The Role of de novo and Ultra-Rare Variants in Hirschsprung Disease (HSCR): Extended Gene Discovery for Risk Profiling of Patients.

medRxiv : the preprint server for health sciences Pub Date : 2025-01-08 DOI:10.1101/2025.01.07.25320162

Mingzhou Fu, Hanna E Berk-Rauch, Sumantra Chatterjee, Aravinda Chakravarti

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Abstract

Background: Hirschsprung disease (HSCR) is a rare neurodevelopmental disorder caused by disrupted migration and proliferation of enteric neural crest cells during enteric nervous system development. Genetic studies suggest a complex etiology involving both rare and common variants, but the contribution of ultra-rare pathogenic variants (PAs) remains poorly understood.

Methods: We perform whole-exome sequencing (WES) on 301 HSCR probands and 109 family trios, employing advanced statistical methods and gene prioritization strategies to identify genes carrying de novo and ultra-rare coding pathogenic variants. Multiple study designs, including case-control, de novo mutation analysis and joint test, are used to detect associated genes. Candidate genes are further prioritized based on their biological and functional relevance to disease associated tissues and onset period (i.e., human embryonic colon).

Results: We identify 19 risk genes enriched with ultra-rare coding pathogenic variants in HSCR probands, including four known genes (RET, EDNRB, ZEB2, SOX10) and 15 novel candidates (e.g., COLQ, NES, FAT3) functioning in neural proliferation and neuromuscular synaptic development. These genes account for 17.5% of the population-attributable risk (PAR), with novel candidates contributing 6.5%. Notably, a positive correlation between pathogenic mutational burden and disease severity is observed. Female cases exhibit at least 42% higher ultra-rare pathogenic variant burden than males (P = 0.05).

Conclusions: This first-ever genome-wide screen of ultra-rare variants in a large, phenotypically diverse HSCR cohort highlights the substantial contribution of ultra-rare pathogenic variants to the disease risk and phenotypic variability. These findings enhance our understanding of the genetic architecture of HSCR and provide potential targets for genetic screening and personalized interventions.

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新生和超罕见变异在巨结肠疾病（HSCR）中的作用：扩展了患者风险谱的基因发现。

背景：巨结肠病（HSCR）是一种罕见的神经发育障碍，由肠神经系统发育过程中肠神经嵴细胞的迁移和增殖中断引起。遗传学研究表明，其复杂的病因包括罕见和常见的变异，但超罕见致病变异（PAs）的作用仍然知之甚少。方法：对301个HSCR先显子和109个三家族进行全外显子组测序（WES），采用先进的统计学方法和基因优先级策略鉴定携带新生和超罕见编码致病变异的基因。多种研究设计，包括病例对照、新生突变分析和联合试验，用于检测相关基因。候选基因根据其与疾病相关组织和发病时间（即人类胚胎结肠）的生物学和功能相关性进一步优先排序。结果：我们在HSCR先显子中鉴定出19个富含超罕见编码致病变异的风险基因，包括4个已知基因（RET、EDNRB、ZEB2、SOX10）和15个新的候选基因（如COLQ、NES、FAT3），这些基因在神经增殖和神经肌肉突触发育中起作用。这些基因占人群归因风险（PAR）的17.5%，而新的候选基因占6.5%。值得注意的是，致病突变负担与疾病严重程度呈正相关。女性病例的超罕见致病变异负担至少比男性高42% （P = 0.05）。结论：这是首次在一个大型、表型多样化的HSCR队列中对超罕见变异进行全基因组筛查，突出了超罕见致病变异对疾病风险和表型变异性的重大贡献。这些发现增强了我们对HSCR遗传结构的理解，并为遗传筛查和个性化干预提供了潜在的靶点。

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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medRxiv : the preprint server for health sciences

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