APOL1 variants: Understanding the basis of disparities in rates of kidney disease

APOL1 变异：了解肾脏疾病发病率差异的基础

• 批准号: 8607479
• 负责人: MARTIN R. POLLAK
• 金额: $ 43.5万
• 依托单位: BETH ISRAEL DEACONESS MEDICAL CENTER
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-04-01 至 2017-01-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8607479
• 关键词: AIDS-Associated Nephropathy; Accounting; Address; Admixture; Affect; Africa; African; African American; African Trypanosomiasis; Alleles; American; Binding; Binding Sites; Biochemical; Biological Assay; Biology; Caring; Code; Data; Disease; Employee Strikes; End stage renal failure; Environmental Risk Factor; Epidemic; European; Focal Segmental Glomerulosclerosis; Frequencies; Gene Expression; Gene Frequency; Genes; Genetic; Genetic Polymorphism; Genotype; Hereditary Disease; Human; Human Genetics; Hypertension; In Vitro; Individual; Injury; Kidney; Kidney Diseases; Kidney Failure; Lead; Lipids; Mediating; Mediator of activation protein; MicroRNAs; Mutation; Other Genetics; Pathway interactions; Penetrance; Protein Binding; Public Health; Renal function; Renal glomerular disease; Resistance; Risk; Risk Factors; Stratification; Testing; Trypanosoma; United States; Variant; Vitamin D; Yeasts; base; disorder risk; gain of function; genetic variant; genome wide association study; health disparity; high risk; improved; protective effect; risk variant; screening; transcription factor; yeast two hybrid system

SUMMARY More than 500,000 Americans suffer from end-stage renal disease (ESRD). African Americans develop kidney failure at rates 4-5 fold higher than European Americans. Recently, we discovered two coding sequence variants in ApolipoproteinL1 (APOL1) that account for a large proportion of this major health disparity. APOL1 kidney disease variants have a major impact on multiple different types of kidney disease including hypertension-associated ESRD, focal segmental glomerulosclerosis (FSGS), and HIV-associated nephropathy (HIVAN). Risk inheritance is recessive: individuals with two variant APOL1 alleles have a 7-30 fold increased risk for kidney disease. We predict that more than 3.5 million African Americans have the high risk APOL1 genotype. The presence of two risk alleles does not lead to kidney disease in all individuals, indicating that other genetic and environmental factors are important modifiers. Understanding why some individuals with the high-risk genotype develop kidney disease while others do not will improve risk stratification and may illuminate the pathways most amenable to therapy. We therefore propose to: Aim 1: Identify additional genetic modifiers at the APOL1 gene locus. Our data suggest that APOL1 kidney disease risk variants are gain-of- function alleles. Since not all individuals with two risk alleles develop disease, other local polymorphisms may regulate expression of APOL1, modulating the effect of the disease-causing APOL1 coding mutations. We will define structural variants that may alter APOL1 gene expression, and test their effects on the penetrance of the two disease-causing alleles. We will test whether polymorphisms in transcription factor and microRNA binding sites affect the penetrance of these APOL1 risk alleles. Aim 2: Find epistatic modifiers of APOL1 penetrance. The APOL1 renal risk variants increased in frequency in Africa, at least in part, because they provided protection against trypanosomes. We hypothesize that additional genetic loci were simultaneously selected that protect against renal injury from the major coding risk alleles, and that the protective effect of these loci may have diminished after admixture with Europeans. Here, we will perform a genome-wide screen for polymorphisms that may protect against or exacerbate APOL1 variant-induced renal injury. We will identify proteins that bind differentially to wild type and coding variant ApoL1, as these binding partners may modulate injury caused by the risk variants. Aim 3: Identify biochemical modifiers of APOL1-mediated renal disease. ApoL1 kidney disease risk variants may be most deleterious in the setting of additional risk factors. Here, we explore how two important factors may interact with APOL1 genotype to cause renal disease. Vitamin D is believed to be protective against renal injury, while certain lipid profiles may promote injury. We ask whether these molecules alter APOL1 biology in vitro, and whether biochemical levels of these mediators predict which individuals with the APOL1 risk genotype are likely to develop kidney disease.

概括 超过50万美国人患有末期肾脏疾病（ESRD）。非裔美国人发展肾脏 率的失败比欧洲人高4-5倍。最近，我们发现了两个编码序列 载脂蛋白1（Apol1）的变体占此主要健康差异的很大比例。 apol1 肾脏疾病变体对多种不同类型的肾脏疾病有重大影响 高血压相关的ESRD，局灶性节段性肾小球硬化（FSGS）和与HIV相关的肾病 （Hivan）。风险继承是隐性的：两个变体Apol1等位基因的人增加了7-30倍 肾脏疾病的风险。我们预测，超过350万非洲裔美国人的风险很高。 基因型。在所有个体中，存在两个风险等位基因的存在不会导致肾脏疾病，表明 其他遗传和环境因素是重要的修饰符。了解为什么有些人与 高风险的基因型发展肾脏疾病，而其他人则不会改善风险分层，并可能阐明 最适合治疗的途径。因此，我们建议：目标1：确定其他遗传 Apol1基因座的修饰符。我们的数据表明，apol1肾脏疾病风险变异是 - 功能等位基因。由于并非所有患有两个风险等位基因的人都会出现疾病，因此其他局部多态性可能 调节APOL1的表达，调节引起疾病的APOL1编码突变的作用。我们将 定义可能改变apol1基因表达的结构变体，并测试其对 两个引起疾病的等位基因。我们将测试转录因子和microRNA结合中的多态性是否 站点会影响这些APOL1风险等位基因的外观。 AIM 2：查找Apol1的同志修饰符 外观。至少部分是因为它们 提供防止锥虫的保护。我们假设其他遗传基因座同时是 选择防止肾脏损伤免受主要编码风险等位基因的选择，以及 与欧洲人混合后，这些基因座可能已经减少。在这里，我们将执行全基因组屏幕 对于可能预防或加剧APOL1变异诱导的肾脏损伤的多态性。我们将确定 与野生类型和编码变体Apol1差异结合的蛋白质，因为这些结合伙伴可能会调节 风险变体造成的伤害。 AIM 3：确定APOL1介导的肾脏的生化修饰符 疾病。在其他风险因素的情况下，Apol1肾脏疾病风险变异可能是最有害的。 在这里，我们探讨了两个重要因素如何与APOL1基因型相互作用以引起肾脏疾病。 维生素D被认为可以防止肾脏损伤，而某些脂质特征可能会促进损伤。我们 询问这些分子是否会在体外改变Apol1生物学，以及这些介体的生化水平是否 预测哪些患有APOL1风险基因型的人可能会发展肾脏疾病。