This proposal focusses on transcription initiation and elongation by bacterial RNA polymerase (RNAP). Transcription initiation and elongation involve a series of steps: (i) RNAP binds to promoter DNA, yielding an RNAP-promoter closed complex;(ii) RNAP unwinds promoter DNA, yielding an RNAP-promoter open complex;(iii) RNAP synthesizes the first ~8 -15 nucleotides of RNA as an RNAP-promoter initial transcribing complex, using a """"""""scrunching"""""""" mechanism, in which RNAP remains stationary on promoter DNA and pulls in adjacent DNA in each nucleotide-addition cycle;and (iv) RNAP breaks its interactions with promoter DNA and synthesizes the remaining nucleotides of RNA as an RNAP-DNA elongation complex, using a """"""""stepping"""""""" mechanism, in which RNAP moves forward on DNA in each nucleotide-addition cycle. Each of these steps is a potential target for transcriptional regulators. Understanding transcription initiation, transcription elongation, and transcriptional regulation will require defining the structural transitions in protein and DNA at each step, defining kinetics of structural transitions, and defining mechanisms by which transcriptional regulators affect structural transitions. The proposed work will use ensemble and single-molecule fluorescence resonance energy transfer, single-molecule nanomanipulation, biochemical methods, and genetic methods to address five specific aims:
Specific Aim 1 : Determination of the mechanism of scrunching Specific Aim 2: Determination of the role of scrunching Specific Aim 3: Determination of the mechanism of RNAP active-center-cleft loading Specific Aim 4: Detection and analysis of RNAP active-center conformational cycling Specific Aim 5: Determination of the target and mechanism of transcriptional regulators ppGpp and DksA The results will contribute to understanding bacterial transcription and transcriptional regulation, and will contribute to design and synthesis of small-molecule inhibitors of bacterial transcription, for application in antibacterial therapy. Since bacterial RNAP subunits show sequence, structural, and mechanistic similarities to eukaryotic RNAP subunits, the results also will contribute to understanding eukaryotic transcription and transcriptional regulation.

Public Health Relevance

Bacterial RNA polymerase (RNAP) is a molecular machine that carries out reactions essential for bacterial gene expression and bacterial growth. An important class of broad-spectrum antibacterial therapeutic agents functions by inhibiting RNAP. The proposed work will provide information essential for understanding the mechanism of action of RNAP and for rational design of improved and novel broad-spectrum antibacterial agents that function by inhibiting RNAP.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
3R01GM041376-21S1
Application #
7932650
Study Section
Prokaryotic Cell and Molecular Biology Study Section (PCMB)
Program Officer
Preusch, Peter C
Project Start
2009-09-30
Project End
2010-01-31
Budget Start
2009-09-30
Budget End
2010-01-31
Support Year
21
Fiscal Year
2009
Total Cost
$48,358
Indirect Cost
Name
Rutgers University
Department
Type
Organized Research Units
DUNS #
001912864
City
New Brunswick
State
NJ
Country
United States
Zip Code
08901
Vvedenskaya, Irina O; Bird, Jeremy G; Zhang, Yuanchao et al. (2018) CapZyme-Seq Comprehensively Defines Promoter-Sequence Determinants for RNA 5' Capping with NAD. Mol Cell 70:553-564.e9
Lin, Wei; Das, Kalyan; Degen, David et al. (2018) Structural Basis of Transcription Inhibition by Fidaxomicin (Lipiarmycin A3). Mol Cell 70:60-71.e15
Sosio, Margherita; Gaspari, Eleonora; Iorio, Marianna et al. (2018) Analysis of the Pseudouridimycin Biosynthetic Pathway Provides Insights into the Formation of C-nucleoside Antibiotics. Cell Chem Biol 25:540-549.e4
Maffioli, Sonia I; Sosio, Margherita; Ebright, Richard H et al. (2018) Discovery, properties, and biosynthesis of pseudouridimycin, an antibacterial nucleoside-analog inhibitor of bacterial RNA polymerase. J Ind Microbiol Biotechnol :
Gabizon, Ronen; Lee, Antony; Vahedian-Movahed, Hanif et al. (2018) Pause sequences facilitate entry into long-lived paused states by reducing RNA polymerase transcription rates. Nat Commun 9:2930
Walker, Scott S; Degen, David; Nickbarg, Elliott et al. (2017) Affinity Selection-Mass Spectrometry Identifies a Novel Antibacterial RNA Polymerase Inhibitor. ACS Chem Biol 12:1346-1352
Maffioli, Sonia I; Zhang, Yu; Degen, David et al. (2017) Antibacterial Nucleoside-Analog Inhibitor of Bacterial RNA Polymerase. Cell 169:1240-1248.e23
Lin, Wei; Mandal, Soma; Degen, David et al. (2017) Structural Basis of Mycobacterium tuberculosis Transcription and Transcription Inhibition. Mol Cell 66:169-179.e8
Yu, Libing; Winkelman, Jared T; Pukhrambam, Chirangini et al. (2017) The mechanism of variability in transcription start site selection. Elife 6:
Bird, Jeremy G; Nickels, Bryce E; Ebright, Richard H (2017) RNA Capping by Transcription Initiation with Non-canonical Initiating Nucleotides (NCINs): Determination of Relative Efficiencies of Transcription Initiation with NCINs and NTPs. Bio Protoc 7:

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