were detected in association with apo(a) alleles from individuals with 2 defective LDL-R alleles compared with those with only 1 defective allele. This difference of Lp(a) levels between allele pairs was present across the whole size range of apo(a) alleles. Hence, mutations in the LDL-R demonstrate a clear gene-dosage effect on Lp(a) plasma concentrations.

Genetic control of lipoprotein(a) concentrations is different in Africans and Caucasians.

Lipoprotein(a) (Lp(a)) represents a quantitative trait in human plasma associated with atherothrombotic disease. Large variation in the distribution of Lp(a) concentrations exists across populations which is at present unexplained. Sib-pair linkage analysis has suggested that the apo(a) gene on chromosome 6q27 is the major determinant of Lp(a) levels in Caucasians. We have here dissected the genetic architecture of the Lp(a) trait in Africans (Khoi San, South African Blacks) and Caucasians (Austrians) by family/sib-pair analysis. Heritability estimates ranged from h2 = 51% in Blacks, h2 = 61% in Khoi San, to h2 = 71% in Caucasians. Analysis by a variance components model also demonstrated that the proportion of the total phenotypic variance explained by genetic factors is smaller in Africans (65%) than in Caucasians (74%). Importantly the sib-pair analysis clearly identified the apo(a) gene as the major locus in Caucasians which explained the total genetic variance. In the African samples the apo(a) gene accounted for only half the genetic variance. Together with previous results from population studies our data indicate that genetic control of Lp(a) levels seems to be distinctly different between Africans and Caucasians. In the former genetic factors distinct from the apo(a) locus and also non-genetic factors may play a major role.

Concentrations of the atherogenic Lp(a) are elevated in FH.

Lipoprotein(a) (Lp(a)) is a complex in human plasma assembled from low-density lipoprotein (LDL) and apolipoprotein(a) (apo(a)). High plasma concentrations of Lp(a) are a risk factor for coronary heart disease (CHD) in particular in patients with concomitant elevation of LDL. We have analysed for elevated Lp(a) levels in patients with familial hypercholesterolaemia (FH), a condition caused by mutations in the LDL receptor (LDLR) gene and characterised by high LDL, xanthomatosis and premature CHD. To avoid possible confusion by the apo(a) gene which is the major quantitative trait locus controlling Lp(a) in the population at large, we used a sib pair approach based on genotype information for both the LDLR and the apo(a) gene. We analysed 367 family members of 30 South African and 30 French Canadian index patients with FH for LDLR mutations and for apo(a) genotype. Three lines of evidence showed a significant effect of FH on Lp(a) levels: (1) Lp(a) values were significantly higher in FH individuals compared to non-FH relatives (p < 0.001), although the distribution of apo(a) alleles was not different in the two groups; (2) comparison of Lp(a) concentrations in 28 sib pairs, identical by descent (i.b.d.) at the apo(a) locus but non-identical for LDLR status, extracted from this large sample demonstrated significantly elevated Lp(a) concentrations in sibs with FH (p < 0.001); (3) single i.b.d. apo(a) alleles were associated with significantly higher Lp(a) concentrations (p < 0.0001) in FH than non-FH family members. Variability in associated Lp(a) levels also depended on FH status and was highest when i.b.d. alleles were present in FH subjects and lowest when present in non-FH individuals. The study demonstrates that sib pair analysis makes it possible to detect the effect of a minor gene in the presence of the effect of a major gene. Given the interactive effect of elevated LDL and high Lp(a) on CHD risk our data suggest that elevated Lp(a) may add to the CHD risk in FH subjects.

Intracellular metabolism of human apolipoprotein(a) in stably transfected Hep G2 cells.

Lipoprotein(a) [Lp(a)] consists of LDL and the glycoprotein apolipoprotein(a) [apo(a)], which are covalently linked via a single disulfide bridge. The formation of Lp(a) occurs extracellularly, but an intracellular assembly in human liver cells has also been claimed. The human apo(a) gene locus is highly polymorphic due to a variable number of tandemly arranged kringle IV repeats. The size of apo(a) isoforms correlates inversely with Lp(a) plasma concentrations, which is believed to reflect different synthesis rates. To examine this association at the cellular level, we analyzed the subcellular localization and fate of apo(a) in stably transfected HepG2 cells. Our results demonstrate that apo(a) is synthesized as a precursor with a lower molecular mass which is processed into the mature, secreted form. The retention times of the precursor in the ER positively correlated with the sizes of apo(a) isoforms. The mature form was observed intracellularly at low levels and only in the Golgi apparatus. No apo(a) was found to be associated with the plasma membrane. Under temperature-blocking conditions, we did not detect any apo(a)/apoB-100 complexes within cells. This finding was confirmed in HepG2 cells transiently expressing KDEL-tagged apo(a). The precursor and the mature forms of apo(a) were found in the ER and Golgi fractions, respectively, also in human liver tissue. From our data, we conclude that in HepG2 cells the apo(a) precursor, dependent on the apo(a) isoform, is retained in the ER for a prolonged period of time, possibly due to an extensive maturation process of this large protein. The assembly of Lp(a) takes place exclusively extracellularly following the separate secretion of apo(a) and apoB.

