细胞信号、细胞接触与酵母群落的组织

Cell signals, cell contacts, and the organization of yeast communities.

作者信息

Honigberg Saul M

机构信息

School of Biological Sciences, University of Missouri, Kansas City, MO 66207, USA.

出版信息

Eukaryot Cell. 2011 Apr;10(4):466-73. doi: 10.1128/EC.00313-10. Epub 2011 Feb 4.

DOI:10.1128/EC.00313-10

PMID:21296916

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3127636/

Abstract

Even relatively simple species have evolved mechanisms to organize individual organisms into communities, such that the fitness of the group is greater than the fitness of isolated individuals. Within the fungal kingdom, the ability of many yeast species to organize into communities is crucial for their growth and survival, and this property has important impacts both on the economy and on human health. Over the last few years, studies of Saccharomyces cerevisiae have revealed several fundamental properties of yeast communities. First, strain-to-strain variation in the structures of these groups is attributable in part to variability in the expression and functions of adhesin proteins. Second, the extracellular matrix surrounding these communities can protect them from environmental stress and may also be important in cell signaling. Finally, diffusible signals between cells contribute to community organization so that different regions of a community express different genes and adopt different cell fates. These findings provide an arena in which to view fundamental mechanisms by which contacts and signals between individual organisms allow them to assemble into functional communities.

摘要

即使是相对简单的物种也进化出了将个体生物组织成群落的机制，从而使群体的适应性大于孤立个体的适应性。在真菌界，许多酵母物种组织成群落的能力对其生长和生存至关重要，这一特性对经济和人类健康都有重要影响。在过去几年中，对酿酒酵母的研究揭示了酵母群落的几个基本特性。首先，这些群体结构中的菌株间差异部分归因于粘附素蛋白表达和功能的变异性。其次，围绕这些群落的细胞外基质可以保护它们免受环境压力，并且在细胞信号传导中可能也很重要。最后，细胞间的可扩散信号有助于群落组织，从而使群落的不同区域表达不同的基因并采用不同的细胞命运。这些发现提供了一个视角，从中可以观察个体生物之间的接触和信号使它们组装成功能群落的基本机制。

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