Identification and Characterization of a B-Raf Kinase α-Helix Critical for the Activity of MEK Kinase in MAPK Signaling

Overview

Journal Biochemistry

Specialty Biochemistry

Date 2020 Dec 4

PMID 33272017

Citations 4

Authors

Diep Nguyen

Linda Yingqi Lin

Jeffrey O Zhou

Emily Kibby

Twan W Sia

Tiara D Tillis

Narine Vapuryan

Ming-Ray Xu

Rajiv Potluri

YongJoon Shin

Elizabeth A Erler

Naomi Bronkema

Daniel J Boehlmer

Christopher D Chung

Caroline Burkhard

Shirley H Zeng

Michael Grasso

Lucila A Acevedo

Ronen Marmorstein

Daniela Fera

Affiliations

Soon will be listed here.

Abstract

In the MAPK pathway, an oncogenic V600E mutation in B-Raf kinase causes the enzyme to be constitutively active, leading to aberrantly high phosphorylation levels of its downstream effectors, MEK and ERK kinases. The V600E mutation in B-Raf accounts for more than half of all melanomas and ∼3% of all cancers, and many drugs target the ATP binding site of the enzyme for its inhibition. Because B-Raf can develop resistance against these drugs and such drugs can induce paradoxical activation, drugs that target allosteric sites are needed. To identify other potential drug targets, we generated and kinetically characterized an active form of B-Raf expressed using a bacterial expression system. In doing so, we identified an α-helix on B-Raf, found at the B-Raf-MEK interface, that is critical for their interaction and the oncogenic activity of B-Raf. We assessed the binding between B-Raf mutants and MEK using pull downs and biolayer interferometry and assessed phosphorylation levels of MEK and in cells as well as its downstream target ERK to show that mutating certain residues on this α-helix is detrimental to binding and downstream activity. Our results suggest that this B-Raf α-helix binding site on MEK could be a site to target for drug development to treat B-Raf-induced melanomas.

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