Heijmans Bastiaan T, Beekman Marian, Putter Hein, Lakenberg Nico, van der Wijk Henk Jan, Whitfield John B, Posthuma Daniëlle, Pedersen Nancy L, Martin Nicholas G, Boomsma Dorret I, Slagboom P Eline
Molecular Epidemiology, Leiden University Medical Centre, Leiden, The Netherlands.
Eur J Hum Genet. 2005 Oct;13(10):1143-53. doi: 10.1038/sj.ejhg.5201466.
Lipid levels in plasma strongly influence the risk for coronary heart disease. To localise and subsequently identify genes affecting lipid levels, we performed four genome-wide linkage scans followed by combined linkage/association analysis. Genome-scans were performed in 701 dizygotic twin pairs from four samples with data on plasma levels of HDL- and LDL-cholesterol and their major protein constituents, apolipoprotein AI (ApoAI) and Apolipoprotein B (ApoB). To maximise power, the genome scans were analysed simultaneously using a well-established meta-analysis method that was newly applied to linkage analysis. Overall LOD scores were estimated using the means of the sample-specific quantitative trait locus (QTL) effects inversely weighted by the standard errors obtained using an inverse regression method. Possible heterogeneity was accounted for with a random effects model. Suggestive linkage for HDL-C was observed on 8p23.1 and 12q21.2 and for ApoAI on 1q21.3. For LDL-C and ApoB, linkage regions frequently coincided (2p24.1, 2q32.1, 19p13.2 and 19q13.31). Six of the putative QTLs replicated previous findings. After fine mapping, three maximum LOD scores mapped within 1 cM of major candidate genes, namely APOB (LOD=2.1), LDLR (LOD=1.9) and APOE (LOD=1.7). APOB haplotypes explained 27% of the QTL effect observed for LDL-C on 2p24.1 and reduced the LOD-score by 0.82. Accounting for the effect of the LDLR and APOE haplotypes did not change the LOD score close to the LDLR gene but abolished the linkage signal at the APOE gene. In conclusion, application of a new meta-analysis approach maximised the power to detect QTLs for lipid levels and improved the precision of their location estimate.
血浆中的脂质水平对冠心病风险有强烈影响。为了定位并随后鉴定影响脂质水平的基因,我们进行了四项全基因组连锁扫描,随后进行了连锁/关联联合分析。在来自四个样本的701对异卵双胞胎中进行了基因组扫描,这些样本具有高密度脂蛋白胆固醇(HDL-C)和低密度脂蛋白胆固醇(LDL-C)及其主要蛋白质成分载脂蛋白AI(ApoAI)和载脂蛋白B(ApoB)的血浆水平数据。为了最大化检验效能,使用一种新应用于连锁分析的成熟荟萃分析方法同时分析基因组扫描结果。使用通过逆回归方法获得的标准误进行反向加权后的样本特异性数量性状位点(QTL)效应均值来估计总体LOD分数。采用随机效应模型来考虑可能的异质性。在8p23.1和12q21.2观察到HDL-C的提示性连锁,在1q21.3观察到ApoAI的提示性连锁。对于LDL-C和ApoB,连锁区域经常重合(2p24.1、2q32.1、19p13.2和19q13.31)。六个推定的QTL重复了先前的发现。精细定位后,三个最大LOD分数位于主要候选基因的1 cM范围内,即APOB(LOD = 2.1)、LDLR(LOD = 1.9)和APOE(LOD = 1.7)。APOB单倍型解释了2p24.1上观察到的LDL-C的QTL效应的27%,并使LOD分数降低了0.82。考虑LDLR和APOE单倍型的效应并没有改变靠近LDLR基因的LOD分数,但消除了APOE基因处的连锁信号。总之,一种新的荟萃分析方法的应用最大化了检测脂质水平QTL的能力,并提高了其定位估计的精度。
