RraA: A protein inhibitor of RNase E activity that globally modulates RNA abundance in E. coli

Kangseok Lee; Xiaoming Zhan; Junjun Gao; Ji Qiu; Yanan Feng; R. Meganathan; Stanley N. Cohen; George Georgiou

doi:10.1016/j.cell.2003.08.003

RraA: A protein inhibitor of RNase E activity that globally modulates RNA abundance in E. coli

Kangseok Lee, Xiaoming Zhan, Junjun Gao, Ji Qiu, Yanan Feng, R. Meganathan, Stanley N. Cohen, George Georgiou

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

140 Scopus citations

Abstract

Ribonuclease E (RNase E) has a key role in mRNA degradation and the processing of catalytic and structural RNAs in E. coli. We report the discovery of an evolutionarily conserved 17.4 kDa protein, here named RraA (regulator of ribonuclease activity A) that binds to RNase E and inhibits RNase E endonucleolytic cleavages without altering cleavage site specificity or interacting detectably with substrate RNAs. Overexpression of RraA circumvents the effects of an autoregulatory mechanism that normally maintains the RNase E cellular level within a narrow range, resulting in the genome-wide accumulation of RNase E-targeted transcripts. While not required for RraA action, the C-terminal RNase E region that serves as a scaffold for formation of a multiprotein degradosome complex modulates the inhibition of RNase E catalytic activity by RraA. Our results reveal a possible mechanism for the dynamic regulation of RNA decay and processing by inhibitory RNase binding proteins.

Original language	English (US)
Pages (from-to)	623-634
Number of pages	12
Journal	Cell
Volume	114
Issue number	5
DOIs	https://doi.org/10.1016/j.cell.2003.08.003
State	Published - Sep 5 2003
Externally published	Yes

ASJC Scopus subject areas

General Biochemistry, Genetics and Molecular Biology

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title = "RraA: A protein inhibitor of RNase E activity that globally modulates RNA abundance in E. coli",

abstract = "Ribonuclease E (RNase E) has a key role in mRNA degradation and the processing of catalytic and structural RNAs in E. coli. We report the discovery of an evolutionarily conserved 17.4 kDa protein, here named RraA (regulator of ribonuclease activity A) that binds to RNase E and inhibits RNase E endonucleolytic cleavages without altering cleavage site specificity or interacting detectably with substrate RNAs. Overexpression of RraA circumvents the effects of an autoregulatory mechanism that normally maintains the RNase E cellular level within a narrow range, resulting in the genome-wide accumulation of RNase E-targeted transcripts. While not required for RraA action, the C-terminal RNase E region that serves as a scaffold for formation of a multiprotein degradosome complex modulates the inhibition of RNase E catalytic activity by RraA. Our results reveal a possible mechanism for the dynamic regulation of RNA decay and processing by inhibitory RNase binding proteins.",

author = "Kangseok Lee and Xiaoming Zhan and Junjun Gao and Ji Qiu and Yanan Feng and R. Meganathan and Cohen, {Stanley N.} and George Georgiou",

note = "Funding Information: This work was supported by grants NSF BES-963406 and NIH GM 55090 to G.G., NIH GM 64511-01 to R.M., and by NIH GM 54158 to S.N.C. We thank J. Beckwith, A.J. Carpousis, J.G. Belasco, and S.R. Kushner for the gift of strains and S.R. Kushner and S. Lin-Chao for polyclonal antibodies to RNase E. We are grateful to C. Jain for many useful suggestions, K. Ravi for running the HPLC analysis of quinone synthesis, A. Saxena for assistance with library screening, and A. Hayhurst for help with BIACORE analysis.",

year = "2003",

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T2 - A protein inhibitor of RNase E activity that globally modulates RNA abundance in E. coli

AU - Lee, Kangseok

AU - Zhan, Xiaoming

AU - Gao, Junjun

AU - Qiu, Ji

AU - Feng, Yanan

AU - Meganathan, R.

AU - Cohen, Stanley N.

AU - Georgiou, George

N1 - Funding Information: This work was supported by grants NSF BES-963406 and NIH GM 55090 to G.G., NIH GM 64511-01 to R.M., and by NIH GM 54158 to S.N.C. We thank J. Beckwith, A.J. Carpousis, J.G. Belasco, and S.R. Kushner for the gift of strains and S.R. Kushner and S. Lin-Chao for polyclonal antibodies to RNase E. We are grateful to C. Jain for many useful suggestions, K. Ravi for running the HPLC analysis of quinone synthesis, A. Saxena for assistance with library screening, and A. Hayhurst for help with BIACORE analysis.

PY - 2003/9/5

Y1 - 2003/9/5

N2 - Ribonuclease E (RNase E) has a key role in mRNA degradation and the processing of catalytic and structural RNAs in E. coli. We report the discovery of an evolutionarily conserved 17.4 kDa protein, here named RraA (regulator of ribonuclease activity A) that binds to RNase E and inhibits RNase E endonucleolytic cleavages without altering cleavage site specificity or interacting detectably with substrate RNAs. Overexpression of RraA circumvents the effects of an autoregulatory mechanism that normally maintains the RNase E cellular level within a narrow range, resulting in the genome-wide accumulation of RNase E-targeted transcripts. While not required for RraA action, the C-terminal RNase E region that serves as a scaffold for formation of a multiprotein degradosome complex modulates the inhibition of RNase E catalytic activity by RraA. Our results reveal a possible mechanism for the dynamic regulation of RNA decay and processing by inhibitory RNase binding proteins.

AB - Ribonuclease E (RNase E) has a key role in mRNA degradation and the processing of catalytic and structural RNAs in E. coli. We report the discovery of an evolutionarily conserved 17.4 kDa protein, here named RraA (regulator of ribonuclease activity A) that binds to RNase E and inhibits RNase E endonucleolytic cleavages without altering cleavage site specificity or interacting detectably with substrate RNAs. Overexpression of RraA circumvents the effects of an autoregulatory mechanism that normally maintains the RNase E cellular level within a narrow range, resulting in the genome-wide accumulation of RNase E-targeted transcripts. While not required for RraA action, the C-terminal RNase E region that serves as a scaffold for formation of a multiprotein degradosome complex modulates the inhibition of RNase E catalytic activity by RraA. Our results reveal a possible mechanism for the dynamic regulation of RNA decay and processing by inhibitory RNase binding proteins.

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RraA: A protein inhibitor of RNase E activity that globally modulates RNA abundance in E. coli

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