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(Arteriosclerosis, Thrombosis, and Vascular Biology. 2004;24:1935.)
© 2004 American Heart Association, Inc.

Atherosclerosis and Lipoproteins

Quantitative Trait Loci for Apolipoprotein B, Cholesterol, and Triglycerides in Familial Combined Hyperlipidemia Pedigrees

Rita M. Cantor; Tjerk de Bruin; Naoko Kono; Susan Napier; Atila van Nas; Hooman Allayee; Aldons J. Lusis

From the Departments of Human Genetics (R.M.C., N.K., S.N., A.v.N., H.A., A.J.L.) and Medicine (A.J.L.), David Geffen School of Medicine at UCLA, Los Angeles, Calif; and the Department of Medicine and Cardiovascular Research Institute (T.B.), Academic Hospital, Maastricht, the Netherlands.

Correspondence to Dr Rita M. Cantor, Department of Human Genetics, David Geffen School of Medicine at UCLA, 695 Charles E. Young Dr. South, Los Angeles, CA 90095-7088. E-mail rcantor{at}mednet.ucla.edu

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
Objective— Familial combined hyperlipidemia (FCHL) is a genetically complex lipid disorder that is diagnosed in families by combinations of increased cholesterol, triglycerides, and/or apolipoprotein B (apoB) levels in patients and their first-degree relatives. Identifying the predisposing genes promises to reveal the primary risk factors and susceptibility pathways and suggest methods of prevention and treatment. As with most genetically complex disorders, a clinical definition of disease may not be the most useful phenotype for finding the complement of predisposing genes, and the quantitative traits used to define the disorder can provide important information. This is a report of a quantitative trait loci (QTL) analysis of FCHL.

Methods and Results— A full genome scan of 377 multi-allelic markers genotyped at 10 centimorgan (cM) intervals was conducted in 150 sibling pairs from 22 nuclear families in FCHL pedigrees. These data were analyzed by 2 multipoint QTL linkage methods using the nonparametric and Haseman–Elston procedures of the Genehunter software. Using a criterion of P<0.001 by the nonparametric analysis, we found evidence of 2 apoB QTL at 1p21-31 (P<0.000009) and 17p11-q21 (P<0.000009), a total serum cholesterol QTL at 12p13 (P<0.0001), and a serum triglycerides QTL at 4p15-16 (P<0.0002). Using the criterion of P<0.03 for at least 2 traits at the same locus, additional evidence for cholesterol (P<0.01) and a triglycerides P<0.02) was observed at 17p11-21, as well as suggestive evidence for apoB (P<0.02) and triglycerides (P<0.01) at 4q34-35, and cholesterol (P<0.01) and triglycerides (P<0.02) and a binary FCHL trait (lod=1.5) at 16p12-13.

Conclusions— QTL analyses of the traits that define FCHL are effective for localizing disease-predisposing genes.

FCHL QTL were identified at 1p21-31 and 17p11-q21 for apolipoprotein B, 12p13 for total serum cholesterol, and 4p15-16 for serum triglycerides by nonparametric linkage analyses of a full genome scan of 150 sibpairs in 22 familial combined hyperlipidemia sibships. Multiple QTL were observed at 4q34-35, 16p12-13, and 17p11-q21.

