Multisite phosphorylation of P-Rex1 by protein kinase C.

Juan Carlos Montero,Samuel Seoane,Atanasio Pandiella,Sara García-Alonso

doi:10.18632/oncotarget.12846

Juan Carlos Montero, Samuel Seoane + Show 2 more

Open Access

https://doi.org/10.18632/oncotarget.12846

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Journal: Oncotarget	Publication Date: Oct 24, 2016
Citations: 10	License type: cc-by

Affiliation: Universidad de Salamanca

Abstract

P-Rex proteins are guanine nucleotide exchange factors (GEFs) that act on the Rho/Rac family of GTP binding proteins. The activity of P-Rex proteins is regulated by several extracellular stimuli. In fact, activation of growth factor receptors has been reported to activate a phosphorylation/dephosphorylation cycle of P-Rex1. Such cycle includes dephosphorylation of serines 313 and 319 which negatively regulate the GEF activity of P-Rex1, together with phosphorylation of serines 605 and 1169 which favour P-Rex1 GEF activity. However, the kinases that regulate phosphorylation at these different regulatory sites are largely unknown. Here we have investigated the potential regulatory action of several kinases on the phosphorylation of P-Rex1 at S313, S319, S605 and S1169. We show that activation of protein kinase C (PKC) caused phosphorylation of S313, S319 and S1169. Activation of growth factor receptors induced phosphorylation of S1169 through a mechanism that was independent of PKC, indicating that distinct kinases and mechanisms control the phosphorylation of P-Rex1 at different regulatory serines. Genetic and biochemical studies confirmed that the PKC isoform PKCδ was able to directly phosphorylate P-Rex1 at S313. Functional studies using cells with very low endogenous P-Rex1 expression, transfected with wild type P-Rex1 or a mutant form in which S313 was substituted by alanine, indicated that phosphorylation at that residue negatively regulated P-Rex1 exchange activity. We suggest that control of P-Rex1 activity depends on a highly dynamic interplay among distinct signalling routes and its multisite phosphorylation is controlled by the action of different kinases.

Highlights

P-Rex proteins belong to the family of guanine nucleotide exchange factors (GEFs) which act on the Rho/ Rac family of GTP binding proteins [1, 2]
S313, S319, S605 and S1169 were included among those sites and we centered our attention on those residues because of their reported regulatory role on P-Rex1 GEF activity [4]
Activation of growth factor receptors was shown to modify the phosphorylation status of those four P-Rex1 sites, and such phosphorylations were linked to changes in the GEF activity of P-Rex1 [4, 24]

Summary

Introduction

P-Rex proteins belong to the family of guanine nucleotide exchange factors (GEFs) which act on the Rho/ Rac family of GTP binding proteins [1, 2]. P-Rex proteins may exert GEF-independent roles, such as the regulation of PTEN function by P-Rex2 [3]. While knockout studies in mice have defined the role of P-Rex and P-Rex in animal homeostasis [5,6,7,8], several other studies have indicated that these proteins may participate in the pathogenesis of certain neoplasias [3, 4, 9,10,11,12,13,14,15,16,17]. A link between P-Rex expression and patient outcome has been reported in breast cancer [4, 13]. Mutations in P-Rex proteins have been described, and preclinical studies demonstrated that ectopic expression of mutated P-Rex in melanocytes accelerates tumor formation [11]. Frequent mutations in PREX2 have been reported [18]

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