The Coordination of Cell Growth during Fission Yeast Mating Requires Ras1-GTP Hydrolysis

Weston, Cathryn; Bond, Michael; Croft, Wayne; Ladds, Graham

doi:10.1371/journal.pone.0077487

Cited by 17 publications

(37 citation statements)

References 53 publications

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“…Indeed, deletion of Gap1, the predicted GTPase activating protein (GAP) for Ras1 [39, 40], caused an important increase in zone lifetime: heterothallic gap1Δ M-cells lacking the P-factor protease Sxa2 exposed to homogeneous P-factor (0.01 to 1μM) displayed dynamic Scd2 zones, but these exhibited significantly longer lifetimes than gap1+ controls exposed to the same pheromone concentrations (Figure 4C). Some of these cells also lysed, as previously reported [40]. Thus, Ras inactivation promotes polarity zone disassembly.…”

Section: Resultsmentioning

confidence: 99%

Local Pheromone Release from Dynamic Polarity Sites Underlies Cell-Cell Pairing during Yeast Mating

et al. 2016

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Summary Cell pairing is central for many processes, including immune defense, neuronal connection, hyphal fusion or sexual reproduction. How does a cell orient towards a partner, especially when faced with multiple choices? Fission yeast Schizosaccharomyces pombe P- and M-cells, which respectively express P- and M-factor pheromones [1, 2], pair during the mating process induced by nitrogen starvation. Engagement of pheromone receptors Map3 and Mam2 [3, 4] with their cognate pheromone ligands leads to activation of the Gα-protein Gpa1 to signal sexual differentiation [3, 5, 6]. Prior to cell pairing, the Cdc42 GTPase, a central regulator of cell polarization, forms dynamic zones of activity at the cell periphery at distinct locations over time [7]. Here, we show that Cdc42-GTP polarization sites contain the M-factor transporter Mam1, the general secretion machinery, which underlies P-factor secretion, and Gpa1, suggesting these are sub-cellular zones of pheromone secretion and signaling. Zone lifetimes scale with pheromone concentration. Computational simulations of pair formation through a fluctuating zone show that the combination of local pheromone release and sensing, short pheromone decay length, and pheromone-dependent zone stabilization leads to efficient pair formation. Consistently, pairing efficiency is reduced in absence of the P-factor protease. Similarly, zone stabilization at reduced pheromone levels, which occurs in absence of the predicted GTPase-activating protein for Ras, leads to reduction in pairing efficiency. We propose that efficient cell pairing relies on a fluctuating local signal emission and perception, which become locked into place through stimulation.

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Section: Resultsmentioning

confidence: 99%

Local Pheromone Release from Dynamic Polarity Sites Underlies Cell-Cell Pairing during Yeast Mating

et al. 2016

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“…However, while deletion of both Scd1 and Gef1 is lethal (Coll et al, 2003), we noticed that cells lacking scd2 and gef1 are viable ( Fig S1A) which suggested that other mechanisms for Scd1 recruitment and/or activation exist. Several pieces of data implicated the small GTPase Ras1 as positive regulator of Cdc42 acting upstream of Scd1 (Chang et al, 1994;Merlini et al, 2016;Weston et al, 2013). Indeed, we find that ras1 is required for viability of scd2Δ gef1Δ double mutant cells (Tables S1-S2), but not gef1Δ nor scd2Δ single mutants ( Fig S1B-C).…”

Section: Ras1 Cooperates With Scd2 For Scd1 Recruitment To Cell Polesmentioning

confidence: 60%

“…Notably, scd2 deletion causes cell rounding (Chang et al, 1994;Kelly and Nurse, 2011b) but does not severely affect Cdc42 activity, in contrast to scd1∆ , implying the existence of alternative mechanisms for Cdc42 activation. Several pieces of data implicate the small GTPase Ras1 as a Cdc42 regulator upstream of Scd1 (Chang et al, 1994;Merlini et al, 2018;Weston et al, 2013): Ras1 binds Scd1 directly (Chang et al, 1994), is localized to the plasma membrane and activated at the cell ends like Cdc42 , and its deletion causes partial cell rounding (Fukui et al, 1986).…”

Section: Introductionmentioning

confidence: 99%

Optogenetics reveals Cdc42 local activation by scaffold-mediated positive feedback and Ras GTPase

Lamas

Merlini

Vještica

et al. 2019

Preprint

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The small GTPase Cdc42 is critical for cell polarization. Scaffold-mediated positive feedback regulation was proposed to mediate symmetry-breaking to a single active zone in budding yeast cells. In rod-shaped fission yeast S. pombe cells, active Cdc42-GTP localizes to both cell poles, where it promotes bipolar growth. Here, we implement the CRY2-CIBN optogenetic system for acute light-dependent protein recruitment to the plasma membrane, which allowed to directly demonstrate positive feedback. Indeed, optogenetic recruitment of constitutively active Cdc42 leads to co-recruitment of the GEF Scd1, in a manner dependent on the scaffold protein Scd2. We show that Scd2 function is completely bypassed and positive feedback restored by an engineered interaction between the GEF and a Cdc42 effector, the Pak1 kinase. Remarkably, such re-wired cells are viable and grow in a bipolar manner even when lacking otherwise essential Cdc42 activators.Interestingly, these cells reveal that Ras1 GTPase plays a dual role in localizing and activating the GEF, thus potentiating the feedback. We conclude that scaffoldmediated positive feedback, gated by Ras activity, is minimally required for rodshape formation.