Key Words: FCHL • QTL • apolipoprotein B • cholesterol • triglycerides

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Familial combined hyperlipidemia (FCHL) is a genetically complex lipid disorder that predisposes to coronary artery disease. Since its recognition in 1973,^1–3 it has been clinically defined by multiple lipid abnormalities that are exhibited by first-degree relatives within families. A prevalence of 1% among white populations makes it an important contributor to the burden of coronary artery disease.⁴ Finding the genes that predispose to FCHL promises to reveal its primary risk factors and susceptibility pathways, and to suggest possible methods of prevention and treatment. Increased levels of serum triglycerides, total cholesterol, and/or apolipoprotein B (apoB) in a patient indicate the possibility of FCHL. On the examination of family members, FCHL is diagnosed if at least 2 of the lipid abnormalities seen in the patient (usually increases in cholesterol and triglycerides) also segregate among the patient’s first-degree relatives. As with most genetically complex disorders, the binary classification of family members into affected and unaffected may not be the best phenotype for finding disease-predisposing genes, because such classifications do not follow a classical Mendelian pattern of inheritance.^5–7 These increased lipid levels are likely to result from the interaction of multiple genes and environmental factors, such as adiposity and the degree of exercise, and the individual quantitative lipid profiles may be closer to the genetic defects than the binary definition of FCHL. In addition, it is anticipated that the wide variance of quantitative traits will provide more statistical power to detect linked loci than the binary categorization of FCHL. We report, herein, the results of a full genome scan in FCHL families when the individual quantitative lipid traits used to diagnose FCHL have been the focus of the linkage analyses.

Searches for lipid disorder genes have been conducted using multiple genetic epidemiologic approaches, including full genome scans,^8–14 extensive candidate gene analyses,¹⁵ and analyses of the FCHL diagnosis in large pedigrees¹⁰ and in nuclear families.¹¹ Recently, very promising findings were generated by analyzing the FCHL diagnosis or a related binary trait derived from increases over age/sex-specific cutoff values. These include linkage to 1q in large Finnish pedigrees, followed by successful association analyses of a positional candidate gene, upstream transcription factor 1,¹⁶ replication of a linked region on 11p,^11,12 and a combined analysis of Finnish and Dutch families, which showed linkage to 16q.¹⁷ Although some analyses of the quantitative lipid traits associated with FCHL have been included in these gene finding investigations, they have rarely been the main focus of the studies. For example, when analyzing FCHL-associated quantitative traits, Allayee et al¹⁸ found linkage of apoB to chromosome region 1p31 in a cohort of Dutch FCHL pedigrees when the trait was treated as binary. That is, if the individual exceeded the 90th percentile for their age and sex category, they were considered as affected. Using a similar analytic approach, Pajukanta et al¹⁷ treated high-density lipoprotein (HDL) cholesterol as a binary trait, and mapped a locus for HDL cholesterol to chromosome 16q. Almasy et al¹⁹ used the full quantitative distribution of HDL cholesterol and localized 2 putative genes influencing this trait in large pedigrees that were not ascertained for a specific lipid disorder, such as FCHL. Although the quantitative traits have been the focus of these analyses, we can hypothesize that against different genetic backgrounds (morbid or healthy), a different genetic cause in the same or different pathways may be operating to define one’s profile of lipid traits.

The linkage analyses we report herein were undertaken to identify the QTL for cholesterol, triglycerides, and apoB, which are the component traits contributing to a diagnosis of FCHL. We conducted these analyses in a sample of FCHL pedigrees containing affected and unaffected individuals, and in which the disease-defining quantitative traits show extensive variation that is not normally distributed. By searching for lipid QTL within FCHL families, we hypothesized genes that normally make small contributions to individual lipid profiles may have larger effects and act as major genes that are easier to detect in these FCHL families.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Study Sample
Pedigrees were ascertained in Maastricht, the Netherlands via probands with multiple lipid abnormalities associated with FCHL. The ascertainment criteria were: (1) a proband with a primary hyperlipidemia, including fasting total plasma cholesterol >6.5mmol/L (250 mg/dL) and/or fasting plasma triglyceride concentrations >2.0 mmol/L (180 mg/dL); (2) multiple lipoprotein phenotypes within the family (Fredrickson classification IIa, IIb, or IV); and (3) a positive family history of premature cardiovascular disease, defined as the occurrence of a myocardial infarction or cerebrovascular accident before the age of 60 reported in medical records. Exclusion criteria were secondary causes of hyperlipidemia (renal or hepatic insufficiency, hypothyroidism, and medication), the apo E2/E2 genotype, and subjects with tendon xanthomas or a diagnosis matching familial hypercholesterolemia. To further reduce potential genetic heterogeneity, pedigrees from among those satisfying the aforementioned criteria were included in the current analyses only if the proband had levels of serum triglycerides and serum cholesterol exceeding age/sex-specific cutoff values and at least 1 first-degree relative had an increased age-specific and sex-specific serum triglyceride or serum cholesterol level Specifically, the proband in each family included in these analyses exceeded the 90th percentiles for total serum cholesterol and triglyceride levels within the subject’s age and sex category according to the distributions from a large-scale Finnish population-based study.²⁰ These percentiles may be more stringent than those for the Dutch, which are not available.

