A Quantitative Computational Framework for Allopolyploid Single-Cell Data Integration and Core Gene Ranking in Development.

IF 11 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Molecular biology and evolution Pub Date : 2024-09-04 DOI:10.1093/molbev/msae178
Meiyue Wang, Zijuan Li, Haoyu Wang, Junwei Zhao, Yuyun Zhang, Kande Lin, Shusong Zheng, Yilong Feng, Yu'e Zhang, Wan Teng, Yiping Tong, Wenli Zhang, Yongbiao Xue, Hude Mao, Hao Li, Bo Zhang, Awais Rasheed, Sridhar Bhavani, Chenghong Liu, Hong-Qing Ling, Yue-Qing Hu, Yijing Zhang
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Abstract

Polyploidization drives regulatory and phenotypic innovation. How the merger of different genomes contributes to polyploid development is a fundamental issue in evolutionary developmental biology and breeding research. Clarifying this issue is challenging because of genome complexity and the difficulty in tracking stochastic subgenome divergence during development. Recent single-cell sequencing techniques enabled probing subgenome-divergent regulation in the context of cellular differentiation. However, analyzing single-cell data suffers from high error rates due to high dimensionality, noise, and sparsity, and the errors stack up in polyploid analysis due to the increased dimensionality of comparisons between subgenomes of each cell, hindering deeper mechanistic understandings. In this study, we develop a quantitative computational framework, called "pseudo-genome divergence quantification" (pgDQ), for quantifying and tracking subgenome divergence directly at the cellular level. Further comparing with cellular differentiation trajectories derived from single-cell RNA sequencing data allows for an examination of the relationship between subgenome divergence and the progression of development. pgDQ produces robust results and is insensitive to data dropout and noise, avoiding high error rates due to multiple comparisons of genes, cells, and subgenomes. A statistical diagnostic approach is proposed to identify genes that are central to subgenome divergence during development, which facilitates the integration of different data modalities, enabling the identification of factors and pathways that mediate subgenome-divergent activity during development. Case studies have demonstrated that applying pgDQ to single-cell and bulk tissue transcriptomic data promotes a systematic and deeper understanding of how dynamic subgenome divergence contributes to developmental trajectories in polyploid evolution.

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全多倍体单细胞数据整合及发育过程中核心基因排序的定量计算框架。
多倍体化推动了调控和表型创新。不同基因组的合并如何促进多倍体的发育是进化发育生物学和育种研究的一个基本问题。由于基因组的复杂性以及在发育过程中跟踪随机亚基因组分化的难度,要弄清这一问题具有挑战性。最近的单细胞测序技术能够在细胞分化的背景下探测亚基因组的分化调控。然而,由于高维度、噪声和稀疏性,分析单细胞数据的错误率很高,而在多倍体分析中,由于每个细胞的亚基因组之间的比较维度增加,错误会叠加,从而阻碍了对机理的深入理解。在此,我们开发了一种定量计算框架--伪基因组分歧量化(pgDQ),可直接在细胞水平上量化和跟踪亚基因组分歧。pgDQ 能产生稳健的结果,对数据丢失和噪声不敏感,避免了因基因、细胞和亚基因组的多重比较而导致的高错误率。该研究提出了一种统计对角方法,用于识别发育过程中亚基因组分化的核心基因,这有助于整合不同的数据模式,从而识别发育过程中介导亚基因组分化活动的因素和途径。案例研究表明,将 pgDQ 应用于单细胞和大块组织转录组数据有助于系统和深入地了解动态亚基因组分化是如何促进多倍体进化过程中的发育轨迹的。
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来源期刊
Molecular biology and evolution
Molecular biology and evolution 生物-进化生物学
CiteScore
19.70
自引率
3.70%
发文量
257
审稿时长
1 months
期刊介绍: Molecular Biology and Evolution Journal Overview: Publishes research at the interface of molecular (including genomics) and evolutionary biology Considers manuscripts containing patterns, processes, and predictions at all levels of organization: population, taxonomic, functional, and phenotypic Interested in fundamental discoveries, new and improved methods, resources, technologies, and theories advancing evolutionary research Publishes balanced reviews of recent developments in genome evolution and forward-looking perspectives suggesting future directions in molecular evolution applications.
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