Crystal structures of deoxy and CO-bound bjFixLH reveal details of ligand recognition and signaling

Rhizobia directly regulate the expression of genes required for symbiotic nitrogen fixation in response to oxygen concentration via the sensor protein FixL. The N-terminal PAS domain of FixL contains a histidine-coordinated heme and regulates the activity of its effector domain, a C-terminal histidine kinase, in response to binding of oxygen and other ligands at the heme. To further investigate ligand-induced inhibition of FixL, we have determined the crystal structures of the heme domain in both the deoxy state and bound to carbon monoxide, a weak inhibitor of FixL kinase activity. Structures collected at room temperature are presented in each state from two crystallographic space groups at 1.8 and 2 A resolution. These structures reveal displacement of the residues of the H(beta) and I(beta) strands by Leu236 upon CO binding, and this structural change propagates more than 15 A to a region of the structure implicated in signal transduction in PAS proteins. Displacement of residues Ile215, Ile216, and Gly217 in the FG loop is also evident, accompanied by the movement of heme propionate 6 upon change in iron ligation. CO binding increases the temperature factors in the FG loop of the protein and disorders the side chain of Arg206, a conserved residue involved in the FG loop switch mechanism. We relate these results to structural changes in other PAS sensor domains and their involvement in catalytic control.     

Heme Ligand Binding Properties and Intradimer Interactions in the Full-length Sensor Protein Dos from Escherichia coli and Its Isolated Heme Domain

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 ∼1 μm), 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 O₂) 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 ∼10-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.     

Molecular oxygen regulates the enzymatic activity of a heme-containing diguanylate cyclase (HemDGC) for the synthesis of cyclic di-GMP

We have studied the structural and enzymatic properties of a diguanylate cyclase from an obligatory anaerobic bacterium Desulfotalea psychrophila, which consists of the N-terminal sensor domain and the C-terminal diguanylate cyclase domain. The sensor domain shows an amino acid sequence homology and spectroscopic properties similar to those of the sensor domains of the globin-coupled sensor proteins containing a protoheme. This heme-containing diguanylate cyclase catalyzes the formation of cyclic di-GMP from GTP only when the heme in the sensor domain binds molecular oxygen. When the heme is in the ferric, deoxy, CO-bound, or NO-bound forms, no enzymatic activity is observed. Resonance Raman spectroscopy reveals that Tyr55 forms a hydrogen bond with the heme-bound O₂, but not with CO. Instead, Gln81 interacts with the heme-bound CO. These differences of a hydrogen bonding network will play a crucial role for the selective O₂ sensing responsible for the regulation of the enzymatic activity.     

Mammalian PASKIN, a PAS-serine/threonine kinase related to bacterial oxygen sensors.

The PAS domain is a versatile protein fold found in many archaeal, bacterial, and plant proteins capable of sensing environmental changes in light intensity, oxygen concentration, and redox potentials. The oxygen sensor FixL from Rhizobium species contains a heme-bearing PAS domain and a histidine kinase domain that couples sensing to signaling. We identified a novel mammalian PAS protein (PASKIN) containing a domain architecture resembling FixL. PASKIN is encoded by an evolutionarily conserved single-copy gene which is ubiquitously expressed. The human PASKIN and mouse Paskin genes show a conserved intron-exon structure and share their promoter regions with another ubiquitously expressed gene that encodes a regulator of protein phosphatase-1. The 144-kDa PASKIN protein contains a PAS region homologous to the FixL PAS domain and a serine/threonine kinase domain which might be involved in signaling. Thus, PASKIN is likely to function as a mammalian PAS sensor protein.     