ApoB, cholesterol, and triglycerides levels are not normally distributed in these pedigrees, as illustrated in Figure 1. The means (m) and standard deviations (s) of these traits taken respectively in the siblings in this sample are: apoB (m=121.2; s=33.1), cholesterol (m=5.9; s=1.7), and triglycerides (m=2.4; s=2.8). The pedigrees selected for the analyses also vary markedly in their sizes, with some nuclear families and other quite large multigenerational families. These factors discouraged us from undertaking a variance component linkage analysis, which assumes normality of the quantitative traits and is most effective in larger pedigrees. We chose to use a nonparametric statistical linkage method that correlates allele sharing identical-by-descent (ibd) in sibling pairs with the differences in their trait values, instead. Table 1 gives the sizes of the sibships in this sample, the numbers of sibships of each of those sizes, and the numbers of sibling pairs provided to the analyses. This study was approved by Human Investigation Research Committee of the Academic Hospital of Maastricht and the UCLA institutional review board.

View larger version (11K): [in this window] [in a new window]   Figure 1. Frequency distributions of apoB, cholesterol, and triglycerides in FCHL sibships.

View this table: [in this window] [in a new window]   TABLE 1. Sibships in the FCHL Quantitative Trait Locus Analyses

Lipid Measurements
The lipid measurements were performed in the morning (8:00 AM to 11:00 AM) after an overnight fast (12 to 14 hours). Subjects refrained from smoking and did not drink coffee or tea in the morning and had abstained from alcohol for at least 72 hours. Any lipid-lowering medication had been withdrawn for 2 weeks before all measurements were made. Total cholesterol and fasting triglyceride concentrations were measured in duplicate by a commercially available colorimetric assay (Monotest Cholesterol kit, Boehringer Mannheim 1442350 and GPO-PAP, Boehringer Mannheim, 701912, respectively). Plasma apoB measurements were obtained using a commercially available immunophelometric assay using calibrated standards according to the International Federation for Clinical Chemistry (Behringwerke, Marburg, Germany). Plasma cholesterol and triglycerides are reported in mmol/L. Each sibling had values for the 3 quantitative traits undergoing analysis.

Genotyping
Three hundred seventy-seven informative microsatellite markers with an average intermarker distance of 9.4 cM were genotyped by the Marshfield Genotyping service (http://www.marshfieldclinic.org/research/genetics/) using the markers of Marshfield Panel 10. Gaps between markers >15 cM were located at 5p1314 (23 cM), 6p24-25 (17 cM), 9q34 (17 cM), 11q12-3 (17 cM), and 11q24-25 (19 cM). All siblings and 76% of the parents in these nuclear families were genotyped. Mendelian errors were detected in 4.2% of the sibling genotypes, and the inconsistent marker was then coded with zeros for that sibling or family.

QTL Linkage Analyses
A multipoint nonparametric or model-free statistical method that correlates the differences in trait levels within sibling pairs with their degree of allele sharing ibd along the chromosomes was used. When there is linkage to a region, similar trait values are expected to occur in sibling pairs with increased marker allele sharing, whereas those pairs that have different trait values will exhibit reduced marker allele sharing. With this test, for each sibling pair, the trait difference is calculated and ranked over the entire sample. Siblings in a pair who have a similar lipid value will have a low rank, such as 10 of 100, whereas siblings in a pair who differ by a relatively large amount will have a larger rank, such as 90 of 100. The statistical procedure relates the ranks of the sibling trait differences to their estimated degrees of allele sharing, using the nonparametric Kruskal–Wallis test,²¹ which is similar to an analysis of variance on the ranks of the trait differences. This test is programmed in the "nonparametric" option in the Genehunter software,²² and the test statistic is a z-score in which the probability value is calculated from the 1-sided standard normal distribution. The multipoint nature of the analysis results from estimating the probabilities of sharing 0, 1, and 2 alleles ibd across the chromosome at 2-cM intervals using the alleles of the siblings at the genotyped markers and the genetic map across the region. A Haldane map function was used. Significant QTL have been identified by P<0.001 with this analysis. We also identified those regions having 2 or more traits each with P<0.03 at the same locus.

