Cytochromes serve as electron carriers in a wide variety of biochemical processes including respiration, photosynthesis, nitrite reduction and surface reduction. Because cytochromes have a key role in biological processes, it is important to understand the factors which control both the rates and specificities of their electron transfer. We will address two questions in this area: How does the protein control its redox potential (and, thus, the driving force for electron transfer) and, what are the role of electrostatic interactions in determining the rate of electron transfer? Four factors have been proposed to control the redox potential of the heme, but have not yet been tested in detail: hydrogen bonding or deprotonation of the axial histidine NH proton, hydrogen bonding or deprotonation of one of the propionic acid side chains, changes in the axial ligand-heme bond angles and distances, and the distribution of charged groups around the heme. We propose to synthesize chelated model hemes to test each of these aspects of heme chemistry. In addition, we propose a series of experiments to delineate some of the factors which control the NMR spectra of cytochromes, and heme proteins in general. Much structural information has been obtained from NMR. A clearer understanding of the factors which affect heme protein NMR will make this an even more powerful tool. Electrostatic interactions may be a major determinant of the rate of electron transfer in heme proteins. If so, electron self-exchange rate constants (cyta+3+cytb+3=cyta+2+cytb+3) will be a function of the distribution of charges on the surface of the heme. This distribution can be altered by functionalizing a cytochrome with a wide variety of reagents. We will measure the rate of electron self-exchange of cytochromes functionalized at specific amino acid residues. Our long term goal in both the model and the protein experiments is to elucidate the factors which govern heme protein biochemistry and spectroscopy.

Agency
National Institute of Health (NIH)
Institute
National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK)
Type
Research Project (R01)
Project #
7R01DK038826-01
Application #
3238342
Study Section
Metallobiochemistry Study Section (BMT)
Project Start
1986-09-01
Project End
1988-08-31
Budget Start
1986-09-01
Budget End
1987-08-31
Support Year
1
Fiscal Year
1986
Total Cost
Indirect Cost
Name
Georgia State University
Department
Type
Schools of Arts and Sciences
DUNS #
837322494
City
Atlanta
State
GA
Country
United States
Zip Code
30302
Imig, John D; Ryan, Michael J (2013) Immune and inflammatory role in renal disease. Compr Physiol 3:957-76
Lee, Craig R; Imig, John D; Edin, Matthew L et al. (2010) Endothelial expression of human cytochrome P450 epoxygenases lowers blood pressure and attenuates hypertension-induced renal injury in mice. FASEB J 24:3770-81
Imig, John D (2008) Eicosanoids and renal damage in cardiometabolic syndrome. Expert Opin Drug Metab Toxicol 4:165-74
Shoshani, I; Qui, H; Johnson, F et al. (1995) Azido-iodo-phenyl-analogs of 2',5'-dideoxy-adenosine as photoaffinity ligands for adenylyl cyclase. Biochim Biophys Acta 1245:37-42
Dixon, D W; Hong, X; Woehler, S E (1989) Electrostatic and steric control of electron self-exchange in cytochromes c, c551, and b5. Biophys J 56:339-51
Dixon, D W; Amis, L; Kim, M S et al. (1989) Characterization and purification of iron porphyrins by high-performance liquid chromatography and column chromatography. J Chromatogr 462:411-8
Timkovich, R; Cai, M L; Dixon, D W (1988) Electron self-exchange in Pseudomonas cytochromes. Biochem Biophys Res Commun 150:1044-50