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Structure-Based Mechanisms of a Molecular RNA Polymerase/Chaperone Machine Required for Ribosome Biosynthesis

59 Pages Posted: 12 May 2020 Publication Status: Published

See all articles by Yong-Heng Huang

Yong-Heng Huang

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

Tarek Hilal

Free University of Berlin (FUB)

Bernhard Loll

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

Jörg Bürger

Charité - Universitätsmedizin Berlin - Department of Medical Physics and Biophysics

Thorsten Mielke

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

Christoph Böttcher

Free University of Berlin (FUB)

Nelly Said

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

Markus Wahl

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

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Abstract

Bacterial ribosomal RNAs are synthesized by a dedicated, conserved transcription elongation complex that transcribes at high rates, shields RNA polymerase from premature termination, and supports co-transcriptional RNA folding, modification, processing and ribosomal subunit assembly by presently unknown mechanisms. We have determined cryo-electron microscopy structures of complete Escherichia coli ribosomal RNA transcription elongation complexes, comprising RNA polymerase, DNA, RNA bearing an N-utilization site-like anti-termination element, Nus factors A, B, E, and G, inositol mono-phosphatase SuhB and ribosomal protein S4. Our structures and structure-informed functional analyses show that fast transcription and anti-termination involve suppression of NusA-stabilized pausing, enhancement of NusG-mediated anti-backtracking, sequestration of the NusG C-terminal domain from termination factor ρ and ρ blockade. Strikingly, the factors form a composite RNA chaperone around the RNA polymerase RNA exit tunnel, which supports co-transcriptional RNA folding and annealing of distal RNA regions. Our work reveals a polymerase/chaperone machine required for biosynthesis of functional ribosomes.

Keywords: Co-transcriptional RNA folding and processing, Nus factors, RNA polymerase pausing and backtracking, RNA chaperone, ribosomal RNA transcription, single-particle cryo-electron microscopy, structural biology, transcription (anti-)termination, Transcription regulation

Suggested Citation

Huang, Yong-Heng and Hilal, Tarek and Loll, Bernhard and Bürger, Jörg and Mielke, Thorsten and Böttcher, Christoph and Said, Nelly and Wahl, Markus, Structure-Based Mechanisms of a Molecular RNA Polymerase/Chaperone Machine Required for Ribosome Biosynthesis. Available at SSRN: https://ssrn.com/abstract=3583657 or http://dx.doi.org/10.2139/ssrn.3583657
This version of the paper has not been formally peer reviewed.

Yong-Heng Huang

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

Van't-Hoff-Str. 8
Berlin, Berlin 14195
Germany

Tarek Hilal

Free University of Berlin (FUB) ( email )

Van't-Hoff-Str. 8
Berlin, Berlin 14195
Germany

Bernhard Loll

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

Van't-Hoff-Str. 8
Berlin, Berlin 14195
Germany

Jörg Bürger

Charité - Universitätsmedizin Berlin - Department of Medical Physics and Biophysics

Charitéplatz 1
Berlin, 10117
Germany

Thorsten Mielke

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

Van't-Hoff-Str. 8
Berlin, Berlin 14195
Germany

Christoph Böttcher

Free University of Berlin (FUB) ( email )

Van't-Hoff-Str. 8
Berlin, Berlin 14195
Germany

Nelly Said

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry

Van't-Hoff-Str. 8
Berlin, Berlin 14195
Germany

Markus Wahl (Contact Author)

Free University of Berlin (FUB) - Laboratory of Structural Biochemistry ( email )

Van't-Hoff-Str. 8
Berlin, Berlin 14195
Germany

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