盘状盘骨:社会性阿米巴。

CSH protocols Pub Date : 2008-12-01 DOI:10.1101/pdb.emo109
Pascale Gaudet, Petra Fey, Rex Chisholm
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引用次数: 8

摘要

盘状盘基骨柱是一种单细胞真核生物,通常被称为“社会性变形虫”,因为当营养条件有限时,它可以形成多细胞结构。盘状盘齿龙及其相关生物,即盘齿钢索菌,已经被研究了近150年。它们的多细胞生活方式的细胞和分子方面已经被详细研究,细胞间通讯、细胞内信号传导和细胞运动过程中的细胞骨架组织的一般原理已经从这项工作中衍生出来,并被发现在所有真核生物中都是保守的。单细胞阶段的细菌性为研究吞噬作用和细菌毒力机制提供了一个很好的模型。盘状棘球绦虫还被成功地用于探索各种人类疾病的分子基础,以及药物作用机制和导致对某些治疗剂产生耐药性的途径。完整基因组序列的可用性进一步扩大了利用盘状棘球蚴进行研究的范围。次生代谢的巨大潜力已经变得明显,这为发现具有潜在医学应用的新化合物打开了大门。许多被认为与人类疾病有关的基因的同源物,但其分子功能仍未被表征,存在于盘状棘球绦虫基因组中。最后,社区资源的可用性,包括基因组数据库dictyBase和Dicty Stock Center,使盘状棘球蚴成为一个容易获取和强大的模式生物进行研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dictyostelium discoideum: The Social Ameba.

INTRODUCTIONDictyostelium discoideum is a unicellular eukaryote often referred to as a "social ameba" because it can form a multicellular structure when nutrient conditions are limiting. D. discoideum and related organisms, known as the Dictyostelia, have been studied for almost 150 years. The cellular and molecular aspects of their multicellular lifestyle have been studied in detail, and general principles for cell-to-cell communication, intracellular signaling, and cytoskeletal organization during cell motility have been derived from this work and have been found to be conserved across all eukaryotes. The bacteriovore nature of the unicellular stage provides an excellent model in which to study phagocytosis and the mechanisms of bacterial virulence. D. discoideum has also been used successfully to explore the molecular basis of various human diseases, as well as the mechanisms of drug action and the pathways that lead to resistance to certain therapeutic agents. The availability of a complete genome sequence has further widened the scope of studies using D. discoideum. A large potential for secondary metabolism has become apparent, which opens the door to discovering new compounds with potential medical applications. Numerous putative orthologs of genes responsible for diseases in humans, but whose molecular functions are still uncharacterized, are present in the D. discoideum genome. Finally, the availability of community resources, including the genome database dictyBase and the Dicty Stock Center, makes D. discoideum an easily accessible and powerful model organism to study.

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