Structural and functional analyses of a germline KRAS T50I mutation provide insights into Raf activation
Pan-Yu Chen, Benjamin J. Huang, Max Harris, Christopher Boone, Weijie Wang, Heidi Carias, Brian Mesiona, Daniela Mavrici, Amanda C. Kohler, Gideon Bollag, Chao Zhang, Ying Zhang, Kevin Shannon
Pan-Yu Chen, Benjamin J. Huang, Max Harris, Christopher Boone, Weijie Wang, Heidi Carias, Brian Mesiona, Daniela Mavrici, Amanda C. Kohler, Gideon Bollag, Chao Zhang, Ying Zhang, Kevin Shannon
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Research Article Oncology

Structural and functional analyses of a germline KRAS T50I mutation provide insights into Raf activation

Abstract

A T50I substitution in the K-Ras interswitch domain causes Noonan syndrome and emerged as a third-site mutation that restored the in vivo transforming activity and constitutive MAPK pathway activation by an attenuated KrasG12D,E37G oncogene in a mouse leukemia model. Biochemical and crystallographic data suggested that K-RasT50I increases MAPK signal output through a non-GTPase mechanism, potentially by promoting asymmetric Ras:Ras interactions between T50 and E162. We generated a “switchable” system in which K-Ras mutant proteins expressed at physiologic levels supplant the fms like tyrosine kinase 3 (FLT3) dependency of MOLM-13 leukemia cells lacking endogenous KRAS and used this system to interrogate single or compound G12D, T50I, D154Q, and E162L mutations. These studies support a key role for the asymmetric lateral assembly of K-Ras in a plasma membrane–distal orientation that promotes the formation of active Ras:Raf complexes in a membrane-proximal conformation. Disease-causing mutations such as T50I are a valuable starting point for illuminating normal Ras function, elucidating mechanisms of disease, and identifying potential therapeutic opportunities for Rasopathy disorders and cancer.

Authors

Pan-Yu Chen, Benjamin J. Huang, Max Harris, Christopher Boone, Weijie Wang, Heidi Carias, Brian Mesiona, Daniela Mavrici, Amanda C. Kohler, Gideon Bollag, Chao Zhang, Ying Zhang, Kevin Shannon

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Figure 5

Potential impact of T50I in the context of recent models of Raf recruitment to the plasma membrane and activation by Ras-GTP.

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Potential impact of T50I in the context of recent models of Raf recruitm...
In accordance with the data of Van et al. (15, 17, 18, 47), T50I and E162L mutations could enhance the lateral assembly of Ras-GTP in the membrane-distal state, thereby increasing interaction avidity and range as “bait” to engage the RBD of Raf. Upon binding to Raf, the interswitch region of Ras, which includes T50, dissociates from neighboring Ras molecules and binds the Raf-CRD. Ras binding to the Raf-CRD has been shown to disassemble the auto-inhibited state of Raf, with the exposed basic α4/α5 side chains of Ras acting together with the Raf-CRD as lipid “adhesives” that facilitate transition of the Ras:Raf monomer to a plasma membrane–proximal state. When viewed in the context of recently solved co-crystal structures, a T50I mutation could increase signal output by stabilizing the interaction of Ras with the Raf-CRD at the PM. Kinase domain–exposed Raf is then poised to attract and integrate a second Ras:Raf monomer to form a productive signaling complex.