The number of kringle IV repeats 3-10 is invariable in the human apo(a) gene.

The human apolipoprotein(a) (apo(a)) gene is a member of a family of related genes including plasminogen, apo(a)rg-B and apo(a)rg-C, which are clustered on chromosome 6q 2,7. Apo(a) contains ten different types of plasminogen-like kringle IV repeats (K-IV 1-10) one of which (K-IV 2) varies in number resulting in a remarkable size polymorphism of the protein. Sequence analysis of human apo(a) alleles and indirect evidence have suggested that K-IV 1 and K-IV 3-10 are each present once in individual alleles and that the 3' apo(a) region encompassing kringles IV 3-10, kringle V and the protease domain is invariable. To directly test this, we have constructed a restriction map of the apo(a) gene region from genomic DNA and from a yeast artificial chromosome (YAC) (K-IV 13) which contains the entire apo(a) gene. The presence of a 63 kb ClaI fragment encompassing kringles IV 3-10, kringle V and the protease domain and a 46 kb SwaI fragment, spanning kringles IV 5-10, kringle V and the protease domain was demonstrated by PFGE/Southern blotting in 30 unrelated subjects, who represented a range of apo(a) size alleles containing from 11 to 49 kringles. Our analysis demonstrates that the number of kringles IV 3-10 is invariable in the human apo(a) gene, suggesting that the 3'domain of Apo(a) is functionally important.

Significant impact of the +93 C/T polymorphism in the apolipoprotein(a) gene on Lp(a) concentrations in Africans but not in Caucasians: confounding effect of linkage disequilibrium.

Lipoprotein(a) [Lp(a)] is a quantitative genetic trait in human plasma associated with atherothrombotic disease. The major determinant of Lp(a) concentration is the apolipoprotein(a) [apo(a)] gene locus. Variation in the number of kringle IV repeats (K-IV VNTR) in apo(a) has a direct effect on Lp(a) concentrations but explains only a fraction of the large intra- and inter-population variance in Lp(a) levels. Effects on Lp(a) of other intragenic polymorphisms including a pentanucleotide repeat (PNRP) in the promoter likely reflect allelic associations with as yet unidentified sequence variation in the apo(a) gene. We have studied a candidate C-->T transition in two European and two African populations. This polymorphism in the 5' region of the apo(a) gene creates an ATG start codon thereby reducing apo(a) translation in vitro by 60%. All samples were also analyzed for the K-IV VNTR and the PNRP to stratify for their effects and to consider allelic associations. Consistent with the in vitro effect the C-->T transition was associated with a significant reduction in Lp(a) levels in both African populations ( P < 0.0056). In Caucasians, however, the effect was not significant. This was explained by linkage disequilibrium of the +93 T with apo(a) alleles of intermediate length (K-24-K-34) and with nine PNRs. In Europeans these alleles are associated with low Lp(a) which makes any potential effect of the +93 T undetectable in the total sample. From our results we conclude (i) that the +93 C/T polymorphism is the second known intragenic apo(a) polymorphism which affects Lp(a) levels directly in vivo ; (ii) that allelic associations may mask the effect of a mutation; and (iii) that heterogeneity of an effect of a mutation across populations does not disprove causality.

Lipoprotein[a] is not present in the plasma of patients with some peroxisomal disorders.