Additional QTL Analyses
A second analytic approach, the Haseman–Elston (HE) test,²³ which correlates allele-sharing ibd with the squares of raw trait differences in sibling pairs by regressing the squared differences against the allele sharing, is more vulnerable to the influences of non-normally distributed data. Multipoint HE analyses were also conducted with the Genehunter software, but the results were not used to identify the linked regions and were included for informational purposes only in those the regions first identified by the nonparametric analyses. One large sibship in the sample consisted of 13 siblings as well as additional sibships that contained their offspring. We conducted all of the analyses described, on this subsample alone, to infer which of the linkage signals derived primarily from this family.

Linkage Analysis of ApoB and Triglycerides as a Discrete Trait
To also investigate the binary phenotype of FCHL, we used the quantitative traits of apoB and triglycerides as suggested by the most recent workshop on FCHL²⁴ to define a binary FCHL phenotype. Their consensus was that increased apoB and triglyceride levels, rather than the classical phenotype of combined elevated cholesterol and triglyceride levels, be applied in the diagnosis of FCHL. This was based on previous studies of the FCHL trait that showed impaired clearance of postprandial lipoproteins and increased very-low-density lipoprotein (VLDL) secretion lead to increased plasma levels of apoB and triglycerides,^25,26 implying that apoB may be a more precise measure of increased VLDL. Thus, all pedigree members were assessed as to whether their apoB or triglyceride levels exceeded the 90th percentile for their age and sex categories, again using the Finnish distributions.²⁰ Among the pedigrees, 20 contained at least 2 individuals who exceeded either of these criteria and they were included, resulting in 125 individuals who were classified as "affected." A single-point parametric linkage analysis of the genome scan data was conducted using a dominant fully penetrant model for the inheritance of the putative disease gene.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Table 2 summarizes the positive QTL results from the nonparametric linkage analyses as defined by P<0.001 for 1 trait, or P<0.03 for each of 2 or more traits. The table is organized vertically by the chromosome, and within that the trait names in alphabetic order. The first column gives the name of the trait, the second column gives the name of the marker closest to the linkage peak, and the third column gives the chromosome band(s) at which the QTL occurs. The fourth column gives the distance of the peak marker from the p-terminal end of the chromosome, the fifth column gives the z-score for the nonparametric analysis and the corresponding probability value, the sixth column gives the HE lod score, and the last column gives the nonparametric z-score and the corresponding probability value for the analysis of the largest family of 13 siblings and 3 nuclear families containing their offspring. Four QTL were identified by the criterion of P<0.001. They are at 1p21-31 (P<0.000009) and 17p11-21 (P<0.000009) for apoB, 12p13 (P<0.0001) for cholesterol, and 4p15-16 (P<0002) for triglycerides.

View this table: [in this window] [in a new window]   TABLE 2. Linkage Peaks for ApoB, Cholesterol, and Triglycerides QTL in FCHL Sibships

Detailed plots of the significant QTL as defined by P<0.001 by the multipoint nonparametric analysis of the full genome scan of apoB, total cholesterol, and triglycerides are presented in Figure 2. The QTL are displayed in both directions from the peak to the point where the linkage signal is zero. The nonparametric and HE linkage statistics are presented on the same axes, with the nonparametric z-score in solid black lines and the HE lod scores in dashed gray lines.

View larger version (18K): [in this window] [in a new window]   Figure 2. Plots in bold black lines of nonparametric z-scores QTL defined by P<.001 for apoB, cholesterol, and triglycerides in FCHL sibships. The HE lod scores for these data are plotted with dashed gray lines on the same axes. The distance along the horizontal axis is in centimorgans (cM) and the genotyped markers are indicated. The distance along the vertical axis is either nonparametric z-score or HE lod score.

