PROJECT SUMMARY/ABSTRACT In this MIRA program, we aim to gain atomic-level insights into complex biological systems such as bacterial membrane proteins and light-sensitive proteins with particular emphasis on their native protein and lipid environments. We will test the impact of such biochemical environments in two distinct projects. A wide variety of toxic chemicals, including toxic metal oxides and hydroxides, pollute our environment, posing an imminent threat to human life. One can leverage the unique respiration mechanism in marine microbes like Shewanella to revolutionize bioremediation and wastewater treatment technology. Molecular modeling and computations will provide an atomic-scale comprehension of the mechanism that will augment macroscale experimental observables. In the first project, we will model the outer membrane cytochrome-porin complex of Shewanella oneidensis in its native environment and obtain molecular insights into the charge-transfer network employed in its respiration. Electronically excited-state processes are ubiquitous in nature and biotechnology. For example, blue-light-sensitive proteins are used in the optogenetic control of cellular processes. Fluorescent proteins with emissions spanning the entire visible region are often utilized for in vivo imaging. In these applications, subtle structural changes in an electronically excited molecule induce pronounced conformational changes in the nearby protein environment or further from its location (allostery). Therefore, the biochemical environment relays the information at the photon-absorption site to another site. Most conformational changes occur well beyond a few nanoseconds, making them inaccessible to modern multi-scale quantum mechanics/molecular mechanics (QM/MM) techniques. Therefore, in the second project, we will build a tool to model excited states of biomolecules using force field parameters and then validate those parameters using a few case studies with fluorescent proteins. Furthermore, we will use those parameters to decipher photoinduced allosteric pathways in blue-light-sensitive proteins.

PROJECT NARRATIVE Biochemistry does not occur in a vacuum. Several molecules, ions, and biomolecules gather to create an optimal biochemical environment required for any biochemical process to occur. In this proposed research, we will investigate the impact of such a biochemical environment on the metal "breathing" machinery of marine bacteria and photoinduced allosteric processes with potential applications in bioremediation and optogenetics technologies.