A birth-to-death view of mRNA from the RNA recognition motif perspective

Terri Goss Kinzy; Lauren A. De Stefano; Anthony M. Esposito; Jennifer M. Hurley; Rohini Roy; Anibal J. Valentin-Acevedo; Kai Hsiung Changt; Jonathan Davila; Jennifer M. Defren; Jesse Donovan; Patricia Irizarry-Barreto; Anibal Soto; Riza M. Ysla; H. Liesel Copeland; Paul R. Copeland

doi:10.1002/bmb.20149

A birth-to-death view of mRNA from the RNA recognition motif perspective

Terri Goss Kinzy, Lauren A. De Stefano, Anthony M. Esposito, Jennifer M. Hurley, Rohini Roy, Anibal J. Valentin-Acevedo, Kai Hsiung Changt, Jonathan Davila, Jennifer M. Defren, Jesse Donovan, Patricia Irizarry-Barreto, Anibal Soto, Riza M. Ysla, H. Liesel Copeland, Paul R. Copeland

Robert Wood Johnson Medical School (RWJMS), Biochemistry & Molecular Biology

Research output: Contribution to journal › Review article › peer-review

1 Scopus citations

Abstract

RNA binding proteins are a large and varied group of factors that are the driving force behind post-transcriptional gene regulation. By analogy with transcription factors, RNA binding proteins bind to various regions of the mRNAs that they regulate, usually upstream or downstream from the coding region, and modulate one of the five major processes in mRNA metabolism: splicing, polyadenylation, export, translation and decay. The most abundant RNA binding protein domain is called the RNA Recognition Motif (RRM)¹. It is probably safe to say that an RRM-containing protein is making some contact with an mRNA throughout its existence. The transcriptional counterpart would likely be the histones, yet the multitude of specific functions that are results of RRM based interactions belies the universality of the motif. This complex and diverse application of a single protein motif was used as the basis to develop an advanced graduate level seminar course in RNA:protein interactions. The course, utilizing a learner-centered empowerment model, was developed to dissect each step in RNA metabolism from the perspective of an RRM containing protein. This provided a framework to discuss the development of specificity for the RRM for each required process.

Original language	English (US)
Pages (from-to)	1-8
Number of pages	8
Journal	Biochemistry and Molecular Biology Education
Volume	36
Issue number	1
DOIs	https://doi.org/10.1002/bmb.20149
State	Published - Jan 2008

All Science Journal Classification (ASJC) codes

Biochemistry
Molecular Biology

Keywords

Polyadenylation
RNA export
RNA recognition motif
Splicing
Translation
mRNA decay
mRNA localization

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10.1002/bmb.20149

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Kinzy, T. G., De Stefano, L. A., Esposito, A. M., Hurley, J. M., Roy, R., Valentin-Acevedo, A. J., Changt, K. H., Davila, J., Defren, J. M., Donovan, J., Irizarry-Barreto, P., Soto, A., Ysla, R. M., Copeland, H. L., & Copeland, P. R. (2008). A birth-to-death view of mRNA from the RNA recognition motif perspective. Biochemistry and Molecular Biology Education, 36(1), 1-8. https://doi.org/10.1002/bmb.20149

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title = "A birth-to-death view of mRNA from the RNA recognition motif perspective",

abstract = "RNA binding proteins are a large and varied group of factors that are the driving force behind post-transcriptional gene regulation. By analogy with transcription factors, RNA binding proteins bind to various regions of the mRNAs that they regulate, usually upstream or downstream from the coding region, and modulate one of the five major processes in mRNA metabolism: splicing, polyadenylation, export, translation and decay. The most abundant RNA binding protein domain is called the RNA Recognition Motif (RRM)1. It is probably safe to say that an RRM-containing protein is making some contact with an mRNA throughout its existence. The transcriptional counterpart would likely be the histones, yet the multitude of specific functions that are results of RRM based interactions belies the universality of the motif. This complex and diverse application of a single protein motif was used as the basis to develop an advanced graduate level seminar course in RNA:protein interactions. The course, utilizing a learner-centered empowerment model, was developed to dissect each step in RNA metabolism from the perspective of an RRM containing protein. This provided a framework to discuss the development of specificity for the RRM for each required process.",

keywords = "Polyadenylation, RNA export, RNA recognition motif, Splicing, Translation, mRNA decay, mRNA localization",

author = "Kinzy, {Terri Goss} and {De Stefano}, {Lauren A.} and Esposito, {Anthony M.} and Hurley, {Jennifer M.} and Rohini Roy and Valentin-Acevedo, {Anibal J.} and Changt, {Kai Hsiung} and Jonathan Davila and Defren, {Jennifer M.} and Jesse Donovan and Patricia Irizarry-Barreto and Anibal Soto and Ysla, {Riza M.} and Copeland, {H. Liesel} and Copeland, {Paul R.}",

year = "2008",

month = jan,

doi = "10.1002/bmb.20149",

language = "English (US)",

volume = "36",

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journal = "Biochemistry and Molecular Biology Education",

