Protein Dynamics of the Sensor Protein HemAT as Probed by Time-Resolved Step-Scan FTIR Spectroscopy (original) (raw)
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Primary processes in heme-based sensor proteins
Biochimica et Biophysica Acta (BBA) - Proteins and Proteomics, 2013
A wide and still rapidly increasing range of heme-based sensor proteins has been discovered over the last two decades. At the molecular level, these proteins function as bistable switches in which the catalytic activity of an enzymatic domain is altered mostly by binding or dissociation of small gaseous ligands (O 2 , NO or CO) to the heme in a sensor domain. The initial "signal" at the heme level is subsequently transmitted within the protein to the catalytic site, ultimately leading to adapted expression levels of specific proteins. Making use of the photolability of the heme-ligand bond that mimics thermal dissociation, early processes in this intra-protein signaling pathway can be followed using ultrafast optical spectroscopic techniques; they also occur on timescales accessible to molecular dynamics simulations. Experimental studies performed over the last decade on proteins including the sensors FixL (O 2 ), CooA (CO) and soluble guanylate cyclase (NO) are reviewed with an emphasis on emerging general mechanisms. After heme-ligand bond breaking, the ligand can escape from the heme pocket and eventually from the protein, or rebind directly to the heme. Remarkably, in all sensor proteins the rebinding, specifically of the sensed ligand, is highly efficient. This "ligand trap" property possibly provides means to smoothen the effects of fast environmental fluctuations on the switching frequency. For 6-coordinate proteins, where exchange between an internal heme-bound residue and external gaseous ligands occurs, the study of early processes starting from the unliganded form indicates that mobility of the internal ligand may facilitate signal transfer. This article is part of a Special Issue entitled: Oxygen Binding and Sensing Proteins.
Biochemistry, 2007
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 µs 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 µs. † This work is supported by NIH Grants GM036452 and RR07707 (BioCARS). ‡ Coordinates and structure factors have been deposited in the Protein Data Bank under ID codes 2OWJ and 2OWH.
Biopolymers, 2004
It is shown by using the vibronic approach that the iron displacement out of the porphyrin plane in deoxyheme proteins intermixes the porphyrin and axial iron-histidine electronic subsystems. This intermixing explains the substantial coupling of the iron-histidine vibration to the heme Soret excitation, the appearance of the iron-histidine band in the corresponding resonance Raman spectra, and a number of other experimental data, including the dependence of the iron-histidine vibrational frequency on the extent of the iron displacement out of the porphyrin plane. This dependence implies that there is an anharmonic coupling between the corresponding vibrations, which is shown to be the cause of the specific temperature dependence of the iron-histidine band. The anharmonic coupling and the dependence of the dipole transition moment of the charge transfer optical absorption band III on the iron-porphyrin distance cause the anomalous temperature and pressure dependencies of this band. It is shown that the change in both the magnitude and the distribution of the iron-porphyrin distance is expected to affect the band III intensity. Consequently, the stationarity of the band III intensity can be considered as a signature of the stationarity of the iron-porphyrin distance and its distribution in deoxyheme proteins, whereas the band III position and width could be also affected by the change in the protein electric field, caused by the protein globule dynamics.
Journal of Biological Chemistry, 2009
Dos from Escherichia coli is a bacterial gas sensor protein comprising a heme-containing gas sensor domain and a phosphodiesterase catalytic domain. Using a combination of static light scattering and gel filtration experiments, we established that, as are many other sensor proteins, the full-length protein is dimeric. The full-length dimer (association constant <10 nM) is more stable than the dimeric heme domain (association constant ϳ1 M), and the dimer interface presumably includes both sensor and catalytic domains. Ultrafast spectroscopic studies showed little influence of the catalytic domain on kinetic processes in the direct vicinity of the heme. By contrast, the properties of ligand (CO and O 2 ) binding to the heme in the sensor domain, occurring on a microsecond to second time scale, were found to be influenced by i) the presence of the catalytic domain, (ii) the dimerization state, and in dimers, (iii) the ligation state of the other subunit. These results imply allosteric interactions within dimers. Steady-state titrations demonstrated marked cooperativity in oxygen binding to both the full-length protein and the isolated heme domain, a feature not reported to date for any dimeric sensor protein. Analysis of a variety of time-resolved experiments showed that Met-95 plays a major role in the intradimer interactions. The intrinsic binding and dissociation rates of Met-95 to the heme were modulated ϳ10-fold by intradimer and sensor-catalytic domain interactions. Dimerization effects were also observed for cyanide binding to the ferric heme domains, suggesting a similar role for Met-95 in ferric proteins. . 4 The abbreviations used are: EcDos, E. coli direct oxygen sensor; EcDosH, heme sensor domain of EcDos; FixLH, heme sensor domain of FixL; PBS, phosphate-buffered saline; MALLS, multi-angle laser light scattering.
