C Bertolucci1, L J Ming, G Gonzalez, M A Gilles-Gonzalez. 1. Department of Chemistry and Institute for Biomolecular Science, University of South Florida, 4202 East Fowler Avenue, CHE305, Tampa, FL 33620-5250, USA. ming@chuma.cas.usf.edu
Abstract
BACKGROUND: [corrected] The Rhizobial oxygen sensor FixL is a hemoprotein with kinase activity. On binding of strong-field ligands, a change of the ferrous or ferric heme iron from high to low spin reversibly inactivates the kinase. This spin-state change and other information on the heme pocket have been inferred from enzymatic assays, absorption spectra and mutagenesis studies. We set out to investigate the spin-state of the FixL heme and to identify the hyperfine-shifted heme-proton signals by NMR spectroscopy. RESULTS: Using one-dimensional NMR we directly observed the high- and low-spin nature of the met- and cyanomet-FixL heme domain, respectively. We determined the hyperfine-shifted 1H-NMR signals of the heme and the proximal histidine by one- and two-dimensional spectroscopy and note the absence of distal histidine signals. CONCLUSIONS: These findings support the spin-state mechanism of FixL regulation. They establish that the site of heme coordination is a histidine residue and strongly suggest that a distal histidine is absent. With a majority of the heme resonances identified, one- and two-dimensional NMR techniques can be extended to provide structural and mechanistic information about the residues that line the heme pocket.
BACKGROUND: [corrected] The Rhizobial oxygen sensor FixL is a hemoprotein with kinase activity. On binding of strong-field ligands, a change of the ferrous or ferric hemeiron from high to low spin reversibly inactivates the kinase. This spin-state change and other information on the heme pocket have been inferred from enzymatic assays, absorption spectra and mutagenesis studies. We set out to investigate the spin-state of the FixL heme and to identify the hyperfine-shifted heme-proton signals by NMR spectroscopy. RESULTS: Using one-dimensional NMR we directly observed the high- and low-spin nature of the met- and cyanomet-FixL heme domain, respectively. We determined the hyperfine-shifted 1H-NMR signals of the heme and the proximal histidine by one- and two-dimensional spectroscopy and note the absence of distal histidine signals. CONCLUSIONS: These findings support the spin-state mechanism of FixL regulation. They establish that the site of heme coordination is a histidine residue and strongly suggest that a distal histidine is absent. With a majority of the heme resonances identified, one- and two-dimensional NMR techniques can be extended to provide structural and mechanistic information about the residues that line the heme pocket.
Authors: Guilherme Razzera; Javier Vernal; Debora Baruh; Viviane I Serpa; Carolina Tavares; Flávio Lara; Emanuel M Souza; Fábio O Pedrosa; Fábio C L Almeida; Hernán Terenzi; Ana Paula Valente Journal: J Biol Inorg Chem Date: 2008-06-12 Impact factor: 3.358