Philip Bevilacqua

Research

2022   Keynote Speaker, Northwestern University T32 Training Grant Symposium

2020   Keynote Speaker, Bermuda Principles

2019   Swiss RNA Biology Programme Speaker at ETH Zurich and University of Bern

2019   Keynote Speaker, International Symposium RNA Tool and Target. Duke University, Durham, NC

2018   Gomberg Lecturer, U Michigan, Ann Arbor MI

2018   Keynote Speaker, CMBP/RNA Biology Symposium, Ohio State University

2018   Distinguished Professor, Penn State

2016   Keynote Speaker, Zing Nucleic Acids Conference, Tampa, FL

2013   Keynote Speaker, RNA Upstate NY: Finger Lakes RNA Conference

2010   Faculty Scholar Medal in Physical Sciences, Penn State

2009   Elected Fellow of American Association for Advancement of Science (AAAS)

2001 - 2006   Camille Dreyfus Teacher-Scholar

2001 - 2006   Alfred P. Sloan Foundation Fellow

2000 - 2005   National Science Foundation (NSF), Faculty Career Development (CAREER) Award

Teaching

2020   Alumni/Student Award for Excellence in Teaching, Penn State University-wide

2018   Priestley Teaching Prize, Penn State Chemistry

2015   CESE Tombros Education Fellow, Penn State

2012   C.I. Noll Award for Excellence in Teaching, Penn State Eberly College

2010 - 2012   Distinguished Honors Faculty Fellow, Penn State Schreyer Honors College

Research

Our lab works to attain a molecular level understanding of RNA in biology. We find RNA fascinating because it is a both a structural and informatic molecule. RNA is single stranded and so folds back on itself. This leads it to adopt simple secondary structures such as stem-loops, as well as complex tertiary structures with clefts that bind small molecules specifically and tightly (riboswitches) and catalyze reactions (ribozymes). This diversity of structures gives rise to diversity of functions including the ability of RNA to regulate genes.

Ribozyme Mechanism

In the early 1980s, Tom Cech and Sidney Altman showed that RNA could act as an enzyme–a ‘ribozyme’–catalyzing the making and breaking of covalent bonds. This led to the 1989 Nobel Prize in Chemistry. The Bevilacqua lab helped establish roles for nucleobases in proton transfer, determination of driving forces for pKa shifting, and establishing multichannel pathways for RNA cleavage by a combination of experiments and classical and quantum mechanical theory. We are currently working in the twister and other ribozymes to determine roles of metal ions, nucleobases, and cofactors in the mechanism of cleavage of the catalytic RNAs.In addition, the lab is focused on how these RNAs fold under in vivo conditions.

RNA Folding In Vivo

Folding of RNA in the cell is not well understood nor has it been integrated into a cohesive mechanistic framework. We are taking two approaches to understanding RNA folding in vivo: (1) Simulating in vivo conditions and examining the RNA folding pathways and the evolutionary driving forces for these, and (2) Determining RNA folding transcriptome-wide in living organisms (plants, bacteria, and archaea) and evaluating implications of this folding on gene regulation and RNA processing. The former project has the advantage that one can precisely control experimental variable such as crowding, cosolutes, and ionic conditions on RNA folding, while the latter allows observations to be made made directly in a living organism. We collaborate with Professors Sally Assmann and Paul Babitzke in the in vivo work.

Early Earth and RNA

One of the great questions facing humanity is “How did life begin?” It is thought that RNA may have played a major role in the process through the so-called RNA world hypothesis. We are collaborating with Christine Keating’s lab at Penn State to address physical means that may have aided the emergence of life through the localization and improvement of catalysis. We are evaluating compartmentalization driven by aqueous phase separation as a potential physicochemical mechanism to concentrate and help chaperone the folding, multiple turnover, and evolution of rare catalytic RNA molecules. We are also addressing how compartmentalization may facilitate the assembly of progenitor membranes as a step towards protocell formation. Accomplishing these goals will provide insight into the early evolution of life on this and other planets.

Recent Publications

Jolley, E. A., Yakhnin, H., Tack, D. C., Babitzke, P. & Bevilacqua, P. C. Transcriptome-wide probing reveals RNA thermometers that regulate translation of glycerol permease genes in Bacillus subtilis. RNA (in press) (2023). [PubMed].

Sieg J.P., Arteaga S.J., Znosko B.M., Bevilacqua PC. Meltr software provides facile determination of nucleic acid thermodynamics. Biophys Rep 3, 100101 (2023). [PubMed].

Sieg, J. P., McKinley, L. N., Huot, M. J., Yennawar, N. H., Bevilacqua, P. C. The metabolome weakens RNA thermodynamic stability and strengthens RNA chemical stability. Biochemistry 61, 2579-2591 (2022). [PubMed].

Yamagami, R., Sieg, J., Assmann, S. A., Bevilacqua, P. C. Genome-wide analysis of the in vivo tRNA structurome reveals RNA structural and modification dynamics under heat stress. Proc. Natl. Acad. Sci. 119, e2201237119 (2022). [PubMed].

Choi, S., Meyer, M. O., Bevilacqua, P. C., Keating, C. D. Phase-specific RNA accumulation and duplex thermodynamics in multiphase coacervate models for membraneless organelles. Nature Chem. 14, 1110-1117 (2022). [PubMed].

Bevilacqua, P. C., Williams, A. M., Chou, H. L., Assmann, S. M. RNA multimerization as an organizing force for liquid-liquid phase separation. RNA 28, 16-26 (2022). [PubMed].

Veenis, A. J., Li, P., Soudackov, A. V., Hammes-Schiffer, S., Bevilacqua, P. C. Investigation of the pK_aof the nucleophilic O2' of the hairpin ribozyme. J. Phys. Chem. B. 43, 11869-11883 (2021). [PubMed].

Leamy, K. A., Yamagami, R., Yennawar, N., Bevilacqua, P. C. Single nucleotide control of tRNA folding cooperativity. Proc Natl. Acad. Sci. 116, 23075-23082 (2019). [PubMed].

Poudyal, R., Keating, C. D., Bevilacqua, P. C. Polyanion-assisted catalysis inside complex coacervates. ACS Chem. Biol. 14, 1243-1248 (2019). [PubMed].

Poudyal, R.R., Guth, R.M., Veenis, A.J., Frankel, E.A., Keating, C.D., Bevilacqua, P.C. Template-directed RNA polymerization and enhanced ribozyme catalysis inside membraneless compartments formed by coacervates. Nat. Commun. 10, 490 (2019) [PubMed] (open access).

Messina, KJ & Bevilacqua, PC. Cellular small molecules contribute to twister ribozyme catalysis. J. Am. Chem. Soc. 140, 10578-10582 (2018) [PubMed].