Negative Feedback and Competition in the Yeast Polarity Establishment Circuit

Wu, Chi-Fang

January 2013

<p>Many cells spontaneously establish a polarity axis even in the absence of directional cues, a process called symmetry breaking. A central question concerns how cells polarize towards one, and only one, randomly oriented "front". The conserved Rhotype GTPase Cdc42p is an essential factor for both directed and spontaneous polarization in various organisms, whose local activation is thought to define the cell's front. We previously proposed that in yeast cells, a small stochastic cluster of GTP-Cdc42p at a random site on the cortex can grow into a large, dominating cluster via a positive feedback loop involving the scaffold protein Bem1p. As stochastic Cdc42p clusters could presumably arise at many sites, why does only one site become the dominating "front"? We speculated that competition between growing clusters for limiting factors would lead to growth of a single winning "front" at the expense of the others. Utilizing time-lapse imaging with high spatiotemporal resolution, we now document initiation of multiple polarized clusters that competed rapidly to resolve a winning cluster. Such multicluster intermediates are observed in wild-type yeast cells with functional directional cues, but the locations where they are initiated are biased by the spatial cues. In addition, we detected an unexpected oscillatory polarization in a majority of the cells breaking symmetry, in which polarity factors initially concentrated very brightly and then dimmed in an oscillatory manner, dampening down to a final intermediate level after 2-3 peaks. Dampened oscillation suggests that the polarity circuit contains an in-built negative feedback loop. Mathematical modeling predicts that negative feedback would confer robustness to the polarity circuit and make the kinetics of competition between polarity factor clusters relatively insensitive to polarity factor concentration.</p><p>We are trying to understand how competition between clusters occurs. We find that the yeast guanine-nucleotide dissociation inhibitor (GDI), Rdi1p, is needed for rapid competition between clusters. In the absence of Rdi1p the initial clustering of polarity</p><p>factors is slowed, and competition is also much slower: in some cases cells still have two clusters at the time of bud emergence and they form two buds. We suggest that in the absence of Rdi1p, the clusters compete for a limiting pool of Cdc42p, and that slow</p><p>exchange of Cdc42p on and off the membrane in the absence of Rdi1p leads to slow competition.</p> / Dissertation

Cellular biology

Genetics

bud-site selection

Cdc42

GDI

Negative feedback

Polarity

yeast

OVERT AND LATENT PATHWAYS OF POLARITY SPECIFICATION IN ZYGOTES: THE HAPLOID-TO-DIPLOID TRANSITION

Rinonos, Serendipity Zapanta

08 March 2013

No description available.

Cellular Biology

Molecular Biology

polarity specification

cell polarity

yeast polarity

bud site selection

zygotes

budding yeast

Regulation of Cell Polarity in the Budding Yeast <i>Saccharomyces cerevisiae</i> / Die Regulation der Zellpolarität in der Bäckerhefe <i>Saccharomyces cerevisiae</i>

Taheri Talesh, Naimeh

31 October 2002

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Zellpolarität

bipolare Sprossung

Sprosswahl

Pseudohyphen

Zellpolprotein

Bud8p und Bud9p

distale und proximale Sprossung

Cell Polarity

Bipolar Budding

Bud Site Selection

Pseudohyphae

Spatial Landmark

Bud8p and Bud9p

Distal and Proximal Budding Pattern

42.13 Molekularbiologie