The results for regions showing >1 QTL, as defined by P<0.03 for each trait, are 4q34-35 for apoB (P<0.02) and triglycerides (P<0.01), 16p12-13 for cholesterol (P<0.01) and triglycerides (P<0.02), and 17p11-q21 shows linkage to cholesterol (P<0.008) and triglycerides (P<0.02) in addition to apoB. The traits are highly correlated in the probands of these sibships; the Spearman correlations are: 0.71 (P=0.0002) for apoB and cholesterol, 0.42 (P=0.05) for apoB and triglycerides, and 0.62 (P=0.002) for cholesterol and triglycerides. Nonparametric analysis z-scores and probability values indicate that the largest sibship of 13 siblings and 3 nuclear families with their offspring can explain the linkage of triglycerides to 4p15-16. However, although linkage of apoB to 1p21-31 is also observed in the large family, other sibships in the sample also appear to contribute to this QTL. This same pattern is evident at 17p11-q21 for apoB. The QTL for cholesterol at 12p13 appears to derive very little of its linkage signal from this large family.

The parametric 2-point analyses of FCHL, when it was defined as binary trait by either increased age/sex-specific apoB or triglyceride levels, yielded all but 2 lod scores <1.5. Both were in one 20-cM region of 16p12-13. Because only one of the markers yielded a high lod score of 4.0, we also conducted a multipoint analysis to include the linkage information from the surrounding markers. Those results were, as expected, more modulated, with a multipoint lod score of 1.5. In a parametric analysis of a binary trait, lack of evidence for linkage can occur either because there is no linkage to a region or because an incorrect model for the inheritance pattern of the FCHL genes was posed. We report these results, however, because the alternative definition of the FCHL trait is linked to a chromosome region that overlaps with the cholesterol and triglycerides QTL on 16p12-13 as defined by P<0.03 for both traits.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
The overwhelming success of gene-finding efforts for Mendelian diseases encourages a focus on genetically complex disorders such as FCHL. Recent reports indicate that a number of predisposing FCHL genes are on their way toward being identified and confirmed, but much remains to be performed before the genetics of this disorder is fully understood, and thoughts can turn to risk prediction and specific treatment targets. A successful example is the report of linkage¹⁰ and association of USF-1 in Finnish FCHL pedigrees,¹⁶ with support for linkage of triglycerides to this region found in Dutch FCHL families,¹⁸ as well as diabetes-related traits found in other independent cohorts.^27–29 FCHL is a genetically complex disease, and the consensus is that innovative and more in-depth trait definitions and alternative analytic strategies are required to obtain insight. Toward that end, we examined individual FCHL-related quantitative traits in pedigrees to map their QTL. A model-free nonparametric statistical linkage procedure that makes no assumptions regarding trait normality and correlates the degree of allele sharing with the degree of trait sharing in the sibling pairs was used. The analyses provided evidence for apoB QTL on 1p21-31 and 17p11-q23, a cholesterol QTL on 12p13, and a triglycerides QTL on 4p15-16. Using a less stringent criterion, we found evidence of apoB and triglycerides QTL on 4q34-35, cholesterol and triglycerides QTL as well as linkage of a binary FCHL trait defined by increased apoB or serum triglycerides to 16p13-12, and all 3 quantitative traits to 17p11-21.

Although the criterion of P<0.001 was used for reporting linkage, 3 correlated quantitative traits and 1 bivariate binary trait have been analyzed separately, and multiple testing must be considered in the interpretation of these results. The QTL reported in Table 2 and Figure 2 are significant at the P<0.001 level, even if a stringent Bonferroni correction is applied. This is not true for the QTL identified by P<0.03 for 2 or more traits, so we report them but, without follow-up studies, interpret them as interesting results. In addition, we recognize that this 10-cM genome scan is only a first step in the gene identification process for FCHL. It can only localize the predisposing genes to wide chromosome regions of 35 to 40 cM. However, we envision that reports, such as this one, will provide the basis for future collaborations to fine-map specific regions in combined study samples to localize the disease-predisposing genes with greater precision. As SNP technologies become more cost-effective, the individual risk genes will likely be discovered. This is a long process, and these initial investigations are necessary for future success. With this in mind, we examined the literature for other positive linkage signals in the QTL regions revealed by these analyses.

