Chimera proteins with affinity for membranes and microtubule tips polarize in the membrane of fission yeast cells

Recouvreux, Pierre; Sokolowski, Thomas R.; Γραμμουστιάνου, Αριστέα; Wolde, Pieter Rein ten; Dogterom, Marileen

doi:10.1073/pnas.1419248113

Cited by 10 publications

(6 citation statements)

References 28 publications

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“…Stronger oligomerization reduces the rate at which local asymmetries grow, and the rate at which they approach steady state. This allows external cues that promote local binding [14, 17, 46, 47] or unbinding [48] of polarity factors, or their rapid transport by actomyosin flows [18, 19, 44] to impose spatial asymmetry patterns that are then maintained as quasi-stable states over much longer timescales, and which are no longer dictated by the internal reaction/diffusion kinetics of the polarity circuit. While increasing oligomerization strength to maintain asymmetries far from steady state will also necessarily decrease the rate at which asymmetries grow, this can be readily overcome through the rapid control of local binding/unbinding or transport by external inputs.…”

Section: Discussionmentioning

confidence: 99%

Oligomerization of peripheral membrane proteins provides tunable control of cell surface polarity

Lang

Munro

2022

Preprint

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Asymmetric distributions of peripheral membrane proteins define cell polarity across all kingdoms of life. These asymmetries are shaped by membrane binding, diffusion and transport. Theoretical studies have revealed a general requirement for non-linear positive feedback to spontaneously amplify and/or stabilize asymmetries against dispersion by diffusion and dissociation. But how specific molecular sources of non-linearity shape polarization dynamics remains poorly understood. Here we study how oligomerization of peripheral membrane proteins shapes polarization dynamics in simple feedback circuits. We show that size dependent binding avidity and mobility of membrane bound oligomers endow polarity circuits generically with several key properties. Size-dependent binding avidity confers a form of positive feedback in which the effective rate constant for subunit dissociation decreases with increasing subunit density. This combined with additional weak linear positive feedback is sufficient for spontaneous emergence of stably polarized states. Size-dependent oligomer mobility makes symmetry-breaking and stable polarity more robust with respect to variation in subunit diffusivities and cell sizes, and slows the approach to a final stable spatial distribution, allowing cells to "remember" polarity boundaries imposed by transient external cues. Together, these findings reveal how oligomerization of peripheral membrane proteins can provide powerful and highly tunable sources of non-linear feedback in biochemical circuits that govern cell-surface polarity. Given its prevalence and widespread involvement in cell polarity, we speculate that self-oligomerization may have provided an accessible path to evolving simple polarity circuits.

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Section: Discussionmentioning

confidence: 99%

Oligomerization of peripheral membrane proteins provides tunable control of cell surface polarity

Lang

Munro

2022

Preprint

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“…The role of MT-mediated transport in maintaining cell polarity is well established in fission yeast, where the polarity factors Tea1/Tea4 are transported through association with MT plus-end tracking (+TIPs) proteins such as Mal3 and the kinesin Tea2 to ensure the polar localization of cell growth [ 32 ]. Recently, Recouvreuz et al [ 33 ] have “deconstructed” this system, by using a explicitly engineered chimeric complex using the membrane binding domain of Pom1 coupled to Mal3. This minimal system also displays clear polar enrichment.…”

Section: Discussionmentioning

confidence: 99%

A microtubule-based minimal model for spontaneous and persistent spherical cell polarity

Foteinopoulos

Mulder

2017

PLoS ONE

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We propose a minimal model for the spontaneous and persistent generation of polarity in a spherical cell based on dynamic microtubules and a single mobile molecular component. This component, dubbed the polarity factor, binds to microtubules nucleated from a centrosome located in the center of the cell, is subsequently delivered to the cell membrane, where it diffuses until it unbinds. The only feedback mechanism we impose is that the residence time of the microtubules at the membrane increases with the local density of the polarity factor. We show analytically that this system supports a stable unipolar symmetry-broken state for a wide range of parameters. We validate the predictions of the model by 2D particle-based simulations. Our model provides a route towards the creation of polarity in a minimal cell-like environment using a biochemical reconstitution approach.

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“…As Mod5 presence at the sides of the cell is very low, transfers there are less probable [Minc et al 2000, Snaith andSawin 2003]. We previously showed that an artificial cortical protein that is able to diffuse can form a polarized distribution simply by interactions with microtubule tips in S. pombe [Recouvreux et al 2016]. Therefore, motile receptors, with direct or indirect microtubule binding may facilitate restricting transfers to the poles of the cell.…”

Section: Polarity Establishmentmentioning

confidence: 99%

Motor-mediated clustering at microtubule plus ends facilitates protein transfer to a bio-mimetic cortex

Taberner

Dogterom

2019

Preprint

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Polarized protein distributions at the cortex play an important role in the spatial organization of cells.In S. pombe, growing microtubule ends contribute to the establishment and maintenance of such distributions by delivering specific factors to membrane receptors at the poles of the cell. It is however unclear how microtubule plus-end tracking of proteins favours protein accumulation at the cell cortex compared to proteins arriving directly from the cytoplasm. To address this question, we developed an in vitro assay, where microtubules were made to deliver His-tagged plus-end tracking proteins to functionalized microchamber walls. We found that motor-mediated protein clusters formed at microtubule ends were able to transfer to the walls, but non-clustered proteins were not.We further show that this transfer mechanism leads to preferential cluster accumulation at chamber poles, when microtubules are confined to elongated microfabricated chambers with sizes and shapes similar to S. pombe. may in principle be formed, either based on reaction-diffusion principles and/or dependent on cytoskeletal processes [Vendel et al. 2019], but the exact mechanisms are not yet understood. Here we focus on the principles behind establishment of polarized protein distributions in the model system fission yeast, where dynamic microtubules are essential in targeting cell-end specific factors to the cell poles.

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Chimera proteins with affinity for membranes and microtubule tips polarize in the membrane of fission yeast cells

Cited by 10 publications

References 28 publications

Oligomerization of peripheral membrane proteins provides tunable control of cell surface polarity

Oligomerization of peripheral membrane proteins provides tunable control of cell surface polarity

A microtubule-based minimal model for spontaneous and persistent spherical cell polarity

Motor-mediated clustering at microtubule plus ends facilitates protein transfer to a bio-mimetic cortex

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