Biochemical Classification of Disease-associated Mutants of RAS-like Protein Expressed in Many Tissues (RIT1)

RAS-like protein expressed in many tissues 1 (RIT1) is a disease-associated RAS subfamily small guanosine triphosphatase (GTPase). Recent studies revealed that germ-line and somatic RIT1 mutations can cause Noonan syndrome (NS), and drive proliferation of lung adenocarcinomas, respectively, akin to...

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Published in:	The Journal of biological chemistry Vol. 291; no. 30; pp. 15641 - 15652
Main Authors:	Fang, Zhenhao, Marshall, Christopher B., Yin, Jiani C., Mazhab-Jafari, Mohammad T., Gasmi-Seabrook, Geneviève M.C., Smith, Matthew J., Nishikawa, Tadateru, Xu, Yang, Neel, Benjamin G., Ikura, Mitsuhiko
Format:	Journal Article
Language:	English
Published:	United States Elsevier Inc 22-07-2016 American Society for Biochemistry and Molecular Biology
Subjects:	Adenocarcinoma - genetics Adenocarcinoma - metabolism Adenocarcinoma of Lung Amino Acid Substitution cancer Cell Line GTP hydrolysis Guanosine Triphosphate - chemistry Humans Hydrolysis Lung Neoplasms - genetics Lung Neoplasms - metabolism Molecular Bases of Disease Mutation, Missense Neoplasm Proteins - chemistry Neoplasm Proteins - genetics Neoplasm Proteins - metabolism Noonan Syndrome Noonan Syndrome - genetics Noonan Syndrome - metabolism nuclear magnetic resonance (NMR) nucleotide exchange Protein Domains Ras protein ras Proteins - chemistry ras Proteins - genetics ras Proteins - metabolism RIT1 small GTPase structure-function Urologic Neoplasms - genetics Urologic Neoplasms - metabolism RIT1 GTP hydrolysis nuclear magnetic resonance (NMR) structure-function Noonan Syndrome nucleotide exchange cancer Ras protein small GTPase
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Summary:	RAS-like protein expressed in many tissues 1 (RIT1) is a disease-associated RAS subfamily small guanosine triphosphatase (GTPase). Recent studies revealed that germ-line and somatic RIT1 mutations can cause Noonan syndrome (NS), and drive proliferation of lung adenocarcinomas, respectively, akin to RAS mutations in these diseases. However, the locations of these RIT1 mutations differ significantly from those found in RAS, and do not affect the three mutational “hot spots” of RAS. Moreover, few studies have characterized the GTPase cycle of RIT1 and its disease-associated mutants. Here we developed a real-time NMR-based GTPase assay for RIT1 and investigated the effect of disease-associated mutations on GTPase cycle. RIT1 exhibits an intrinsic GTP hydrolysis rate similar to that of H-RAS, but its intrinsic nucleotide exchange rate is ∼4-fold faster, likely as a result of divergent residues near the nucleotide binding site. All of the disease-associated mutations investigated increased the GTP-loaded, activated state of RIT1 in vitro, but they could be classified into two groups with different intrinsic GTPase properties. The S35T, A57G, and Y89H mutants exhibited more rapid nucleotide exchange, whereas F82V and T83P impaired GTP hydrolysis. A RAS-binding domain pulldown assay indicated that RIT1 A57G and Y89H were highly activated in HEK293T cells, whereas T83P and F82V exhibited more modest activation. All five mutations are associated with NS, whereas two (A57G and F82V) have also been identified in urinary tract cancers and myeloid malignancies. Characterization of the effects on the GTPase cycle of RIT1 disease-associated mutations should enable better understanding of their role in disease processes.
Bibliography:	Present address: Program in Molecular Structure and Function, Hospital for Sick Children, Toronto, Ontario M5G 1X8, Canada. Present address: Institut de recherche en immunologie et en cancérologie (IRIC), Université de Montréal, 2900 Boulevard Edouard-Montpetit, Montréal, Quebec H3T 1J4, Canada. Present address: Laura and Isaac Perlmutter Cancer Center, New York University, New York, NY 10016.
ISSN:	0021-9258 1083-351X
DOI:	10.1074/jbc.M116.714196