The apoB QTL at 1p21-31 with a peak at 139 cM near marker D1S1627 in this sample is 35 cM from a linkage peak for apoB at marker D1S1665 found in an independent Dutch FCHL cohort from Utrecht. In that sample, apoB was treated as a binary trait, and those with an apoB level exceeding the 90th percentile for their age and sex were coded as affected in an "affecteds only" linkage analysis.¹⁸ Although it is tempting, the distance of 35 cM between the peaks may be too large to allow us to infer that these samples are mapping the same apoB gene.

We are most encouraged by the coincident location of QTL for apoB, cholesterol, and triglycerides within the 17p11-21 chromosomal region. Although the traits are correlated in this sample, the fact that all 3 have QTL in the same region may reflect a gene contributing to the increase in multiple lipid profiles associated with FCHL. A 2-point HE analysis of triglyceride levels in an independent sample of 75 obese families resulted in a peak z-score of 2.58 at 65 cM, although the linked region ranged from 40 to 70 cM, and is consistent with our findings.¹³ Although it was not among the strongest results, linkage to this region with P=0.014 has also been reported for cholesterol in an independent cohort of British FCHL families.¹² Because cholesterol-carrying lipoproteins have apoB as their structural apoprotein, and FCHL is characterized by elevated plasma levels of apoB containing VLDL and low-density lipoproteins (LDL), this is not unexpected. The putative gene in this region may have a pleiotropic effect on increased total serum cholesterol and apoB within FCHL pedigrees. In addition, VLDL subclasses have direct impacts on the plasma concentrations of LDL subclasses in FCHL, specifically VLDL1 and small dense LDL,³⁰ suggesting a VLDL–triglyceride pathway in FCHL. What is known about its biochemistry corresponds well with linkage and association results for apoA-CIII-AIV, apoAII, and apoB in FCHL.³⁰ The USF-1 gene may also act in the VLDL–triglyceride pathway by stimulating lipogenesis, by fatty acid synthase, for export in VLDL, apoB, cholesterol, and triglycerides.³¹ 17q11 contains the gene for NOS2A, the inducible nitric oxide synthase, which we found to be downregulated in adipose tissue biopsy samples from FCHL subjects in comparison with age-, sex-, and body mass index-matched controls (data not shown). NOS2A acts in the liver and may have other less well-characterized functions than regulation of vascular tone.³²

The linkage found with apoB in the region of marker D1S1627 is of interest, because it was also found to be linked with plasma leptin concentrations that reflect adiposity in an independent cohort of Dutch FCHL subjects from Utrecht.³³ It was suggested that the linkage may be caused by DNA variation in the leptin receptor (LEPR) gene, close to D1S1627. We also find that as adiposity, assessed by the waist-to-hip ratio, increases, FCHL subjects express higher plasma apoB concentrations than matched controls (data not shown). Thus, the linkage between plasma apoB concentrations and D1S1627 is consistent with the influence of the LEPR gene on apoB in FCHL. Extensive single nucleotide association studies would have to be conducted to pursue this possibility.

These findings illustrate that a QTL approach in combination with refined phenotypes will yield insight into novel genes and pathways responsible for FCHL and its associated risk of heart disease.

	Acknowledgments

 
This work was supported by National Institutes of Health grant HL-28481 and the Netherlands Organization of Scientific Research (900-95-299). Genotyping was performed by the Mammalian Genotyping Service of the Marshfield Medical Research Foundation. We thank Eric Keulen, MD and Josefine van Lin, research nurse, for invaluable help with the collection of the families, and Margee Robertus-Teunissen for technical assistance.

Received April 15, 2004; accepted July 30, 2004.

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