Active site closure stabilizes the backtracked state of RNA polymerase

• Published in: Nucleic acids research Vol. 46; no. 20; pp. 10870 - 10887
• Main Authors: Turtola, Matti, Mäkinen, Janne J, Belogurov, Georgiy A
• Format: Journal Article
• Language: English
• Published: England Oxford University Press 16.11.2018
• Subjects: Catalysis; Catalytic Domain - genetics; DNA-Directed RNA Polymerases - chemistry; DNA-Directed RNA Polymerases - genetics; DNA-Directed RNA Polymerases - metabolism; Escherichia coli; Escherichia coli Proteins - chemistry; Escherichia coli Proteins - genetics; Escherichia coli Proteins - metabolism; Models, Molecular; Nucleic Acid Enzymes; Protein Binding; Protein Folding; Protein Stability; RNA - chemistry; RNA - metabolism; Transcription Elongation, Genetic
• ISSN: 0305-1048; 1362-4962
• DOI: 10.1093/nar/gky883

Abstract All cellular RNA polymerases (RNAP) occasionally backtrack along the template DNA as part of transcriptional proofreading and regulation. Here, we studied the mechanism of RNAP backtracking by one nucleotide using two complementary approaches that allowed us to precisely measure the occupancy and lifetime of the backtracked state. Our data show that the stability of the backtracked state is critically dependent on the closure of the RNAP active site by a mobile domain, the trigger loop (TL). The lifetime and occupancy of the backtracked state measurably decreased by substitutions of the TL residues that interact with the nucleoside triphosphate (NTP) substrate, whereas amino acid substitutions that stabilized the closed active site increased the lifetime and occupancy. These results suggest that the same conformer of the TL closes the active site during catalysis of nucleotide incorporation into the nascent RNA and backtracking by one nucleotide. In support of this hypothesis, we construct a model of the 1-nt backtracked complex with the closed active site and the backtracked nucleotide in the entry pore area known as the E-site. We further propose that 1-nt backtracking mimics the reversal of the NTP substrate loading into the RNAP active site during on-pathway elongation.