Peroxisomal disorders arise either from defects in the biogenesis of peroxisomes or from the defective synthesis of one or more peroxisomal enzymes. These defects result in metabolic disturbances in peroxisomal beta-oxidation of various fatty acids and derivatives and/or in the biosynthesis of ether lipids. In the current study, lipoprotein levels were determined in plasma samples from patients diagnosed with one of four different peroxisomal disorders. While low density lipoprotein (LDL) levels were found to be within the normal range, lipoprotein[a] (Lp[a]) could not be detected by enzyme-linked immunosorbent assay (ELISA) in plasma from patients with cerebro-hepato-renal (Zellweger) syndrome (ZS) and rhizomelic chondrodysplasia punctata (RCDP). Conversely, Lp[a] was clearly present in control plasma obtained from healthy newborns and from patients affected with one of two other peroxisomal disorders, X-linked adrenoleukodystrophy (X-ALD) and Refsum disease (RD) as determined by ELISA. The lack of Lp[a] in plasma of patients with ZS may result from defective secretion of apolipoprotein[a] (apo[a]) (the distinguishing protein component of Lp[a]), as apo[a] mRNA transcripts were clearly present in ZS livers as assessed by PCR, and intracellular apo[a] protein was detected in total liver homogenates from ZS patients as determined by Western blot analysis. Furthermore, LDL present in the plasma of ZS patients was able to associate with recombinant apo[a] in an in vitro Lp[a] assembly assay.

Sib-pair analysis detects elevated Lp(a) levels and large variation of Lp(a) concentration in subjects with familial defective ApoB.

Whether or not Lp(a) plasma levels are affected by the apoB R3500Q mutation, which causes Familial Defective apoB (FDB), is still a matter of debate. We have analyzed 300 family members of 13 unrelated Dutch index patients for the apoB mutation and the apolipoprotein(a) [apo(a)] genotype. Total cholesterol, LDL-cholesterol, and lipoprotein(a) [Lp(a)] concentrations were determined in 85 FDB heterozygotes and 106 non-FDB relatives. Mean LDL levels were significantly elevated in FDB subjects compared to non-FDB relatives (P < 0.001). Median Lp(a) levels were not different between FDB subjects and their non-FDB relatives. In contrast, sib-pair analysis demonstrated a significant effect of the FDB status on Lp(a) levels. In sib pairs identical by descent for apo(a) alleles but discordant for the FDB mutation (n = 11) each sib with FDB had a higher Lp(a) level than the corresponding non-FDB sib. Further, all possible sib pairs (n = 105) were grouped into three categories according to the absence/presence of the apoB R3500Q mutation in one or both subjects of a sib pair. The variability of differences in Lp(a) levels within the sib pairs increased with the number (0, 1, and 2) of FDB subjects present in the sib pair. This suggests that the FDB status increases Lp(a) level and variability, and that apoB may be a variability gene for Lp(a) levels in plasma.

The relative electrophoretic mobility of apo(a) isoforms depends on the gel system: proposal of a nomenclature for apo(a) phenotypes.

Genetic apo(a) isoforms were originally defined according to their relative mobility in SDS-PAGE compared to apoB-100 and were designated as F, B or S1-S4 isotypes. This widely accepted nomenclature does not accommodate the broad spectrum of apo(a) isoforms (> 30) detected by high resolution SDS-agarose gel electrophoresis. Moreover we here show that the relative mobilities of apo(a) isoforms depend on the SDS-gel system used. Comparison of the SDS-PAGE system originally used for phenotyping with SDS-agarose gel electrophoresis and two commercial SDS-PAGE systems (PhastGel, Pharmacia, Sweden and NOVEX, USA) demonstrated marked differences in resolving power and resulted in very different Rf values for identical isoforms. Hence phenotyping results from laboratories using different systems are not comparable. We therefore propose a nomenclature of apo(a) isoforms which reports the number of kringle IV repeats in the apo(a) allele (e.g. apo(a) K-IV20 would designate an isoform with 20 K-IV repeats). This is achieved by using standards in which the number of kringle IV repeats has been determined by pulsed field gel electrophoresis of genomic DNA. The proposed nomenclature (i) accounts for the increased resolution of apo(a) phenotyping methods: (ii) is flexible to the introduction of smaller or larger isoforms; (iii) allows to report data from systems with lower resolution as 'binned' isoform categories; (iv) allows the comparison of phenotyping results between different investigators; and (v) can be applied on DNA as well as on protein based apo(a) phenotyping.

Apolipoprotein(a) kringle IV repeat number predicts risk for coronary heart disease.