Non-exponential non-Arrhenius relaxation in the course of CO rebinding to heme proteins
Chemical Physics, 1995
The dispersive transport model for relaxation of photolyzed heme proteins has been improved to take into account the coupling of the ligand-heme geminate recombination and the non-Gaussian diffusive dynamics of conformational changes in heme proteins. Contrary to the earlier deterministic version of the model, the present more rigorous formulation is based on the stochastic approach to the problem, This implies that the time evolution of protein conformations should be described in terms of the transient distribution which satisfies the Smoluchowski-type differential equation with a time-dependent diffusion coefficient. The obtained analytical solution of this equation enables us to relate main kinetic parameters of the geminate recombination and quantities characterizing the ligand-heme interaction. The derived expressions demonstrate that the reaction barrier shifts with time towards higher values following the near-stretched exponential behavior in agreement with experiment. Such a behavior is governed by the non-exponential non-Arrhenius conformational relaxation. The latter process can be identified by the characteristic "footprint" left on the experimental rebinding curve and is shown to be responsible for some kinetically different phases of the ligand-heme geminate recombination observed within distinct temperature ranges.
Protein dynamics. Comparative investigation on heme-proteins with different physiological roles
Biophysical Journal, 1991
We report the low temperature carbon monoxide recombination kinetics after photolysis and the temperature dependence of the visible absorption spectra of the isolated aSH_CO and 13SH-CO subunits from human hemoglobin A in ethylene glycol/water and in glycerol/water mixtures. Kinetic measurements on sperm whale (Physeter catodon) myoglobin and previously published optical spectroscopy data on the latter protein and on human hemoglobin A, in both solvents, (Cordone, L., A. Cupane, M. Leone, E. Vitrano, and D. Bulone. 1988. J. Mol. Biol. 199:312-218) are taken as reference.
Proceedings of the National Academy of Sciences, 2002
Heme-based oxygen sensors are part of ligand-specific two-component regulatory systems, which have both a relatively low oxygen affinity and a low oxygen-binding rate. To get insight into the dynamical aspects underlying these features and the ligand specificity of the signal transduction from the heme sensor domain, we used femtosecond spectroscopy to study ligand dynamics in the heme domains of the oxygen sensors FixL from Bradyrhizobium japonicum (FixLH) and Dos from Escherichia coli (DosH) . The heme coordination with different ligands and the corresponding ground-state heme spectra of FixLH are similar to myoglobin (Mb). After photodissociation, the excited-state properties and ligand-rebinding kinetics are qualitatively similar for FixLH and Mb for CO and NO as ligands. In contrast to Mb, the transient spectra of FixLH after photodissociation of ligands are distorted compared with the ground-state difference spectra, indicating differences in the heme environment with respect ...
Journal of Biological Chemistry, 2008
In the heme-based sensor Dos from Escherichia coli, the ferrous heme is coordinated by His-77 and Met-95. The latter residue is replaced upon oxygen binding or oxidation of the heme. Here we investigate the early signaling processes upon dissociation of the distal ligand using ultrafast spectroscopy and sitedirected mutagenesis. Geminate CO rebinding to the heme domain DosH appears insensitive to replacement of Met-95, in agreement with the notion that this residue is oriented out of the heme pocket in the presence of external ligands. A uniquely slow 35-ps phase in rebinding of the flexible methionine side chain after dissociation from ferrous DosH is completely abolished in rebinding of the more rigid histidine side chain in the M95H mutant protein, where only the 7-ps phase, common to all 6-coordinate heme proteins, is observed. Temperature-dependence studies indicate that all rebinding of internal and external ligands is essentially barrierless, but that CfigsO escape from the heme pocket is an activated process. Solvent viscosity studies combined with molecular dynamics simulations show that there are two configurations in the ferrous 6-coordinate protein, involving two isomers of the Met-95 side chain, of which the structural changes extend to the solvent-exposed backbone, which is part of the flexible FG loop. One of these configurations has considerable motional freedom in the Met-95-dissociated state. We suggest that this configuration corresponds to an early signaling intermediate state, is responsible for the slow rebinding, and allows small ligands in the protein to efficiently compete for binding with the heme.
Protein Science, 2005
Amide hydrogen exchange (HX) in combination with mass spectrometry (MS) is a powerful tool to analyze the folding and dynamics of proteins. In the traditional methodology the exchange time is controlled by manual pipetting, thereby limiting the time resolution to several seconds. Some conformational changes in proteins, however, occur in the subsecond time scale, making it desirable to perform HX at shorter time intervals down to the limit set by the intrinsic chemical exchange rate. We now report the development of the first completely on-line quenched-flow setup that allows the performance of HX experiments in the 100-sec to 30-sec time scale, on-line proteolytic digestion using immobilized proteases, rapid desalting, and MS analysis. We show that conformational fluctuations in the range of seconds can be detected and protection factors as small as 10 reproducibly determined. Using this setup we investigated the conformational properties of Escherichia coli heat-shock transcription factor σ32 free in solution. Our results indicate that the C-terminal σ4 domain of σ32, which is responsible for the recognition of the −35 region of heat shock promoters, contains more extensive secondary structure than expected when compared with the structure of the homologous σ-factor σA in complex with the RNA-polymerase. This setup should be very useful for a more accurate analysis of structural motions in proteins in the subsecond to second time scale relevant to allostery and enzyme function.