Web Release Date: March 27,
Time-Resolved Crystallographic Studies of the Heme Domain of the Oxygen Sensor
FixL: Structural Dynamics of Ligand Rebinding and Their Relation to
Signal Transduction
rajer,
and#
Department of Biochemistry and Molecular Biology, University of Chicago, Chicago, Illinois 60637, Consortium for Advanced Radiation Sources, and Institute for Biophysical Dynamics, University of Chicago, Chicago, Illinois 60637
Received January 10, 2007
Revised Manuscript Received February 16, 2007
Abstract:
The FixL protein of Bradyrhizobium japonicum is a dimeric oxygen sensor responsible for
initiating regulation of transcription of genes encoding proteins involved in nitrogen fixation and oxidative
stress. It consists of an N-terminal heme-bound PAS domain, denoted bjFixLH, and a C-terminal histidine
kinase domain whose enzymatic activity depends on the ligation state of the heme. To investigate the
molecular basis for this dependence and the dynamics associated with conversion between ligated and
unligated states, we have conducted time-resolved Laue diffraction studies of CO recombination in bjFixLH.
Time-dependent difference Fourier maps from 1 
s to 10 ms after photolysis of the heme-CO bond
show movement of the side chain of Leu236 and the H and I 
-strands into the ligand binding pocket
formerly occupied by CO. Long-range conformational changes are evident in the protein, driven by
relaxation of steric interactions between the bound ligand and amino acid side chains and/or changes in
heme stereochemistry. These structural changes fully reverse as CO rebinds to the heme. Spectroscopic
measurements of CO recombination kinetics in bjFixLH crystals relate the behavior of crystalline bjFixLH
to solution and provide a framework for our time-resolved crystallographic experiments. Analysis of the
time-dependent difference Fourier maps by singular value decomposition reveals that only one significant
singular value accounts for the data. Thus only two structural states are present, the photolyzed and the
CO-bound states. The first left singular vector represents the difference in density between these two
states and shows features common to difference maps calculated from the static CO and deoxy states.
The first right singular vector represents the time course of this difference density and agrees well with
the CO recombination kinetics measured spectroscopically. We refine the structure of the photolyzed
state present in the early-microsecond time range and find that it does not differ significantly in conformation
from static, deoxy bjFixLH. Thus, structural relaxation from CO-bound to deoxy bjFixLH is complete in
less than 1 s.
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