The role of complement factor I rare genetic variants in age related macular degeneration in Finland.

IF 3.1 2区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Human molecular genetics Pub Date : 2024-11-25 DOI:10.1093/hmg/ddae165

Anneliza Andreadi, Thomas M Hallam, Vicky Brocklebank, Scott J Sharp, Patrick R Walsh, Tom Southerington, Marco Hautalahti, David H Steel, Andrew J Lotery, Claire L Harris, Kevin J Marchbank, David Kavanagh, Amy V Jones

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Abstract

Age-related macular degeneration (AMD) is the leading cause of irreversible blindness in the developed world. The alternative pathway (AP) of complement has been linked to the pathogenesis of AMD. In particular, rare variants (RVs) in the complement factor I (CFI) gene encoding the Factor I (FI) protein confer increased AMD risk. The prevalence of CFI RVs are well characterised in European AMD, however little is known about other populations. The Finnish population underwent genetic restriction events which have skewed allele frequencies in unexpected ways. A series of novel or enriched CFI RVs were identified in individuals with dry AMD from the Finnish Biobank Cooperative (FINBB), but the relationship between these genotypes and contribution to disease was unclear. Understanding how RVs impact the ability of FI to regulate the complement system is important to inform mechanistic understanding for how different genotypes contribute to disease development. To explore this a series of in vitro assays were used to functionally characterise the protein products of 3 CFI RVs enriched in FINBB dry AMD, where no prior data were available. The G547R variant resulted in almost complete loss of both classical pathway and AP regulatory potential. The c.982 g>a variant encoding G328R FI perturbed an exon splice enhancer site which resulted in exon skipping and a premature stop codon in vitro and low levels of FI in vivo. Despite detailed analysis no defect in levels or function was demonstrated in T107A. Functional characterization of all Finnish CFI RVs in the cohort allowed us to demonstrate that in Finnish dry AMD, collectively the type 1 CFI RVs (associated with FI haploinsufficiency) were significantly enriched with odds ratio (ORs) of 72.6 (95% confidence interval; CI 16.92 to 382.1). Meanwhile, type 2 CFI RVs (associated with FI dysfunction) collectively conferred a significant OR of 4.97 (95% CI 1.522 to 15.74), and non-impaired or normal CFI RV collectively conferred an of OR 3.19 (95% CI 2.410 to 4.191) although this was driven primarily by G261D. Overall, this study for the first time determined the ORs and functional effect for all CFI RVs within a Geographic Atrophy (GA) cohort, enabling calculations of combined risk scores that underline the risk conferred by type 1 and 2 CFI RVs in GA/AMD.

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补体因子 I 罕见遗传变异在芬兰老年性黄斑变性中的作用。

老年性黄斑变性（AMD）是发达国家导致不可逆失明的主要原因。补体的替代途径（AP）与老年黄斑变性的发病机制有关。特别是，编码补体因子 I（FI）蛋白的补体因子 I（CFI）基因的罕见变异（RV）会增加 AMD 的风险。CFI RV 在欧洲老年性黄斑病变中的发病率特征明显，但对其他人群的情况却知之甚少。芬兰人口经历了遗传限制事件，这些事件以意想不到的方式扭曲了等位基因频率。在芬兰生物库合作社（FINBB）的干性AMD患者中发现了一系列新的或富集的CFI RV，但这些基因型与疾病之间的关系尚不清楚。了解RV如何影响FI调节补体系统的能力对于从机理上理解不同基因型如何导致疾病的发生非常重要。为了探究这一问题，研究人员使用了一系列体外检测方法，对 FINBB 干性 AMD 中富含的 3 种 CFI RV 的蛋白产物进行了功能表征，而在 FINBB 干性 AMD 中还没有相关数据。G547R 变异导致经典途径和 AP 调节潜力几乎完全丧失。编码 G328R FI 的 c.982 g>a 变异扰乱了一个外显子剪接增强子位点，导致体外的外显子跳过和过早终止密码子，以及体内低水平的 FI。尽管对 T107A 进行了详细分析，但并未发现其水平或功能存在缺陷。通过对队列中所有芬兰 CFI RV 的功能特征进行分析，我们发现在芬兰干性 AMD 患者中，1 型 CFI RV（与 FI 单倍缺失相关）明显富集，其几率比（ORs）为 72.6（95% 置信区间；CI 16.92 至 382.1）。与此同时，2 型 CFI RV（与 FI 功能障碍相关）共同带来 4.97（95% 置信区间：1.522 至 15.74）的显着 OR，而非受损或正常 CFI RV 共同带来 OR 3.19（95% 置信区间：2.410 至 4.191），尽管这主要是由 G261D 驱动的。总之，这项研究首次确定了地理萎缩（GA）队列中所有 CFI RV 的 ORs 和功能效应，从而能够计算出综合风险评分，强调了 1 型和 2 型 CFI RV 在 GA/AMD 中所带来的风险。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Human molecular genetics 生物-生化与分子生物学

CiteScore

6.90

自引率

2.90%

发文量

294

审稿时长

2-4 weeks

期刊介绍： Human Molecular Genetics concentrates on full-length research papers covering a wide range of topics in all aspects of human molecular genetics. These include: the molecular basis of human genetic disease developmental genetics cancer genetics neurogenetics chromosome and genome structure and function therapy of genetic disease stem cells in human genetic disease and therapy, including the application of iPS cells genome-wide association studies mouse and other models of human diseases functional genomics computational genomics In addition, the journal also publishes research on other model systems for the analysis of genes, especially when there is an obvious relevance to human genetics.