Tryptophan at position 104 is involved in transforming light signal into changes of beta-sheet structure for the signaling state in the BLUF domain of AppA

AppA is a member of an FAD-based new class blue-light sensory protein known as sensor of blue light using FAD (BLUF) protein. The spectroscopic properties of an AppA BLUF domain (AppA126), in which the tryptophan residue at position 104 had been replaced with alanine (W104A), were characterized. The W104A mutant AppA126 showed a nearly normal absorption red shift in the FAD UV-visible absorption upon illumination; however, the light state relaxed to the dark state at a rate approximately 150 times faster than that of wild-type AppA126. Light-induced structural changes of FAD and apoprotein in the wild-type and mutant AppA126 were studied by means of light-induced Fourier transform infrared (FTIR) difference spectroscopy using AppA126, in which the apoprotein had been selectively labeled with 13C. The light-induced FTIR spectrum of the W104A mutant AppA126 revealed bands corresponding to a C4 = O stretch of the FAD isoalloxazine ring and structural changes of apoprotein, but with some alterations in the bands' features. Notably, however, prominent protein bands at 1,632(+)/1,619(-) cm(-1) caused by changes in the beta-sheet structure were eliminated by the mutation, indicating that Trp104 is responsible for transforming the light signal into a specific beta-sheet structure change in the apoprotein of the AppA BLUF domain in the signaling state.     

Biophysical properties of a c-type heme in chemotaxis signal transducer protein DcrA

Chemotaxis signal transducer protein DcrA from a sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough was previously shown to contain a c-type heme in its periplasmic domain (DcrA-N) for sensing redox and/or oxygen [Fu et al. (1994) J. Bacteriol. 176, 344-350], which is the first example of a heme-based sensor protein containing a c-type heme as a prosthetic group. Optical absorption and resonance Raman spectroscopies indicates that heme c in DcrA-N shows a redox-dependent ligand exchange. Upon reduction, a water molecule that may be the sixth ligand of the ferric heme c is replaced by an endogenous amino acid. Although the reduced heme in DcrA-N is six-coordinated with two endogenous axial ligands, CO can easily bind to the reduced heme to form CO-bound DcrA-N. Reaction of the reduced DcrA-N with molecular oxygen results in autoxidation to form a ferric state without forming any stable oxygen-bound form probably due to the extremely low redox potential of DcrA-N (-250 mV). Our study supports the initial idea by Fu et al. that DcrA would act as a redox and/or oxygen sensor, in which the ligand exchange between water and an endogenous amino acid is a trigger for signal transduction. While the affinity of CO to DcrA-N (Kd = 138 microM) is significantly weak compared to those of other heme proteins, we suggest that CO might be another physiological effector molecule.     

Photocycle of the flavin-binding photoreceptor AppA, a bacterial transcriptional antirepressor of photosynthesis genes

The flavoprotein AppA from Rhodobacter sphaeroides contains an N-terminal domain belonging to a new class of photoreceptors designated BLUF domains. AppA was shown to control photosynthesis gene expression in response to blue light and oxygen tension. We have investigated the photocycle of the AppA BLUF domain by ultrafast fluorescence, femtosecond transient absorption, and nanosecond flash-photolysis spectroscopy. Time-resolved fluorescence experiments revealed four components of flavin adenine dinucleotide (FAD) excited-state decay, with lifetimes of 25 ps, 150 ps, 670 ps, and 3.8 ns. Ultrafast transient absorption spectroscopy revealed rapid internal conversion and vibrational cooling processes on excited FAD with time constants of 250 fs and 1.2 ps, and a multiexponential decay with effective time constants of 90 ps, 590 ps, and 2.7 ns. Concomitant with the decay of excited FAD, the rise of a species with a narrow absorption difference band near 495 nm was detected which spectrally resembles the long-living signaling state of AppA. Consistent with these results, the nanosecond flash-photolysis measurements indicated that formation of the signaling state was complete within the time resolution of 10 ns. No further changes were detected up to 15 micros. The quantum yield of the signaling-state formation was determined to be 24%. Thus, the signaling state of the AppA BLUF domain is formed on the ultrafast time scale directly from the FAD singlet excited state, without any apparent intermediate, and remains stable over 12 decades of time. In parallel with the signaling state, the FAD triplet state is formed from the FAD singlet excited state at 9% efficiency as a side reaction of the AppA photocycle.     

