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EphA4信号通过招募Pak1抑制Cdc42功能来调节非洲爪蟾胚胎中的卵裂球黏附。

EphA4 signaling regulates blastomere adhesion in the Xenopus embryo by recruiting Pak1 to suppress Cdc42 function.

作者信息

Bisson Nicolas, Poitras Luc, Mikryukov Alexander, Tremblay Michel, Moss Tom

机构信息

Cancer Research Centre, Department of Medical Biology, Laval University, Hôtel-Dieu de Québec, Québec, G1R 2J6 Québec, Canada.

出版信息

Mol Biol Cell. 2007 Mar;18(3):1030-43. doi: 10.1091/mbc.e06-04-0294. Epub 2007 Jan 10.

DOI:10.1091/mbc.e06-04-0294

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1805096/

Abstract

The control of cell adhesion is an important mechanism by which Eph receptors regulate cell sorting during development. Activation of EphA4 in Xenopus blastulae induces a reversible, cell autonomous loss-of-adhesion and disruption of the blastocoel roof. We show this phenotype is rescued by Nckbeta (Grb4) dependent on its interaction with EphA4. Xenopus p21(Cdc42/Rac)-activated kinase xPAK1 interacts with Nck, is activated in embryo by EphA4 in an Nck-dependent manner, and is required for EphA4-induced loss-of-adhesion. Ectopic expression of xPAK1 phenocopies EphA4 activation. This does not require the catalytic activity of xPAK1, but it does require its GTPase binding domain and is enhanced by membrane targeting. Indeed, membrane targeting of the GTPase binding domain (GBD) of xPAK1 alone is sufficient to phenocopy EphA4 loss-of-adhesion. Both EphA4 and the xPAK1-GBD down-regulate RhoA-GTP levels, and consistent with this, loss-of-adhesion can be rescued by activated Cdc42, Rac, and RhoA and can be epistatically induced by dominant-negative RhoA. Despite this, neither Cdc42 nor Rac activities are down-regulated by EphA4 activation or by the xPAK1-GBD. Together, the data suggest that EphA4 activation sequesters active Cdc42 and in this way down-regulates cell-cell adhesion. This novel signaling pathway suggests a mechanism for EphA4-guided migration.

摘要

细胞黏附的控制是Eph受体在发育过程中调节细胞分选的重要机制。非洲爪蟾囊胚中EphA4的激活诱导了一种可逆的、细胞自主的黏附丧失以及囊胚腔顶的破坏。我们发现这种表型可被依赖于其与EphA4相互作用的Nckbeta（Grb4）挽救。非洲爪蟾p21（Cdc42/Rac）激活的激酶xPAK1与Nck相互作用，在胚胎中被EphA4以Nck依赖的方式激活，并且是EphA4诱导的黏附丧失所必需的。xPAK1的异位表达模拟了EphA4的激活。这不需要xPAK1的催化活性，但需要其GTP酶结合结构域，并且通过膜靶向作用增强。实际上，单独xPAK1的GTP酶结合结构域（GBD）的膜靶向作用就足以模拟EphA4的黏附丧失。EphA4和xPAK1-GBD都下调RhoA-GTP水平，与此一致的是，激活的Cdc42、Rac和RhoA可以挽救黏附丧失，并且显性负性RhoA可以上位性诱导黏附丧失。尽管如此，EphA4激活或xPAK1-GBD都不会下调Cdc42或Rac的活性。总之，数据表明EphA4激活隔离了活性Cdc42，从而下调细胞间黏附。这条新的信号通路提示了EphA4引导迁移的一种机制。