Ultraviolet Photodissociation Mass Spectrometry for Characterization of Biological Molecules

Abstract. Understanding the functions of lipids, proteins and even larger macromolecular assemblies depends on deciphering complex structures of individual molecules as well as decrypting how those molecules interact, often via networks of non-covalent interactions. In order to advance the elucidation of

biomolecular organization and functional outcomes, new methods are needed to push the limits of structural insight, providing more detailed holistic chemical information with greater sensitivity. The critical interplay between structure/function is evidenced in numerous biologically-motivated problems, ranging

from understanding the ways that pathogenic bacteria develop antibiotic resistance to the design of new drugs that selectively bind and inhibit the functions of protein targets. The ongoing need for even greater chemical insight has motivated my group’s effort to develop innovative mass spectrometry methods to

characterize structures of biological molecules in unprecedented detail, especially lipids and proteins which are featured in this proposal. The overarching goal of my research program is to develop state-of- the-art tandem mass spectrometry technologies, particularly highlighting ultraviolet photodissociation

(UVPD) and hybrid MS/MS methods, for structural elucidation of lipids, proteins, and protein complexes. These new methods will be showcased for solving challenging problems in three areas. (1) Lipids: (i) profiling lipids of pathogenic bacteria and their signatures of antibiotic resistance, and (ii) structural

characterization of unsaturations, oxidations and other modifications of lipids that occur during remodeling of cellular membranes. (2) Protein complexes: (i) characterization of protein-ligand complexes, membrane protein complexes, protein/nucleic acid complexes, and macromolecular assemblies, and (ii) advancing capillary electrophoresis for native separations and exploration of the

interactome. (3) Post-translational modifications: focusing on decoding the phosphorylation patterns of the C-terminal domain of RNA polymerase II which regulates transcription. These high impact problems are supported via numerous collaborations with microbiology and molecular biology groups who recognize the value of frontier mass spectrometry strategies for elevating biomedical research.