Identification of histidine 77 as the axial heme ligand of carbonmonoxy CooA by picosecond time-resolved resonance Raman spectroscopy

Early processes in heme-based CO-sensing proteins

Carbon monoxide has been recognized relatively recently as signaling molecule, and only very few dedicated natural CO sensor proteins have been identified so far. These include in particular heme-based transcription factors: the bacterial sensor proteins CooA and RcoM. In these 6-coordinated systems, exchange between an internal protein residue and CO as a heme ligand in the sensor domain affects the properties of the DNA-binding domain. Using light to dissociate heme-ligand bonds can in principle initiate this switching process. We review the efforts to use this method to investigate early processes in ligand switching and signaling, with an emphasis on the CO-“trappingˮ properties of the heme cavity. These features are unusual for most heme proteins, but common for heme-based CO sensors.

Iron transitions during activation of allosteric heme proteins in cell signaling

Allosteric heme proteins can fulfill a very large number of different functions thanks to the remarkable chemical versatility of heme through the entire living kingdom. Their efficacy resides in the ability of heme to transmit both iron coordination changes and iron redox state changes to the protein structure. Besides the properties of iron, proteins may impose a particular heme geometry leading to distortion, which allows selection or modulation of the electronic properties of heme. This review focusses on the mechanisms of allosteric protein activation triggered by heme coordination changes following diatomic binding to proteins as diverse as the human NO-receptor, cytochromes, NO-transporters and sensors, and a heme-activated potassium channel. It describes at the molecular level the chemical capabilities of heme to achieve very different tasks and emphasizes how the properties of heme are determined by the protein structure. Particularly, this reviews aims at giving an overview of the exquisite adaptability of heme, from bacteria to mammals.

A Study of the Dynamics of the Heme Pocket and C-helix in CooA upon CO Dissociation Using Time-Resolved Visible and UV Resonance Raman Spectroscopy

CooA is a CO-sensing transcriptional activator from the photosynthetic bacterium Rhodospirillum rubrum that binds CO at the heme iron. The heme iron in ferrous CooA has two axial ligands: His77 and Pro2. CO displaces Pro2 and induces a conformational change in CooA. The dissociation of CO and/or ligation of the Pro2 residue are believed to trigger structural changes in the protein. Visible time-resolved resonance Raman spectra obtained in this study indicated that the ν(Fe-His) mode, arising from the proximal His77-iron stretch, does not shift until 50 μs after the photodissociation of CO. Ligation of the Pro2 residue to the heme iron was observed around 50 μs after the photodissociation of CO, suggesting that the ν(Fe-His) band exhibits no shift until the ligation of Pro2. UV resonance Raman spectra suggested structural changes in the vicinity of Trp110 in the C-helix upon CO binding, but no or very small spectral changes in the time-resolved UV resonance Raman spectra were observed from 100 ns to 100 μs after the photodissociation of CO. These results strongly suggest that the conformational change of CooA is induced by the ligation of Pro2 to the heme iron.

Haem-based sensors: a still growing old superfamily

The haem-based sensors are chimeric multi-domain proteins responsible for the cellular adaptive responses to environmental changes. The signal transduction is mediated by the sensing capability of the haem-binding domain, which transmits a usable signal to the cognate transmitter domain, responsible for providing the adequate answer. Four major families of haem-based sensors can be recognized, depending on the nature of the haem-binding domain: (i) the haem-binding PAS domain, (ii) the CO-sensitive carbon monoxide oxidation activator, (iii) the haem NO-binding domain, and (iv) the globin-coupled sensors. The functional classification of the haem-binding sensors is based on the activity of the transmitter domain and, traditionally, comprises: (i) sensors with aerotactic function; (ii) sensors with gene-regulating function; and (iii) sensors with unknown function. We have implemented this classification with newly identified proteins, that is, the Streptomyces avermitilis and Frankia sp. that present a C-terminal-truncated globin fused to an N-terminal cofactor-free monooxygenase, the structural-related class of non-haem globins in Bacillus subtilis, Moorella thermoacetica, and Bacillus anthracis, and a haemerythrin-coupled diguanylate cyclase in Vibrio cholerae. This review summarizes the structures, the functions, and the structure-function relationships known to date on this broad protein family. We also propose unresolved questions and new possible research approaches.

Primary processes in heme-based sensor proteins

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 (O2, 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 (O2), 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.