A high plasma concentration of lipoprotein(a) [Lp(a)] has been suggested as a risk factor for coronary heart disease (CHD), but some recent prospective studies have questioned the significance of Lp(a). Lp(a) concentrations are determined to a large extent by the hypervariable apo(a) gene locus on chromosome 6q2.7, which contains a variable number of identical tandemly arranged transcribed kringle IV type 2 repeats. The number of these repeats correlates inversely with plasma Lp(a) concentration. We analyzed whether apo(a) gene variation (kringle IV repeat number) is associated with CHD. Apo(a) genotypes were determined by pulsed-field gel electrophoresis/genomic blotting in CHD patients who had undergone angiography (n = 69) and control subjects matched for age, sex, and ethnicity (n = 69) and were related to Lp(a) concentration, apo(a) isoform in plasma, and disease status. Apo(a) alleles with a low kringle IV copy number ( < 22) and high Lp(a) concentration were significantly more frequent in the CHD group (P < .001), whereas large nonexpressed alleles were more frequent in control subjects. The odds ratio for CHD increased continuously with a decreasing number of kringle IV repeats and ranged from 0.3 in individuals with > 25 kringle IV repeats on both alleles to 4.6 in those with < 20 repeats on at least one allele. This provides direct genetic evidence that variation at the apo(a) gene locus, which determines Lp(a) levels, is also a determinant of CHD risk.

Lipoprotein(a) is increased in triglyceride-rich lipoproteins in men with coronary heart disease, but does not change acutely following oral fat ingestion.

Association of apo(a)/Lp(a) with triglyceride-rich lipoproteins (TGR-Lps) is determined by different factors that are poorly understood. Some previous studies suggested that apo(a) in TGR-Lps may affect the atherogenicity of the TGR particles. To study whether there are any peculiarities in postprandial (pp) Lp(a) metabolism, we have determined apo(a) phenotypes and Lp(a) concentrations in 46 subjects with coronary heart disease (CHD) and in six normolipidemic individuals at different time points (4, 6 and 8 h) following an oral fat tolerance test. While mean triglyceride concentration reached its maximum 6 h after a standardized fat meal, no change in total cholesterol and in mean Lp(a) plasma concentration was detected at any time point after the fat load. In 6 normolipidemic probands and in 8 patients with CHD, who were matched for apo(a) phenotype, lipoprotein levels, age and body weight, we followed the distribution of apo(a) in plasma density gradient fractions in the fasting and pp state. In the CHD patients a significant larger percentage of apo(a) reactivity was detected in TGR-Lps in the pre- as well as in the postprandial state, compared to control subjects. The fat intake did not induce a significant change of apo(a) reactivity in the TGR-Lp fractions in both groups. The apo(a) isoform-size and the Lp(a) plasma concentration in the fasting state had no influence on the individual variation of the Lp(a) concentration in pp TGR-Lp fractions. Our results provide evidence that TGR-Lp fractions of CHD patients are enriched in apo(a) reactivity compared to healthy controls, but do not support the hypothesis that Lp(a) acts atherogenically through a pp increase of its plasma concentration.

Frequency distributions of apolipoprotein(a) kringle IV repeat alleles and their effects on lipoprotein(a) levels in Caucasian, Asian, and African populations: the distribution of null alleles is non-random.

A size polymorphism (K IV VNTR) and largely unknown sequence variation in the apolipoprotein(a) [apo(a)] gene on chromosome 6q26-q27 together determine most of the extreme variation in apo(a) glycoprotein expression and lipoprotein(a) [Lp(a)] plasma concentration in Caucasians. We have determined Lp(a) plasma concentrations, the number of kringle IV (K IV) repeats in the apo(a) gene and the expression of the apo(a) glycoprotein in four ethnic groups (Khoi San, South African Blacks, Hong Kong Chinese and Caucasians from the Tyrol, total n = 788). The distributions of Lp(a) concentrations, the frequencies of expressed and non-expressed apo(a) K IV alleles, and the impact of the size polymorphism on Lp(a) concentrations were all heterogeneous across populations. In contrast, the effect of the K IV repeat alleles appeared homogeneous. Lp(a) concentrations were higher in Africans and Chinese than in Caucasians, but this was not explained by differences in K IV repeat allele frequencies among populations. Lp(a) concentrations were highest in Khoi San, suggesting that high Lp(a) is an old African trait. When expressed as Spearman rank correlations the impact of the size polymorphism was smallest in African Blacks (R = -0.386) and largest in the Chinese (R = -0.692). In all four populations, the distribution of non-expressed apo(a) alleles was non-random. Rather they were significantly associated with distinct size alleles and overall positively with high K IV repeat numbers. The negative correlation of K IV repeat length with Lp(a) concentration was non-linear in Khoi San and the average apo(a)-size-allele-associated Lp(a) concentrations were markedly different between all populations. We conclude that besides the apo(a) size variation, other factors affect Lp(a) concentrations to different degrees in the study populations. Most likely, this is sequence variation in apo(a) which is not the same in the different ethnic groups.