Ras Activation by Hydrostatic Pressure is Enhanced by GAP and GEFin vitro

Abstract

AbstractHydrostatic pressure (HP) is a necessary stimulus for cell differentiation and growth in cultured chondrocytes. Assuming that Ras activation is involved in HP-induced reactions, if cellular Ras activity is increased by HP, Ras itself, Raf, Ras regulators including GTPase activating proteins (GAP) and guanine nucleotide exchange factors (GEF), then the upstream receptor and/or interactions between them should have HP sensitivity. Based on this hypothesis, we first attempted to examine whether Ras is activated by HP, and in the affirmative, identify which factors displayed HP sensitivity using anin vitrosystem to measure Ras activity. Thisin vitrosystem included mRaichu, a FRET-based Ras activity probe, to which two-point mutations were introduced to reduce Ras-independent signals. This improved Raichu was used to investigate the HP sensitivity of two components, the GAP domain (GAPd) derived from p120GAP and the GEF domain (GEFd) derived from hSOS-1. It was found that HP weakly activated Ras activity in the absence of GAPd and GEFd, presumably by facilitating GDP dissociation from Ras. A low concentration of GAPd enhanced HP-induced Ras activation by 16.3% whereas high concentrations of GAPd removed HP sensitivity, suggesting that HP partially dissociates GAPd from the GAPd-Ras-GDP complex and reduces the fraction of inactive Ras. Moreover, a broad concentration range of GEFd also enhanced HP-induced Ras activation. Given that HP also increased Ras activity under a condition mimicking cellular Ras activity, we propose that Ras activation is involved in the differentiation and growth stimulation of chondrocytes by HP.Statement of SignificanceThe Ras-cycle has been implicated in the regulation of growth and differentiation of eukaryotic cells. Here, we investigated the relationship between hydrostatic pressure (HP) and components of the Ras-cycle: Ras-Raf, the GAP domain, and the GEF domain. Generally, HP tends to weaken protein-protein and protein-ligand interactions, but in this study, a seemingly positive response was observed: HP-induced Ras activation. Additionally, this response was enhanced by the GEF domain and the GAP domain. Thus, given the multiple cellular functions of Ras and the responses of the Ras-cycle to HP, this study will help clarify the molecular mechanism by which HP modulates cellular functions, particularly in chondrocytes, which are subjected to repetitive HP stimuliin vivo.