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Kinzy, TG, De Stefano, LA, Esposito, AM, Hurley, JM, Roy, R, Valentin-Acevedo, AJ, Changt, KH, Davila, J, Defren, JM, Donovan, J, Irizarry-Barreto, P, Soto, A, Ysla, RM, Copeland, HL & Copeland, PR 2008, 'A birth-to-death view of mRNA from the RNA recognition motif perspective', Biochemistry and Molecular Biology Education, vol. 36, no. 1, pp. 1-8. https://doi.org/10.1002/bmb.20149

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T1 - A birth-to-death view of mRNA from the RNA recognition motif perspective

AU - Kinzy, Terri Goss

AU - De Stefano, Lauren A.

AU - Esposito, Anthony M.

AU - Hurley, Jennifer M.

AU - Roy, Rohini

AU - Valentin-Acevedo, Anibal J.

AU - Changt, Kai Hsiung

AU - Davila, Jonathan

AU - Defren, Jennifer M.

AU - Donovan, Jesse

AU - Irizarry-Barreto, Patricia

AU - Soto, Anibal

AU - Ysla, Riza M.

AU - Copeland, H. Liesel

AU - Copeland, Paul R.

PY - 2008/1

Y1 - 2008/1

N2 - RNA binding proteins are a large and varied group of factors that are the driving force behind post-transcriptional gene regulation. By analogy with transcription factors, RNA binding proteins bind to various regions of the mRNAs that they regulate, usually upstream or downstream from the coding region, and modulate one of the five major processes in mRNA metabolism: splicing, polyadenylation, export, translation and decay. The most abundant RNA binding protein domain is called the RNA Recognition Motif (RRM)1. It is probably safe to say that an RRM-containing protein is making some contact with an mRNA throughout its existence. The transcriptional counterpart would likely be the histones, yet the multitude of specific functions that are results of RRM based interactions belies the universality of the motif. This complex and diverse application of a single protein motif was used as the basis to develop an advanced graduate level seminar course in RNA:protein interactions. The course, utilizing a learner-centered empowerment model, was developed to dissect each step in RNA metabolism from the perspective of an RRM containing protein. This provided a framework to discuss the development of specificity for the RRM for each required process.

AB - RNA binding proteins are a large and varied group of factors that are the driving force behind post-transcriptional gene regulation. By analogy with transcription factors, RNA binding proteins bind to various regions of the mRNAs that they regulate, usually upstream or downstream from the coding region, and modulate one of the five major processes in mRNA metabolism: splicing, polyadenylation, export, translation and decay. The most abundant RNA binding protein domain is called the RNA Recognition Motif (RRM)1. It is probably safe to say that an RRM-containing protein is making some contact with an mRNA throughout its existence. The transcriptional counterpart would likely be the histones, yet the multitude of specific functions that are results of RRM based interactions belies the universality of the motif. This complex and diverse application of a single protein motif was used as the basis to develop an advanced graduate level seminar course in RNA:protein interactions. The course, utilizing a learner-centered empowerment model, was developed to dissect each step in RNA metabolism from the perspective of an RRM containing protein. This provided a framework to discuss the development of specificity for the RRM for each required process.

KW - Polyadenylation

KW - RNA export

KW - RNA recognition motif

KW - Splicing

KW - Translation

KW - mRNA decay

KW - mRNA localization

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U2 - 10.1002/bmb.20149

DO - 10.1002/bmb.20149

M3 - Review article

C2 - 21591152

AN - SCOPUS:38949104116

SN - 1470-8175

VL - 36

SP - 1

EP - 8

JO - Biochemistry and Molecular Biology Education

JF - Biochemistry and Molecular Biology Education

IS - 1

ER -

A birth-to-death view of mRNA from the RNA recognition motif perspective

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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