Matthew J. Tucker
Physical Chemistry, Chemical Physics, Biophysical Chemistry
B.S., B.A. (2000), University of Scranton; Ph.D. (2006), University of Pennyslvania (Feng Gai); Postdoctoral (2006-2011), University of Pennsylvania (Robin M. Hochstrasser); (2012-2013) NIH BTRC Ultrafast Optical Processes Laboratory Staff Scientist.
Office: CB 230
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Matthew J. Tucker
A major thrust of my research focuses on the development and application of novel, ultrafast laser spectroscopy techniques to observe the interplay of structure and dynamics in biologically relevant systems. Femtosecond (10-15 s) laser pulses will be employed to explore new linear and nonlinear infrared spectroscopic properties of molecular systems. Initiation methods, such as optical triggering, in conjunction with two-dimensional infrared (2D IR) spectroscopy will be used to acquire atomic level structural information to generate snapshots of the structural evolution in various biophysical events. Such research provides an atomistic window into drug action, protein motion and folding events, the dynamical behavior of membrane proteins, or the fast folding of RNAs, all pivotal to combat prevalent diseases and to guide drug discovery.
2D IR photon echo experiments, through a detailed analysis of spectral lineshapes, cross-peaks, and time dependent changes of the spectral signatures, allow for a direct observation of site-specific events by measuring couplings between vibrations, the appearance of energy transfer, spectral diffusion or chemical exchange events. My research will develop and utilize a variety of current and novel infrared markers as spectroscopic rulers that will deliver site-specific structural changes and their time dependence. In addition, the 2D IR spectral dynamics of the vibrational markers allow detection of the properties of water local to the regions of interest. Spectral simulation will bring the results of these novel experimental techniques into relationship with theory, such as molecular dynamics and quantum mechanics.
Students in my group will be exposed to both, hands-on experimental laser-based research as well as the application of theory to understand the spectroscopy. They have the opportunity to work with modern ultrafast laser techniques and learn how such experiments can be applied to understand intrinsic biophysical questions. Other spectroscopic techniques, such as circular dichroism, absorption, fluorescence, and vibrational spectroscopy will be utilized.
Tucker, M.J., Abdo, M., Courter, J.R., Chen, J., Brown, S.P., Smith III, A.B., Hochstrasser, R.M.; “Nonequilibrium Dynamics of Helix Reorganization Observed by Transient 2D IR Spectroscopy”, Proc. Natl. Acad. Sci. U.S.A. 2013, 110, 17314-17319.
M. J. Tucker, M. Abdo, J. R. Courter, J. Chen, A. B. Smith III, R. M. Hochstrasser. Dicysteine S,S-tetrazine: A potential ultra-fast photochemical trigger to explore the early events of peptide/protein folding. J Photochem. Photobiol. A: Chemistry, 2012, 234, 156-163.
A. Ghosh, M. J. Tucker, R. M. Hochstrasser. The identification of arginine residues in peptides by 2D-IR echo spectroscopy. J Phys. Chem. A, 2011, 115, 9731-9738.
M. J. Tucker, X. S. Gai, E. F. Fenlon, S. Brewer, and R. M. Hochstrasser. 2DIR Photon Echo of Azido- Probes for Nucleic Acids. Physical Chemistry Chemical Physics, 2011, 13, 2237-2241.
M. J. Tucker, J. R. Courter, J. Chen, O. Atasoylu, A. B. Smith III and R. M. Hochstrasser. Tetrazine Phototriggers: Probes of Protein Dynamics. Angewandte Chemie, 2010, 49, 3612-3616. Communication Cover Article (Highlighted in April 26, 2010 issue of Chemical and Engineering News)
M. J. Tucker, A.L. Serrano, F. Gai. Direct Assessment of the alpha-Helix Nucleation Time. J Phys. Chem. B, 2011, 115, 7472-7478.
M. J. Tucker, Y. S. Kim, and R. M. Hochstrasser. 2D IR photon echo study of anharmonic coupling in the OCN region of phenyl cyanate. Chemical Physics Letters, 2009, 470, 80-84.
A. Ghosh, A. Remorino, M. J. Tucker, R. M. Hochstrasser. 2D IR photon echo spectroscopy reveals hydrogen bond dynamics in aromatic nitriles. Chemical Physics Letters, 2009, 469, 325-330.
M. M. Waegele, M. J. Tucker, and F. Gai. 5-Cyanotryptophan as infrared probe of local hydration status in proteins. Chemical Physics Letters, 2009, 478, 249-253.
M. J. Tucker, R. Oyola, and F.Gai. Exploring the feasibility of using p-cyano-phenylalanine as a sensitive fluorescent probe in binding and folding. Biopolymers, 2006, 83, 571-576.
M. J. Tucker, J. Tang, and F. Gai. A new method to probe the membrane-assisted helix folding dynamics. J. Phys. Chem B, 2006, 110, 8105-8109.
M. J. Tucker, R. Oyola, and F. Gai. Conformational distribution of a 14-residue peptide in solution: A FRET study. J. Phys. Chem. B, 2005, 109, 4788–4785.
M. J. Tucker, Z. Getahun, V. Nanda, W.F. DeGrado, and F. Gai. A new method for determining the conformation and orientation of membrane-binding peptides. J. Am. Chem. Soc., 2004, 126, 5078–5079.