Discovering RNA-Protein Interactome by Using Chemical Context Profiling of the RNA-Protein Interface

Marc Parisien; Xiaoyun Wang; George Perdrizet; Corissa Lamphear; Carol A. Fierke; Ketan C. Maheshwari; Michael J. Wilde; Tobin R. Sosnick; Tao Pan

doi:10.1016/j.celrep.2013.04.010

Discovering RNA-Protein Interactome by Using Chemical Context Profiling of the RNA-Protein Interface

Marc Parisien
, Xiaoyun Wang
, George Perdrizet
, Corissa Lamphear
, Carol A. Fierke
, Ketan C. Maheshwari
, Michael J. Wilde
, Tobin R. Sosnick
, Tao Pan

Research output: Contribution to journal › Article › peer-review

27 Scopus citations

Abstract

RNA-protein (RNP) interactions generally are required for RNA function. At least 5% of human genes code for RNA-binding proteins. Whereas many approaches can identify the RNA partners for a specific protein, finding the protein partners for a specific RNA is difficult. We present a machine-learning method that scores a protein's binding potential for an RNA structure by utilizing the chemical context profiles of the interface from known RNP structures. Our approach is applicable even when only a single RNP structure is available. We examined 801 mammalian proteins and find that 37 (4.6%) potentially bind transfer RNA (tRNA). Most are enzymes involved in cellular processes unrelated to translation and were not known to interact with RNA. We experimentally tested six positive and three negative predictions for tRNA binding invivo, and all nine predictions were correct. Our computational approach provides a powerful complement to experiments in discovering new RNPs.

Original language	English
Pages (from-to)	1703-1713
Number of pages	11
Journal	Cell Reports
Volume	3
Issue number	5
DOIs	https://doi.org/10.1016/j.celrep.2013.04.010
State	Published - May 30 2013
Externally published	Yes

Funding

This work was supported by an NIH grant (GM57880 to T.R.S. and T.P.), the NIH-supported computing resources of the “Beagle” Cray XE6 system (S10 RR029030-01), the NSF-supported ExTENCI project (OCI-1007115), and the computing resources of the Open Science Grid. M.P. was a Chicago Fellow of the University of Chicago and is a Natural Sciences and Engineering Research Council of Canada postdoctoral fellow. Computations were performed on the Godzilla, iBi, and the Beagle clusters at the University of Chicago. We thank B. Busby for computing assistance. We also thank Drs. Xiao-jing Yang and Karl Freed for stimulating discussions. A web server for predicting additional tRNA-protein complexes is available at http://godzilla.uchicago.edu/pages/duck-na/ .

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10.1016/j.celrep.2013.04.010

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title = "Discovering RNA-Protein Interactome by Using Chemical Context Profiling of the RNA-Protein Interface",

abstract = "RNA-protein (RNP) interactions generally are required for RNA function. At least 5\% of human genes code for RNA-binding proteins. Whereas many approaches can identify the RNA partners for a specific protein, finding the protein partners for a specific RNA is difficult. We present a machine-learning method that scores a protein's binding potential for an RNA structure by utilizing the chemical context profiles of the interface from known RNP structures. Our approach is applicable even when only a single RNP structure is available. We examined 801 mammalian proteins and find that 37 (4.6\%) potentially bind transfer RNA (tRNA). Most are enzymes involved in cellular processes unrelated to translation and were not known to interact with RNA. We experimentally tested six positive and three negative predictions for tRNA binding invivo, and all nine predictions were correct. Our computational approach provides a powerful complement to experiments in discovering new RNPs.",

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AU - Parisien, Marc

AU - Wang, Xiaoyun

AU - Perdrizet, George

AU - Lamphear, Corissa

AU - Fierke, Carol A.

AU - Maheshwari, Ketan C.

AU - Wilde, Michael J.

AU - Sosnick, Tobin R.

AU - Pan, Tao

PY - 2013/5/30

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AB - RNA-protein (RNP) interactions generally are required for RNA function. At least 5% of human genes code for RNA-binding proteins. Whereas many approaches can identify the RNA partners for a specific protein, finding the protein partners for a specific RNA is difficult. We present a machine-learning method that scores a protein's binding potential for an RNA structure by utilizing the chemical context profiles of the interface from known RNP structures. Our approach is applicable even when only a single RNP structure is available. We examined 801 mammalian proteins and find that 37 (4.6%) potentially bind transfer RNA (tRNA). Most are enzymes involved in cellular processes unrelated to translation and were not known to interact with RNA. We experimentally tested six positive and three negative predictions for tRNA binding invivo, and all nine predictions were correct. Our computational approach provides a powerful complement to experiments in discovering new RNPs.

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JO - Cell Reports

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ER -

Discovering RNA-Protein Interactome by Using Chemical Context Profiling of the RNA-Protein Interface

Abstract

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