Role of the switch II region in the conformational transition of activation of Ha-ras-p21

JOSÉ FERNANDO DÍAZ; MARÍA MILAGROSA ESCALONA; STEVEN KUPPENS; YVES ENGELBORGHS

doi:10.1110/ps.9.2.361

Abstract

The role of the switch II region in the conformational transition of activation of Ha-ras-p21 has been investigated by mutating residues predicted to act as hinges for the conformational transition of this loop (Ala59, Gly60, and Gly75) (Diaz JF, Wroblowski B, Schlitter J, Engelborghs Y, 1997, Proteins 28:434–451), as well as mutating the catalytic residue Gln61. The proposed mutations of the hinge residues decrease the rate of the conformational transition of activation as measured by the binding of BeF3− to the GDP-p21 complex. Also, the thermodynamic parameters of the binding reaction are altered by a factor between three and five, depending on the temperature. (Due to changes in activation and reaction enthalpies, partially compensated by entropy changes.) The control mutation Q61H in which only the catalytic residue is changed has only a limited effect on the kinetic rate constants of the conformational transition and on the thermodynamic parameters of the reaction.

The fact that mutations of the hinge residues of the switch II region affect both the binding of the phosphate analog and the conformational transition of activation indicates that the switch II is implicated both in the early and the late states of the transition.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Farrar, Christian T. Ma, Jianpeng Singel, David J. and Halkides, Christopher J. 2000. Structural Changes Induced in p21Ras upon GAP-334 Complexation as Probed by ESEEM Spectroscopy and Molecular-Dynamics Simulation. Structure, Vol. 8, Issue. 12, p. 1279.

Dı́az, José Fernando Kralicek, Andrew Mingorance, Jesús Palacios, Juan Manuel Vicente, Miguel and Andreu, José Manuel 2001. Activation of Cell Division Protein FtsZ. Journal of Biological Chemistry, Vol. 276, Issue. 20, p. 17307.

Kosztin, Ioan Bruinsma, Robijn O'Lague, Paul and Schulten, Klaus 2002. Mechanical force generation by G proteins. Proceedings of the National Academy of Sciences, Vol. 99, Issue. 6, p. 3575.

Kuppens, Steven Hellings, Mario Jordens, Jan Verheyden, Stefan and Engelborghs, Yves 2003. Conformational states of the switch I region of Ha‐ras‐p21 in hinge residue mutants studied by fluorescence lifetime and fluorescence anisotropy measurements. Protein Science, Vol. 12, Issue. 5, p. 930.

Swegat, Wolfgang Schlitter, Jürgen Krüger, Peter and Wollmer, Axel 2003. MD Simulation of Protein-Ligand Interaction: Formation and Dissociation of an Insulin-Phenol Complex. Biophysical Journal, Vol. 84, Issue. 3, p. 1493.

Fiegen, Dennis Dvorsky, Radovan and Ahmadian, Mohammad Reza 2006. RAS Family GTPases. p. 45.

Sharma, Neeru Sonavane, Uddhavesh and Joshi, Rajendra 2014. Probing the wild-type HRas activation mechanism using steered molecular dynamics, understanding the energy barrier and role of water in the activation. European Biophysics Journal, Vol. 43, Issue. 2-3, p. 81.

Wey, Michael Lee, Jungwoon Kim, Hyo Sun Jeong, Soon Seog Kim, Jungho and Heo, Jongyun 2016. Kinetic Mechanism of Formation of Hyperactive Embryonic Ras in Cells. Biochemistry, Vol. 55, Issue. 3, p. 543.

Muhoza, Djamali and Adams, Paul D. 2017. Two Small Molecules, ZCL278 and AZA197 Show Promise in Influencing Protein Interactions Involving the Ras-Related Protein Cell division cycle 42 [Cdc42] to Modulate Its Oncogenic Potential. Open Journal of Biophysics, Vol. 07, Issue. 03, p. 71.

Sáez-Calvo, Gonzalo Sharma, Ashwani Balaguer, Francisco de Asís Barasoain, Isabel Rodríguez-Salarichs, Javier Olieric, Natacha Muñoz-Hernández, Hugo Berbís, Manuel Álvaro Wendeborn, Sebastian Peñalva, Miguel Angel Matesanz, Ruth Canales, Ángeles Prota, Andrea Enrico Jímenez-Barbero, Jesús Andreu, José Manuel Lamberth, Clemens Steinmetz, Michel Olivier and Díaz, José Fernando 2017. Triazolopyrimidines Are Microtubule-Stabilizing Agents that Bind the Vinca Inhibitor Site of Tubulin. Cell Chemical Biology, Vol. 24, Issue. 6, p. 737.

Sharma, Neeru Sonavane, Uddhavesh and Joshi, Rajendra 2017. Differentiating the pre-hydrolysis states of wild-type and A59G mutant HRas: An insight through MD simulations. Computational Biology and Chemistry, Vol. 69, Issue. , p. 96.

Peters, Daniel T. Kay, Laura Eswaran, Jeyanthy Lakey, Jeremy H. and Soundararajan, Meera 2018. Human Miro Proteins Act as NTP Hydrolases through a Novel, Non-Canonical Catalytic Mechanism. International Journal of Molecular Sciences, Vol. 19, Issue. 12, p. 3839.

Marín-Ramos, Nagore I. Ortega-Gutiérrez, Silvia and López-Rodríguez, María L. 2019. Blocking Ras inhibition as an antitumor strategy. Seminars in Cancer Biology, Vol. 54, Issue. , p. 91.

Article contents

Role of the switch II region in the conformational transition of activation of Ha-ras-p21

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Role of the switch II region in the conformational transition of activation of Ha-ras-p21

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests