热带爪蟾作为遗传学和基因组学的模式生物：过去、现在与未来

Xenopus tropicalis as a model organism for genetics and genomics: past, present, and future.

作者信息

Grainger Robert M

机构信息

Department of Biology, University of Virginia, Charlottesville, VA, USA.

出版信息

Methods Mol Biol. 2012;917:3-15. doi: 10.1007/978-1-61779-992-1_1.

DOI:10.1007/978-1-61779-992-1_1

PMID:22956079

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3918953/

Abstract

Xenopus tropicalis was introduced as a model system for genetic, and then genomic research, in the early 1990s, complementing work on the widely used model organism Xenopus laevis. Its shorter generation time and diploid genome has facilitated a number of experimental approaches. It has permitted multigenerational experiments (e.g., preparation of transgenic lines and generation of mutant lines) that have added powerful approaches for research by the Xenopus community. As a diploid animal, its simpler genome was sequenced before X. laevis, and has provided a highly valuable resource indispensable for all Xenopus researchers. As more sophisticated transgenic technologies for manipulating gene expression are developed, and mutations, particularly null mutations, are identified in widely studied genes involved in critical cellular and developmental processes, researchers will increasingly turn to X. tropicalis for definitive analysis of complex genetic pathways. This chapter describes the historical and conceptual development of X. tropicalis as a genetic and genomic model system for higher vertebrate development.

摘要

热带爪蟾于20世纪90年代初被引入作为遗传研究，随后是基因组研究的模型系统，作为对广泛使用的模式生物非洲爪蟾研究工作的补充。其较短的世代时间和二倍体基因组促进了多种实验方法的开展。它使得多代实验（例如，转基因品系的制备和突变品系的产生）得以进行，这些实验为爪蟾研究群体增加了强大的研究方法。作为二倍体动物，其更简单的基因组在非洲爪蟾之前就已测序，为所有爪蟾研究人员提供了一种不可或缺的极有价值的资源。随着用于操纵基因表达的更复杂转基因技术的发展，以及在参与关键细胞和发育过程的广泛研究基因中鉴定出突变，特别是无效突变，研究人员将越来越多地转向热带爪蟾，以对复杂的遗传途径进行确定性分析。本章描述了热带爪蟾作为高等脊椎动物发育的遗传和基因组模型系统的历史和概念发展。

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