Dynamic Opposition of Clustered Proteins Stabilizes Cortical Polarity in the C. elegans Zygote

Sailer, Anne; Anneken, Alexander; Li, Younan; Lee, Sam; Munro, Edwin

doi:10.1016/j.devcel.2015.09.006

Cited by 81 publications

(164 citation statements)

References 58 publications

(90 reference statements)

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“…Prior studies have suggested that PAR-3 oligomerization may contribute to maintenance of stable PAR domains during polarity maintenance phase (Dawes and Munro, 2011; Sailer et al, 2015). However, we observed that the largest PAR-3 oligomers were present during establishment phase rather than maintenance phase (Figure 3B).…”

Section: Resultsmentioning

confidence: 99%

A Single-Cell Biochemistry Approach Reveals PAR Complex Dynamics during Cell Polarization

et al. 2017

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Summary Regulated protein-protein interactions are critical for cell signaling, differentiation and development. To study dynamic regulation of protein interactions in vivo, there is a need for techniques that can yield time-resolved information and probe multiple protein binding partners simultaneously, using small amounts of starting material. Here, we describe a single-cell protein interaction assay. Single-cell lysates are generated at defined timepoints and analyzed using single-molecule pull-down, yielding information about dynamic protein complex regulation in vivo. We established the utility of this approach by studying PAR polarity proteins, which mediate polarization of many animal cell types. We uncovered striking regulation of PAR complex composition and stoichiometry during C. elegans zygote polarization, which takes place in less than 20 minutes. PAR complex dynamics are linked to the cell cycle by polo-like kinase 1, and govern movement of PAR proteins to establish polarity. Our results demonstrate an approach to study dynamic biochemical events in vivo.

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Section: Resultsmentioning

confidence: 99%

A Single-Cell Biochemistry Approach Reveals PAR Complex Dynamics during Cell Polarization

et al. 2017

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“…The PAR domains are persistent in the polarized zygote even though individual PAR proteins undergo both lateral diffusion within the cortex and continual exchange between the cortex and the cytoplasm (Cheeks et al, 2004; Goehring et al, 2011a; Nakayama et al, 2009; Robin et al, 2014; Sailer et al, 2015). The maintenance of stable PAR domains depends on a combination of mechanisms that control where they are recruited to the cell cortex and that counteract their lateral diffusion within the cortex.…”

Section: Asymmetric Division Of the C Elegans Zygotementioning

confidence: 99%

“…During polarity maintenance, the recruitment of PAR-6/aPKC from the cytoplasm to the cortex depends on interactions with both PAR-3 and the active form of the small GTPase, CDC42 (Aceto et al, 2006; Gotta et al, 2001; Kay and Hunter, 2001). Both PAR-3 and active CDC42 are concentrated at the anterior cortex, resulting in PAR-6 cortical recruitment rates that are ~9 times higher in the anterior than the posterior cortex (Sailer et al, 2015). This dramatic asymmetry in cortical PAR-6 recruitment depends on two mechanisms that prevent PAR-3 and active CDC42 from localizing to the posterior cortex (Figure 2A).…”

Section: Asymmetric Division Of the C Elegans Zygotementioning

confidence: 99%

“…This dramatic asymmetry in cortical PAR-6 recruitment depends on two mechanisms that prevent PAR-3 and active CDC42 from localizing to the posterior cortex (Figure 2A). One mechanism relies on the phosphorylation of PAR-3 by PAR-1, which excludes PAR-3 from the posterior cortex (discussed above) (Sailer et al, 2015). The second mechanism depends on CHIN-1, a posteriorly enriched CDC42 GAP that inactivates CDC42 in the posterior (Beatty et al, 2013; Kumfer et al, 2010; Sailer et al, 2015).…”

Section: Asymmetric Division Of the C Elegans Zygotementioning

confidence: 99%

“…One mechanism relies on the phosphorylation of PAR-3 by PAR-1, which excludes PAR-3 from the posterior cortex (discussed above) (Sailer et al, 2015). The second mechanism depends on CHIN-1, a posteriorly enriched CDC42 GAP that inactivates CDC42 in the posterior (Beatty et al, 2013; Kumfer et al, 2010; Sailer et al, 2015). The presence of either one of these mechanisms is sufficient to prevent PAR-6 recruitment to the posterior cortex.…”

Section: Asymmetric Division Of the C Elegans Zygotementioning

confidence: 99%

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Regulation of Cell Polarity by PAR-1/MARK Kinase

Griffin

2017

Current Topics in Developmental Biology

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PAR-1/MARK kinases are conserved serine/threonine kinases that are essential regulators of cell polarity. PAR-1/MARK kinases localize and function in opposition to the Anterior PAR proteins to control the asymmetric distribution of factors in a wide variety polarized cells. In this review, we discuss the mechanisms that control the localization and activity of PAR-1/MARK kinases, including their antagonistic interactions with the Anterior PAR proteins. We focus on the role PAR-1 plays in the asymmetric division of the C. elegans zygote, in the establishment of the anterior/posterior axis in the Drosophila oocyte and in the control of microtubule dynamics in mammalian neurons. In addition to conserved aspects of PAR-1 biology, we highlight the unique ways in which PAR-1 acts in these distinct cell types to orchestrate their polarization. Finally, we review the connections between disruptions in PAR-1/MARK function and Alzheimer’s disease and cancer.

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Asymmetric Cell Division in the One-Cell C. elegans Embryo: Multiple Steps to Generate Cell Size Asymmetry

Pacquelet

2017

Results and Problems in Cell Differentiation

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The first division of the one-cell C. elegans embryo has been a fundamental model in deciphering the mechanisms underlying asymmetric cell division. Polarization of the one-cell zygote is induced by a signal from the sperm centrosome and results in the asymmetric distribution of PAR proteins. Multiple mechanisms then maintain PAR polarity until the end of the first division. Once asymmetrically localized, PAR proteins control several essential aspects of asymmetric division, including the position of the mitotic spindle along the polarity axis. Coordination of the spindle and cytokinetic furrow positions is the next essential step to ensure proper asymmetric division. In this chapter, I review the different mechanisms underlying these successive steps of asymmetric division. Work from the last 30 years has revealed the existence of multiple and redundant regulatory pathways which ensure division robustness. Besides the essential role of PAR proteins, this work also emphasizes the importance of both microtubules and actomyosin throughout the different steps of asymmetric division.

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Dynamic Opposition of Clustered Proteins Stabilizes Cortical Polarity in the C. elegans Zygote

Cited by 81 publications

References 58 publications

A Single-Cell Biochemistry Approach Reveals PAR Complex Dynamics during Cell Polarization

A Single-Cell Biochemistry Approach Reveals PAR Complex Dynamics during Cell Polarization

Regulation of Cell Polarity by PAR-1/MARK Kinase

Asymmetric Cell Division in the One-Cell C. elegans Embryo: Multiple Steps to Generate Cell Size Asymmetry

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