A globin-coupled oxygen sensor from the facultatively alkaliphilic<Emphasis Type="Italic"> Bacillus halodurans</Emphasis> C-125

We have recently discovered heme-containing signal transducers from the archaeon Halobacterium salinarum (HemAT-Hs) and the gram-positive bacterium Bacillus subtilis (HemAT-Bs). These proteins bind diatomic oxygen and trigger aerotactic responses. We identified that HemAT oxygen-sensing domains contain a globin-coupled sensor (GCS) motif, which exists as a two-domain transducer, having no similarity to the PAS domain (Period circadian protein, Ah receptor nuclear translocator protein, Single-minded protein) superfamily transducers. Using the GCS motif, we predicted that a 439-amino-acid protein annotated as a methyl-accepting chemotaxis protein (MCP) in the facultatively alkaliphilic bacterium Bacillus halodurans is a globin-coupled oxygen sensor. We cloned, expressed, and purified GCS(Bh), and performed its spectral analysis. GCS(Bh), binds heme and shows myoglobin-like spectra. This suggests that GCS(Bh) acts as an oxygen sensor and transmits a conformational signal through a linked signaling domain to trigger an aerotactic response in B. halodurans.     

Adenosine diphosphate moiety does not participate in structural changes for the signaling state in the sensor of blue-light using FAD domain of AppA

A sensor of blue light using FAD (BLUF) protein is a flavin adenine dinucleotide (FAD) based new class blue-light sensory flavoprotein. The BLUF domain of AppA was reconstituted in vitro from apoprotein and flavin adenine dinucleotide, flavin adenine mononucleotide or riboflavin. The light-induced FTIR spectra of the domain reconstituted from various flavins and the 13C-labeled apoprotein showed that identical light-induced structural changes occur in both the flavin chromophore and protein for the signaling state in all of the reconstituted holoproteins. The results showed that an adenosine 5'-dinucleotide moiety is not required for signaling-state formation in a BLUF domain.     

Interactions between the double-stranded RNA binding motif and RNA: definition of the binding site for the interferon-induced protein kinase DAI (PKR) on adenovirus VA RNA.

The protein kinase DAI, the double-stranded RNA activated inhibitor of translation (also known as PKR), regulates cell growth, virus infection, and other processes. DAI represents a class of proteins containing a recently recognized RNA binding motif, the dsRBM, but little is known about the contacts between these proteins and their RNA ligands. In adenovirus-infected cells, DAI activation is prevented by VA RNAI, a highly structured RNA that binds to the kinase. VA RNA contains three chief structural features: a terminal stem, an apical stem-loop, and a complex central domain. We used enzymatic and chemical footprinting to identify the interactions between DAI and VA RNAI. DAI protects the proximal part of the apical stem structure, an adjacent region in the central domain, and a region surrounding a conserved stem in the central domain from nuclease attack. During binding the RNA undergoes a conformational change that is mainly restricted to the central domain. A similar change is induced by magnesium ions alone. Footprinting and interference binding assays using base-specific chemical probes suggest that the protein does not make major contacts with RNA bases. On the other hand, footprinting with probes specific for the RNA backbone shows that DAI engages in a strong interaction with the minor groove of the apical stem and a weaker interaction in the central domain. A truncated form of DAI, p20, containing only the RNA binding domain, gives a similar protection pattern in the apical stem but protects the central domain less effectively. We conclude that the RNA binding domain of DAI interacts directly with the apical stem and central domain of VA RNA, and that other regions of the protein contribute to interactions with the central domain.     

Structural Refinement of a Key Tryptophan Residue in the BLUF Photoreceptor AppA by Ultraviolet Resonance Raman Spectroscopy

The flavin-adenine-dinucleotide-binding BLUF domain constitutes a new class of blue-light receptors, and the N-terminal domain of AppA is a representative of this family. The BLUF domain is of special interest because it uses a rigid flavin rather than an isomerizable chromophore, such as a rhodopsin or phytochrome, for its light-activation process. Crystal and solution structures of several BLUF domains were recently obtained, and their overall structures are consistent. However, there is a key ambiguity regarding the position of a conserved tryptophan (Trp-104 in AppA), in that this residue was found either close to flavin (Trp_in conformation) or exposed to the solvent (Trp_out conformation). The location of Trp-104 is a crucial factor in understanding the photocycle mechanism of BLUF domains, because this residue has been shown to play an essential role in the activation of AppA. In this study, we demonstrated a Trp_in conformation for the BLUF domain of AppA through direct observation of the vibrational spectrum of Trp-104 by ultraviolet resonance Raman spectroscopy, and also observed light-induced conformational and environmental changes in Trp-104. This study provides a structural basis for future investigations of the photocycle mechanism of BLUF proteins.     

