Abstract

The ultimate goal of this research is to characterize the interactions directing RNA folding, and to use this knowledge to predict reliably the structures of RNA molecules from their sequences. Since most diseases are mediated through RNA, and some viruses, including HIV, have RNA genomes with largely unknown secondary structures, our results can lead to rational design of therapeutics. The ability to predict RNA structure should also further the interpretation of sequences determined by the Human Genome Project and other sequencing efforts. Our results may also contribute to fighting bioterrorism because they potentially provide a rapid way to design therapeutics, including siRNA and antisense compounds, once a genome has been sequenced. The foundation for structure prediction will be advanced by studies of the thermodynamic and structural properties of oligonucleotides. Particular emphasis will be placed on the sequence dependence of stability and structure for internal loops. New collaborations with computational chemists will provide insight into the interactions determining both secondary and local three dimensional structure. Secondary structure prediction by free energy minimization will be augmented with constraints from sequence comparison, chemical mapping, oligonucleotide binding, and NMR to partially compensate for incomplete knowledge of the factors affecting folding. In particular, new microarray and nanoparticle methods will be developed to measure and interpret binding of chemically modified pentamers and hexamers to folded RNA. The foundation will be laid for design of a universal microarray that can be used to interrogate the structure of any RNA. The chemical mapping and microarray methods identify nucleotides that are not in Watson-Crick pairs. The new NMR assisted prediction of secondary structure (NAPSS) method uses unassigned spectra to further restrict folding space by identifying regions of canonical base pairs, including pseudoknots. The power of the predictive methods will be tested by attempting to determine the secondary structure of 323 nucleotides of the 5'coding region of an R2 retrotransposon. In 2006, it was discovered that this region of R2 RNA has a novel function of temporally orchestrating second strand DNA cleavage by R2 protein during insertion of the sequence into a genome. Initial results indicate that the RNA contains a novel pseudoknot. Project Narrative (Relevance) Most diseases are mediated through RNA, and some viruses, including HIV, have RNA genomes. The goal of this research is to be able to predict reliably the structure of an RNA from its sequence in order to provide a foundation for rational design of therapeutics targeting RNA. The results may also help fight bioterrorism because they potentially provide a rapid way to design therapeutics once a genome has been sequenced.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM022939-35
Application #
7904792
Study Section
Macromolecular Structure and Function B Study Section (MSFB)
Program Officer
Preusch, Peter C
Project Start
1979-03-01
Project End
2012-07-31
Budget Start
2010-08-01
Budget End
2011-07-31
Support Year
35
Fiscal Year
2010
Total Cost
$501,486
Indirect Cost

  Institution

Name
University of Rochester
Department
Chemistry
Type
Schools of Arts and Sciences
DUNS #
041294109
City
Rochester
State
NY
Country
United States
Zip Code
14627

  Publications

Berger, Kyle D; Kennedy, Scott D; Schroeder, Susan J et al. (2018) Surprising Sequence Effects on GU Closure of Symmetric 2 × 2 Nucleotide RNA Internal Loops. Biochemistry 57:2121-2131
Smith, Louis G; Zhao, Jianbo; Mathews, David H et al. (2017) Physics-based all-atom modeling of RNA energetics and structure. Wiley Interdiscip Rev RNA 8:
Pinamonti, Giovanni; Zhao, Jianbo; Condon, David E et al. (2017) Predicting the Kinetics of RNA Oligonucleotides Using Markov State Models. J Chem Theory Comput 13:926-934
Kauffmann, Andrew D; Kennedy, Scott D; Zhao, Jianbo et al. (2017) Nuclear Magnetic Resonance Structure of an 8 × 8 Nucleotide RNA Internal Loop Flanked on Each Side by Three Watson-Crick Pairs and Comparison to Three-Dimensional Predictions. Biochemistry 56:3733-3744
Lenartowicz, Elzbieta; Nogales, Aitor; Kierzek, Elzbieta et al. (2016) Antisense Oligonucleotides Targeting Influenza A Segment 8 Genomic RNA Inhibit Viral Replication. Nucleic Acid Ther 26:277-285
Lenartowicz, Elzbieta; Kesy, Julita; Ruszkowska, Agnieszka et al. (2016) Self-Folding of Naked Segment 8 Genomic RNA of Influenza A Virus. PLoS One 11:e0148281
Gleghorn, Michael L; Zhao, Jianbo; Turner, Douglas H et al. (2016) Crystal structure of a poly(rA) staggered zipper at acidic pH: evidence that adenine N1 protonation mediates parallel double helix formation. Nucleic Acids Res 44:8417-24
Jiang, Tian; Nogales, Aitor; Baker, Steven F et al. (2016) Mutations Designed by Ensemble Defect to Misfold Conserved RNA Structures of Influenza A Segments 7 and 8 Affect Splicing and Attenuate Viral Replication in Cell Culture. PLoS One 11:e0156906
Condon, David E; Kennedy, Scott D; Mort, Brendan C et al. (2015) Stacking in RNA: NMR of Four Tetramers Benchmark Molecular Dynamics. J Chem Theory Comput 11:2729-2742
Chen, Jonathan L; Kennedy, Scott D; Turner, Douglas H (2015) Structural features of a 3' splice site in influenza a. Biochemistry 54:3269-85

Showing the most recent 10 out of 162 publications