Centre for Clinical Epidemiology and Biostatistics, and School of Medicine and Public Health, University of Newcastle, Newcastle, New South Wales, Australia.
PLoS One. 2013;8(1):e53830. doi: 10.1371/journal.pone.0053830. Epub 2013 Jan 11.
Genetic factors explain a majority of risk variance for age-related macular degeneration (AMD). While genome-wide association studies (GWAS) for late AMD implicate genes in complement, inflammatory and lipid pathways, the genetic architecture of early AMD has been relatively under studied. We conducted a GWAS meta-analysis of early AMD, including 4,089 individuals with prevalent signs of early AMD (soft drusen and/or retinal pigment epithelial changes) and 20,453 individuals without these signs. For various published late AMD risk loci, we also compared effect sizes between early and late AMD using an additional 484 individuals with prevalent late AMD. GWAS meta-analysis confirmed previously reported association of variants at the complement factor H (CFH) (peak P = 1.5×10(-31)) and age-related maculopathy susceptibility 2 (ARMS2) (P = 4.3×10(-24)) loci, and suggested Apolipoprotein E (ApoE) polymorphisms (rs2075650; P = 1.1×10(-6)) associated with early AMD. Other possible loci that did not reach GWAS significance included variants in the zinc finger protein gene GLI3 (rs2049622; P = 8.9×10(-6)) and upstream of GLI2 (rs6721654; P = 6.5×10(-6)), encoding retinal Sonic hedgehog signalling regulators, and in the tyrosinase (TYR) gene (rs621313; P = 3.5×10(-6)), involved in melanin biosynthesis. For a range of published, late AMD risk loci, estimated effect sizes were significantly lower for early than late AMD. This study confirms the involvement of multiple established AMD risk variants in early AMD, but suggests weaker genetic effects on the risk of early AMD relative to late AMD. Several biological processes were suggested to be potentially specific for early AMD, including pathways regulating RPE cell melanin content and signalling pathways potentially involved in retinal regeneration, generating hypotheses for further investigation.
遗传因素解释了年龄相关性黄斑变性(AMD)的大部分风险差异。虽然全基因组关联研究(GWAS)表明晚期 AMD 中的基因涉及补体、炎症和脂质途径,但早期 AMD 的遗传结构相对研究较少。我们对早期 AMD 进行了 GWAS 荟萃分析,包括 4089 名有早期 AMD 征象(软性玻璃膜疣和/或视网膜色素上皮改变)的个体和 20453 名没有这些征象的个体。对于各种已发表的晚期 AMD 风险位点,我们还使用另外 484 名有晚期 AMD 征象的个体比较了早期和晚期 AMD 之间的效应大小。GWAS 荟萃分析证实了补体因子 H(CFH)(峰 P=1.5×10(-31)) 和年龄相关性黄斑病变易感性 2(ARMS2)(P=4.3×10(-24)) 位点的变异先前报道的关联,并提示载脂蛋白 E(ApoE)多态性(rs2075650;P=1.1×10(-6)) 与早期 AMD 相关。其他未达到 GWAS 显著性的可能位点包括锌指蛋白基因 GLI3(rs2049622;P=8.9×10(-6)) 和 GLI2 上游(rs6721654;P=6.5×10(-6)) 的变异,编码视网膜 Sonic hedgehog 信号调节剂,以及酪氨酸酶(TYR)基因(rs621313;P=3.5×10(-6)),参与黑色素生物合成。对于一系列已发表的晚期 AMD 风险位点,早期 AMD 的估计效应大小明显低于晚期 AMD。本研究证实了多种已确立的 AMD 风险变异在早期 AMD 中的参与,但表明与晚期 AMD 相比,早期 AMD 的遗传效应较弱。一些生物学过程被认为可能是早期 AMD 特有的,包括调节 RPE 细胞黑色素含量的途径和可能参与视网膜再生的信号通路,为进一步研究提供了假设。