Blockage of the channel to heme by the E87 side chain in the GAF domain of Mycobacterium tuberculosis DosS confers the unique sensitivity of DosS to oxygen

Two sensor kinases, DosS and DosT, are responsible for recognition of hypoxia in Mycobacterium tuberculosis. Both proteins are structurally similar to each other, but DosS is a redox sensor while DosT binds oxygen. The primary difference between the two proteins is the channel to the heme present in their GAF domains. DosS has a channel that is blocked by E87 while DosT has an open channel. Absorption spectra of DosS mutants with an open channel show that they bind oxygen as DosT does when they are exposed to air, while DosT G85E mutant is oxidized similarly to DosS without formation of an oxy-ferrous form. This suggests that oxygen accessibility to heme is the primary factor governing the oxygen-binding properties of these proteins.     

Identification of a Thiol/Disulfide Redox Switch in the Human BK Channel That Controls Its Affinity for Heme and CO

Heme is a required prosthetic group in many electron transfer proteins and redox enzymes. The human BK channel, which is a large-conductance Ca²⁺ and voltage-activated K⁺ channel, is involved in the hypoxic response in the carotid body. The BK channel has been shown to bind and undergo inhibition by heme and activation by CO. Furthermore, evidence suggests that human heme oxygenase-2 (HO2) acts as an oxygen sensor and CO donor that can form a protein complex with the BK channel. Here we describe a thiol/disulfide redox switch in the human BK channel and biochemical experiments of heme, CO, and HO2 binding to a 134-residue region within the cytoplasmic domain of the channel. This region, called the heme binding domain (HBD) forms a linker segment between two Ca²⁺-sensing domains (called RCK1 and RCK2) of the BK channel. The HBD includes a CXXCH motif in which histidine serves as the axial heme ligand and the two cysteine residues can form a reversible thiol/disulfide redox switch that regulates affinity of the HBD for heme. The reduced dithiol state binds heme (K_d = 210 nm) 14-fold more tightly than the oxidized disulfide state. Furthermore, the HBD is shown to tightly bind CO (K_d = 50 nm) with the Cys residues in the CXXCH motif regulating affinity of the HBD for CO. This HBD is also shown to interact with heme oxygenase-2. We propose that the thiol/disulfide switch in the HBD is a mechanism by which activity of the BK channel can respond quickly and reversibly to changes in the redox state of the cell, especially as it switches between hypoxic and normoxic conditions.     

Functional implications of the propionate 7-arginine 220 interaction in the FixLH oxygen sensor from Bradyrhizobium japonicum

BjFixL from Bradyrhizobium japonicum is a heme-based oxygen sensor implicated in the signaling cascade that enables the bacterium to adapt to fluctuating oxygen levels. Signal transduction is initiated by the binding of O(2) to the heme domain of BjFixL, resulting in protein conformational changes that are transmitted to a histidine kinase domain. We report structural changes of the heme and its binding pocket in the Fe(II) deoxy and Fe(III) met states of the wild-type BjFixLH oxygen sensor domain and four mutants of the highly conserved residue arginine 220. UV-visible, electron paramagnetic resonance, and resonance Raman spectroscopies all showed that the heme iron of the R220H mutant is unexpectedly six-coordinated at physiological pH in the Fe(III) state but undergoes pH- and redox-dependent coordination changes. This behavior is unprecedented for FixL proteins, but is reminiscent of another oxygen sensor from E. coli, EcDos. All mutants in their deoxy states are five-coordinated Fe(II), although we report rupture of the residue 220-propionate 7 interaction and structural modifications of the heme conformation as well as propionate geometry and flexibility. In this work, we conclude that part of the structural reorganization usually attributed to O(2) binding in the wild-type protein is in fact due to rupture of the Arg220-P7 interaction. Moreover, we correlate the structural modifications of the deoxy Fe(II) states with k(on) values and conclude that the Arg220-P7 interaction is responsible for the lower O(2) and CO k(on) values reported for the wild-type protein.