酵母的趋化性:化学梯度传感的范式转变。

Cellular logistics Pub Date : 2017-04-11 eCollection Date: 2017-01-01 DOI:10.1080/21592799.2017.1314237
Amber Ismael, David E Stone
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引用次数: 8

摘要

细胞根据浅层化学梯度指示其运动和生长的能力在所有真核生物的生命周期中都是必不可少的。趋化细胞定向传感的信号机制已经得到了很好的研究;然而,对于趋化细胞如何解释化学梯度,人们知之甚少。最近对出芽酵母和分裂酵母趋化性的研究揭示了两种截然不同的机制——极性复合物的偏性漂移和受体和G蛋白的差异内化。这些机制都被认为在解码交配信息素梯度中起着关键作用。在这里,我们将探讨它们如何作为一个梯度传感机器的两个重要组成部分一起工作。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Yeast chemotropism: A paradigm shift in chemical gradient sensing.

The ability of cells to direct their movement and growth in response to shallow chemical gradients is essential in the life cycles of all eukaryotic organisms. The signaling mechanisms underlying directional sensing in chemotactic cells have been well studied; however, relatively little is known about how chemotropic cells interpret chemical gradients. Recent studies of chemotropism in budding and fission yeast have revealed 2 quite different mechanisms-biased wandering of the polarity complex, and differential internalization of the receptor and G protein. Each of these mechanisms has been proposed to play a key role in decoding mating pheromone gradients. Here we explore how they may work together as 2 essential components of one gradient sensing machine.

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