Structure, Flexibility, And Overall Motion Of Transmembrane Peptides Studied By NMR Spectroscopy And Molecular Dynamics Simulations

Abstract

Nuclear magnetic resonance (NMR) spectroscopy was used to determine the structure of transmembrane (TM) segment IX of the Na+/H+ exchanger isoform 1 (NHE1) in dodecylphosphocholine micelles. Studying isolated TM segments in this fashion constitutes a well-established "divide and conquer" approach to the study of membrane proteins, which are often extremely difficult to produce, purify, and reconstitute in full-length polytopic form. A similar approach was combined with NMR spin relaxation experiments to determine the peptide backbone flexibility of NHE1 TM VII. The combined NMR structural and dynamics studies are consistent with an important role for TM segment flexibility in the function of NHE1, a protein involved in apoptosis and myocardial disease. The study of the rhomboid protease system is also described from two perspectives: 1) I attempted to produce several TM constructs of the substrate spitz or a related construct and the production and purification are described in detail; and 2) I present coarse-grained molecular dynamics simulation results for the E. coli rhomboid ecGlpG and a spitz TM construct. Spitz appears to preferentially associate with rhomboid near TMs 1 and 3 rather than the proposed substrate gate at TM 5. The two proteins primarily interact at the termini of helices rather than within the hydrocarbon core of the bilayer. Finally, I present a detailed analysis of coarse-grained molecular dynamics simulations of the fibroblast growth factor receptor 3 TM domain dimerization. Specifically, algorithms are described for analyzing critical features of wild-type and G380R mutant constructs. The G380R mutation is the cause of achondroplasia, the most common form of human dwarfism. The results suggest that the proximity of a residue to the dimer interface may impact the severity of the mutant phenotype. Strikingly, heterodimer and mutant homodimer constructs exhibit a secondary dimer interface which may explain the increased signaling activity previously reported for the G380R mutation--the helices may rotate with the introduction of G380R. The unifying theme of this work is the 'study of membrane proteins' using complementary techniques from structural biology and computational biochemistry.