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“…Studies based on recombinant protein assays and yeast-2-hybrid analysis demonstrated 87 that Ras1 interacts with both MAPKKK Byr2 and Scd1, a GDP-GTP exchange factor (GEF) for Cdc42, 88 which regulates the actin cytoskeleton and cell morphology (Chang et al, 1994; Gronwald et al, 89 2001;Tu et al, 1997). These observations suggest that Ras1 simultaneously regulates both the 90 pheromone MAPK Spk1 and the Cdc42 pathways at the cell membrane (Weston et al, 2013). 91Indeed, a dynamic "Cdc42 zone" at the cell cortex prior to mating has been observed (Merlini et 92 al., 2013) and Ras1 and MAPK Spk1 cascade components are found there and are involved in the 93 process (Dudin et al, 2016;Merlini et al, 2013;Merlini et al, 2016;Merlini et al, 2018; Weston 94 et al, 2013).…”

mentioning

confidence: 99%

mentioning

confidence: 99%

Constitutively active RAS in S. pombe causes persistent Cdc42 signalling but only transient MAPK activation

Kelsall

Vértesy

Straatman

et al. 2018

Preprint

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Highlights 19(1) Constitutively active Ras1.GV prolongs Cdc42 activation in S. pombe pheromone signalling 20(2) Ras1.GV results in an immediate but only transient MAPK Spk1 activation 21(3) The RAS effector pathways MAPK Spk1 and Cdc42 compete with each other for active Ras1 22 (4) Predictive modelling explains MAPK Spk1 activation dynamics in 24 signaling-mutants 23 24 eTOC Blurb 25 S. pombe Ras1 activates the MAPK Spk1 and Cdc42 pathways. Kelsall et al. report that the 26 constitutively active Ras1.G17V mutation, which causes morphological anomalies, induces 27 prolonged Cdc42 activation but only a transient MAPK Spk1 activation followed by attenuation. 28 Mathematical modelling and biochemical data suggest a competition between the MAPK Spk1 and 29 Cdc42 pathways for active Ras1. 30 31 Summary 32 33 The small GTPase RAS is a signalling hub for many pathways and oncogenic human RAS 34 mutations are assumed to over-activate all of its downstream pathways. We tested this 35 assumption in fission yeast, where, RAS-mediated pheromone signalling (PS) activates the 36 MAPK Spk1 and Cdc42 pathways. Unexpectedly, we found that constitutively active Ras1.G17V 37 induced immediate but only transient MAPK Spk1 activation, whilst Cdc42 activation persisted. 38 Immediate but transient MAPK Spk1 activation was also seen in the deletion mutant of Cdc42-39 GEF Scd1 , a Cdc42 activator. We built a mathematical model using PS negative-feedback circuits 40 and competition between the two Ras1 effectors, MAPKKK Byr2 and Cdc42-GEF Scd1 . The model 41 robustly predicted the MAPK Spk1 activation dynamics of an additional 21 PS mutants. Supporting 42 the model, we showed that a recombinant Cdc42-GEF Scd1 fragment competes with MAPKKK Byr2 43 for Ras1 binding. Our study has established a concept that the constitutively active RAS 44 propagates differently to downstream pathways where the system prevents MAPK 45 overactivation. 46 47 Key words 48 Ras, MAPK, Cdc42/Rac, yeast pheromone signalling 49 50 Ras1 also regulates cell morphology during vegetative growth; whilst deletion of either gpa1, 83 MAPKKK byr2 , MAPKK byr1 or MAPK spk1 does not result in any obvious phenotypes during vegetative 84 cell growth (Obara et al., 1991;Sipiczki, 1988;Toda et al., 1991), ras1 cells lose the typical rod-85 shape morphology of fission yeast to become rounded (Fukui et al., 1989; Nadin-Davis et al., 86 1986a). Studies based on recombinant protein assays and yeast-2-hybrid analysis demonstrated 87 that Ras1 interacts with both MAPKKK Byr2 and Scd1, a GDP-GTP exchange factor (GEF) for Cdc42, 88 which regulates the actin cytoskeleton and cell morphology (Chang et al., 1994; Gronwald et al., 89 2001;Tu et al., 1997). These observations suggest that Ras1 simultaneously regulates both the 90 pheromone MAPK Spk1 and the Cdc42 pathways at the cell membrane (Weston et al., 2013). 91Indeed, a dynamic "Cdc42 zone" at the cell cortex prior to mating has been observed (Merlini et 92 al., 2013) and Ras1 and MAPK Spk1 cascade components are found there ...

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The Coordination of Cell Growth during Fission Yeast Mating Requires Ras1-GTP Hydrolysis

Cited by 17 publications

References 53 publications

Local Pheromone Release from Dynamic Polarity Sites Underlies Cell-Cell Pairing during Yeast Mating

Local Pheromone Release from Dynamic Polarity Sites Underlies Cell-Cell Pairing during Yeast Mating

Optogenetics reveals Cdc42 local activation by scaffold-mediated positive feedback and Ras GTPase

Constitutively active RAS in S. pombe causes persistent Cdc42 signalling but only transient MAPK activation

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