High-throughput Gene Knockout Production in Tetrahymena thermophila

嗜热四膜虫的高通量基因敲除生产

• 批准号: 8118468
• 负责人: Robert Stephen Coyne
• 金额: $ 36.8万
• 依托单位: J. CRAIG VENTER INSTITUTE, INC.
• 依托单位国家: 美国
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-09-01 至 2013-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8118468
• 关键词: Aging; Animal Model; Area; Basic Science; Biological; Biomedical Research; Chromosomes; Code; Collection; Communities; DNA biosynthesis; Disease; Escherichia coli; Essential Genes; Experimental Models; Future; Gene Family; Generations; Genes; Genetic; Genome; Germline Micronucleus; Goals; Health; Homologous Gene; Human; Investigation; Knock-out; Knowledge; Laboratories; Link; Maintenance; Malignant Neoplasms; Methods; Modeling; Mutation; Orthologous Gene; Partner in relationship; Process; Production; Proteins; RNA Interference; RNA Splicing; Research; Research Personnel; Resources; Source; Telomerase; Tetrahymena; Tetrahymena thermophila; Transcriptional Regulation; Yeasts; base; chromatin modification; gene replacement; genome sequencing; histone modification; interest; knockout gene; public health relevance; telomere; tool

DESCRIPTION (provided by applicant): The specific aims of this project are to generate E. coli clones containing gene replacement mutations in approximately 1,300 protein-coding genes of Tetrahymena thermophila and to transform these clones into the Tetrahymena germline genome to generate knockout strains. The clones and strains will be cryogenically preserved and made freely available to any interested researcher. This resource will greatly facilitate the efforts of an active research community using this model organism and attract new investigators to its study. Tetrahymena has been studied in the laboratory for nearly a century and has contributed to many discoveries of fundamental importance in basic and biomedical research. Prominent areas of investigation include chromatin modification, RNA interference, telomere formation and maintenance, cytoskeletal dynamics, secretion, and DNA replication, amplification and elimination. The availability of whole genome sequence and annotation information has opened up new fields of investigation and attracted new researchers to this model. Tetrahymena has retained many ancestral eukaryotic genetic functions that have been lost in other unicellular model organisms, such as yeast. Many of these genes have human orthologs that are disease- associated. Because Tetrahymena undergoes exclusively homologous gene replacement, many of these genes have been studied by creating knockouts. A unique advantage of Tetrahymena for such analyses is that knockouts of essential genes can be maintained in the transcriptionally silent germline micronucleus and brought into expression by a simple mating. However, the generation of knockout constructs and strains has thus far proceeded on an inefficient, gene-by-gene basis that has hindered the progress of Tetrahymena research and precluded investigation of larger gene families. By optimizing and centralizing this process, we intend to overcome this hurdle for the long-term enhancement of the capabilities of the Tetrahymena research community. A large number of researchers have expressed enthusiasm for this high throughput project and identified numerous knockout targets of particular interest. The knockout strains will be transferred to the Tetrahymena Stock Center and made available to all investigators. The methods developed will serve as a model for future efforts to generate a complete set of Tetrahymena knockout strains. PUBLIC HEALTH RELEVANCE: Research with the simple model organism Tetrahymena has contributed to our understanding of several fundamental processes, such as how chromosome ends replicate; that particular study advanced studies of aging and cancer. Numerous other basic studies with far-reaching relevance to human health would be facilitated by the availability of the proposed freely available resource.

描述（由申请人提供）：本项目的具体目标是产生E。在嗜热四膜虫的约1，300个蛋白质编码基因中含有基因置换突变的大肠杆菌克隆，并将这些克隆转化到四膜虫种系基因组中以产生敲除菌株。克隆和菌株将被低温保存，并免费提供给任何感兴趣的研究人员。这一资源将极大地促进一个活跃的研究社区使用这种模式生物的努力，并吸引新的研究人员对其进行研究。四膜虫已经在实验室研究了近世纪，并在基础和生物医学研究中做出了许多重要发现。主要研究领域包括染色质修饰、RNA干扰、端粒形成和维持、细胞骨架动力学、分泌和DNA复制、扩增和消除。全基因组序列和注释信息的可用性开辟了新的研究领域，并吸引了新的研究人员到这个模型。四膜虫保留了许多在其他单细胞模式生物（如酵母）中丢失的祖先真核生物遗传功能。这些基因中的许多具有与疾病相关的人类直系同源物。由于四膜虫经历了完全同源的基因替换，许多这些基因已经通过创建敲除进行了研究。四膜虫的一个独特的优势，这样的分析是，敲除的必要基因可以保持在转录沉默的生殖细胞微核，并通过一个简单的交配进入表达。然而，迄今为止，敲除构建体和菌株的产生是在低效的、逐个基因的基础上进行的，这阻碍了四膜虫研究的进展，并排除了对更大基因家族的研究。通过优化和集中这一过程，我们打算克服这一障碍，长期提高四膜虫研究界的能力。大量的研究人员表达了对这个高通量项目的热情，并确定了许多特别感兴趣的敲除靶标。敲除菌株将被转移到四膜虫库存中心，并提供给所有研究人员。开发的方法将作为未来努力产生一套完整的四膜虫敲除菌株的模型。 公共卫生关系：对简单模式生物四膜虫的研究有助于我们理解几个基本过程，例如染色体末端如何复制;这项特别的研究推进了对衰老和癌症的研究。拟议的免费资源的提供将促进对人类健康具有深远意义的许多其他基础研究。