Genome architecture dynamics and expression

基因组结构动态和表达

• 批准号: RGPIN-2014-06018
• 负责人: Chen, Nansheng
• 金额: $ 3.42万
• 依托单位: Simon Fraser University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=611980
• 关键词: Genome; architecture; dynamics; expression

Accelerating advances in DNA sequencing technologies is driving the creation of an unprecedented genome resource for a wide range of organisms, presenting golden opportunities for mining the genome information that instructs the generation of biological processes including development, aging, metabolism, and learning and memory. The long-term goal of my research program is to understand genome structural changes (i.e., architecture dynamics) and how this affects genome expression. The strength of this program builds on our combined experience in nematode molecular biology and in developing and applying innovative bioinformatics tools. We work with the genomes of nematodes because this phylum contains both the well-studied model organism C. elegans, and many pathogens including deadly animal (including human) and plant parasites. The proposed research will address two complementary short-term objectives over the next 5 years, aiming to understand genome expression from both the whole-genome level and a single-gene level. Our first objective is to investigate genome architecture dynamics and how such dynamics define genomic novelty and affect gene expression. We hypothesize that the formation of novel genes and isoforms is the driving force in shaping genomic and phenotypic diversity. Novel genes can form through a variety of mechanisms including duplication, extension or truncation of genes, fusion between full or partial genes, and de novo formation. In order to identify novel genes, we will analyze genomic differences between C. elegans strains (including the reference N2 strain and strains collected worldwide), as well as between C. elegans and C. briggsae (the most extensively studied sister species) and other related nematode species, followed by examining how they contribute to the formation of novel genes. Candidate novel genes will be validated through transcriptome sequencing and analysis (RNA-seq), as well as full-length cDNA analysis. In contrast, the formation of novel isoforms of a gene is not well understood. Our recent quantitative comparison RNA-seq results of C. elegans and C. briggsae revealed that orthologs in these two species can have drastically different splicing, suggesting the formation of novel isoforms. Novel isoforms (as well as de novo genes) will be uncovered via direct RNA-seq analysis of various strains and species. We will evaluate the function of the predicted novel genes through computational and experimental approaches. The second objective is to study gene expression regulation at the level of transcription, focusing on the transcriptional regulation of the ciliary gene MAK/dyf-5 in C. elegans that we have cloned and identified previously. dyf-5 is a conserved gene found in a wide range of organisms including the green algae Chlamydomonas reinhardtii and humans. Loss-of-function of dyf-5 leads to defective cilia development and function. We will carry out genetic screening to identify mutants that affect the expression of dyf-5 that is tagged with fluorescence protein tdTomato. These mutated genes will be identified through genetic mapping, genome sequencing, and bioinformatics analysis, followed by molecular studies of their functional contribution to the precise expression of dyf-5. We expect to identify co-transcription factors that function together with RFX/DAF-19, a transcription factor that is required for the expression of essentially all ciliary genes. Collectively, research of these objectives will reveal mechanisms underlying the creation of genomic novelty and phenotypic diversity, which contribute to the initiation of speciation. Bioinformatics tools developed in the course of this proposed research will greatly facilitate the field of comparative genomics.

DNA测序技术的加速进步正在推动为广泛的生物创造前所未有的基因组资源，为挖掘基因组信息提供了黄金机会，这些信息指导着包括发育、衰老、新陈代谢以及学习和记忆在内的生物过程的产生。我的研究计划的长期目标是了解基因组结构变化(即体系结构动态)以及这如何影响基因组表达。该项目的优势建立在我们在线虫分子生物学以及在开发和应用创新生物信息学工具方面的综合经验基础上。我们研究线虫的基因组是因为这个门既包含研究得很好的模式生物秀丽线虫，也包含许多病原体，包括致命的动物(包括人类)和植物寄生虫。这项拟议的研究将在未来5年内解决两个相辅相成的短期目标，旨在从全基因组水平和单基因水平了解基因组表达。 我们的第一个目标是研究基因组结构动力学，以及这种动力学如何定义基因组新颖性和影响基因表达。我们假设，新基因和异构体的形成是形成基因组和表型多样性的驱动力。新的基因可以通过多种机制形成，包括基因的复制、延伸或截断，完全或部分基因之间的融合，以及从头形成。为了识别新的基因，我们将分析线虫菌株(包括参考的N_2菌株和世界各地收集的菌株)以及线虫和布氏线虫(研究最广泛的姊妹种)和其他相关线虫物种之间的基因组差异，然后研究它们对新基因形成的贡献。候选新基因将通过转录组测序和分析(RNA-seq)以及全长cDNA分析进行验证。相比之下，人们对基因的新亚型的形成还没有很好的了解。我们最近对线虫和桥线虫的定量比较RNA-SEQ结果表明，这两个物种的同源基因可能具有截然不同的剪接，这表明形成了新的异构体。新的异构体(以及从头基因)将通过对各种菌株和物种的直接RNA-SEQ分析而被发现。我们将通过计算和实验的方法来评估预测的新基因的功能。 第二个目标是在转录水平上研究基因的表达调控，重点是我们已经克隆和鉴定的线虫纤毛基因MAK/DYF-5的转录调控。Dyf-5是一种保守的基因，广泛存在于包括绿藻、莱茵衣藻和人类在内的多种生物中。Dyf-5功能缺失导致纤毛发育和功能缺陷。我们将进行遗传筛选，以确定影响荧光蛋白tdTomato标记的dyf-5表达的突变体。这些突变的基因将通过遗传图谱、基因组测序和生物信息学分析来鉴定，随后将对它们在Dyf-5精确表达中的功能贡献进行分子研究。我们希望找到与RFX/DAF-19一起发挥作用的共转录因子，RFX/DAF-19是一种转录因子，基本上是所有纤毛基因表达所必需的。 总而言之，对这些目标的研究将揭示创造基因组新颖性和表型多样性的潜在机制，这有助于物种形成的启动。在这项拟议的研究过程中开发的生物信息学工具将极大地促进比较基因组学领域的发展。