Cullen Paul J
Department of Biological Sciences, State University of New York at Buffalo, Buffalo, New York 14260.
Cold Spring Harb Protoc. 2015 Mar 2;2015(3):235-8. doi: 10.1101/pdb.top077495.
In response to nutrient limitation, budding yeast can undergo filamentous growth by differentiating into elongated chains of interconnected cells. Filamentous growth is regulated by signal transduction pathways that oversee the reorganization of cell polarity, changes to the cell cycle, and an increase in cell adhesion that occur in response to nutrient limitation. Each of these changes can be easily measured. Yeast can also grow colonially atop surfaces in a biofilm or mat of connected cells. Filamentous growth and biofilm/mat formation require cooperation among individuals; therefore, studying these responses can shed light on the origin and genetic basis of multicellular behaviors. The assays introduced here can be used to study analogous behaviors in other fungal species, including pathogens, which require filamentous growth and biofilm/mat formation for virulence.
作为对营养限制的响应,出芽酵母可通过分化为相互连接的细胞组成的细长链来进行丝状生长。丝状生长由信号转导通路调控,这些通路负责监督细胞极性的重组、细胞周期的变化以及因营养限制而发生的细胞黏附增加。这些变化中的每一个都可以很容易地进行测量。酵母还可以在生物膜或相连细胞的垫子表面以群体形式生长。丝状生长以及生物膜/垫子的形成需要个体之间的协作;因此,研究这些反应可以揭示多细胞行为的起源和遗传基础。这里介绍的检测方法可用于研究其他真菌物种中的类似行为,包括那些需要丝状生长和生物膜/垫子形成来实现毒力的病原体。