GV-Rep:用于遗传变异表征学习的大规模数据集

Zehui Li, Vallijah Subasri, Guy-Bart Stan, Yiren Zhao, Bo Wang
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引用次数: 0

摘要

基因变异(GVs)被定义为个体间 DNA 序列的差异,在诊断和治疗遗传疾病中起着至关重要的作用。新一代测序成本的快速降低导致患者水平的 GV 数据呈指数增长。这种增长给临床医生带来了挑战,他们必须有效地优先处理患者特定的 GV,并将其与现有的基因组数据库整合,为患者管理提供信息。为了解决 GV 的解释问题,基因组基础模型(GFM)应运而生。然而,这些模型缺乏标准化的性能评估,导致模型评估存在相当大的差异。这就提出了一个问题:深度学习方法如何有效地对未知 GV 进行分类,并将其与临床验证的 GV 进行对齐?我们认为,将原始数据转换为有意义的特征空间的表征学习是解决索引和分类难题的有效方法。我们引入了一个名为 GV-Rep 的大规模基因变异数据集,该数据集具有可变长度的上下文和详细注释,专为深度学习模型设计,用于学习各种性状、疾病、组织类型和实验上下文中的基因变异表征。我们的贡献包括三个方面:(i) 构建了一个包含 700 万条记录的综合数据集,每条记录都标注了相应变体的特征,此外还有来自 1,107 种细胞类型、1,808 种变体组合的 17,548 个基因敲除测试的数据,以及来自真实世界患者的 156 个经临床验证的独特 GV。(iii)用预先训练的 GFM 对数据集进行实验。结果表明,GFMs 目前的能力与准确的 GV 呈现之间存在明显差距。我们希望这个数据集将有助于推进基因组深度学习,弥补这一差距。
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GV-Rep: A Large-Scale Dataset for Genetic Variant Representation Learning
Genetic variants (GVs) are defined as differences in the DNA sequences among individuals and play a crucial role in diagnosing and treating genetic diseases. The rapid decrease in next generation sequencing cost has led to an exponential increase in patient-level GV data. This growth poses a challenge for clinicians who must efficiently prioritize patient-specific GVs and integrate them with existing genomic databases to inform patient management. To addressing the interpretation of GVs, genomic foundation models (GFMs) have emerged. However, these models lack standardized performance assessments, leading to considerable variability in model evaluations. This poses the question: How effectively do deep learning methods classify unknown GVs and align them with clinically-verified GVs? We argue that representation learning, which transforms raw data into meaningful feature spaces, is an effective approach for addressing both indexing and classification challenges. We introduce a large-scale Genetic Variant dataset, named GV-Rep, featuring variable-length contexts and detailed annotations, designed for deep learning models to learn GV representations across various traits, diseases, tissue types, and experimental contexts. Our contributions are three-fold: (i) Construction of a comprehensive dataset with 7 million records, each labeled with characteristics of the corresponding variants, alongside additional data from 17,548 gene knockout tests across 1,107 cell types, 1,808 variant combinations, and 156 unique clinically verified GVs from real-world patients. (ii) Analysis of the structure and properties of the dataset. (iii) Experimentation of the dataset with pre-trained GFMs. The results show a significant gap between GFMs current capabilities and accurate GV representation. We hope this dataset will help advance genomic deep learning to bridge this gap.
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