Ultrafast proteinquake dynamics in cytochrome c

We report here our systematic studies of the heme dynamics and induced protein conformational relaxations in two redox states of ferric and ferrous cytochrome c upon femtosecond excitation. With a wide range of probing wavelengths from the visible to the UV and a site-directed mutation we unambiguously determined that the protein dynamics in the two states are drastically different. For the ferrous state the heme transforms from 6-fold to 5-fold coordination with ultrafast ligand dissociation in less than 100 fs, followed by vibrational cooling within several picoseconds, but then recombining back to its original 6-fold coordination in 7 ps. Such impulsive bond breaking and late rebinding generate proteinquakes and strongly perturb the local heme site and shake global protein conformation, which were found to completely recover in 13 and 42 ps, respectively. For the ferric state the heme however maintains its 6-fold coordination. The dynamics mainly occur at the local site, including ultrafast internal conversion in hundreds of femtoseconds, vibrational cooling on the similar picosecond time scale, and complete ground-state recovery in 10 ps, and no global conformation relaxation was observed.

Substrate-protein interaction in human tryptophan dioxygenase: the critical role of H76

The initial and rate-limiting step of the kynurenine pathway in humans involves the oxidation of tryptophan to N-formyl kynurenine catalyzed by two hemeproteins, tryptophan 2,3-dioxygenase (hTDO) and indoleamine 2,3-dioxygenase (hIDO). In hTDO, the conserved H76 residue is believed to act as an active site base to deprotonate the indole NH group of Trp, the initial step of the Trp oxidation reaction. In hIDO, this histidine is replaced by a serine. To investigate the role of the H76, we have studied the H76S and H76A mutants of hTDO. Activity assays show that the mutations cause a decrease in k(cat) and an increase in K(M) for both mutants. The decrease in the k(cat) is accounted for by the replacement of the active site base catalyst, H76, with a weaker base, possibly a water, whereas the increase in K(M) is attributed to the loss of the specific interactions between the H76 and the substrate as well as the protein matrix. Resonance Raman studies with various Trp analogs indicate that the substrate is positioned in the active site by the ammonium, carboxylate, and indole groups, via intricate H-bonding and hydrophobic interactions. This scenario is consistent with the observation that l-Trp binding significantly perturbs the electronic properties of the O(2)-adduct of hTDO. The important structural and functional roles of H76 in hTDO is underscored by the observation that the electronic configuration of the active ternary complex, l-Trp-O(2)-hTDO, is sensitive to the H76 mutations.

Low-frequency dynamics of Caldariomyces fumago chloroperoxidase probed by femtosecond coherence spectroscopy

Ultrafast laser spectroscopy techniques are used to measure the low-frequency vibrational coherence spectra and nitric oxide rebinding kinetics of Caldariomyces fumago chloroperoxidase (CPO). Comparisons of the CPO coherence spectra with those of other heme species are made to gauge the protein-specific nature of the low-frequency spectra. The coherence spectrum of native CPO is dominated by a mode that appears near 32-33 cm(-1) at all excitation wavelengths, with a phase that is consistent with a ground-state Raman-excited vibrational wavepacket. On the basis of a normal coordinate structural decomposition (NSD) analysis, we assign this feature to the thiolate-bound heme doming mode. Spectral resolution of the probe pulse ("detuned" detection) reveals a mode at 349 cm(-1), which has been previously assigned using Raman spectroscopy to the Fe-S stretching mode of native CPO. The ferrous species displays a larger degree of spectral inhomogeneity than the ferric species, as reflected by multiple shoulders in the optical absorption spectra. The inhomogeneities are revealed by changes in the coherence spectra at different excitation wavelengths. The appearance of a mode close to 220 cm(-1) in the coherence spectrum of reduced CPO excited at 440 nm suggests that a subpopulation of five coordinated histidine-ligated hemes is present in the ferrous state at a physiologically relevant pH. A significant increase in the amplitude of the coherence signal is observed for the resonance with the 440 nm subpopulation. Kinetics measurements reveal that nitric oxide binding to ferric and ferrous CPO can be described as a single-exponential process, with rebinding time constants of 29.4 +/- 1 and 9.3 +/- 1 ps, respectively. This is very similar to results previously reported for nitric oxide binding to horseradish peroxidase.

DFT analysis of axial and equatorial effects on heme-CO vibrational modes: applications to CooA and H-NOX heme sensor proteins

Determinants of the Fe-CO and C-O stretching frequencies in (imidazole)heme-CO adducts have been investigated via density functional theory (DFT) analysis, in connection with puzzling characteristics of the heme sensor protein CooA and of the H-NOX (Heme-Nitric Oxide and/or OXygen binding) family of proteins, including soluble guanylate cyclase (sGC). The computations show that two mechanisms of Fe-histidine bond weakening have opposite effects on the nuFeC/nuCO pattern. Mechanical tension is expected to raise nuFeC with little change in nuCO whereas the weakening of H-bond donation from the imidazole ligand has the opposite effect. Data on CooA indicate imidazole H-bond weakening associated with heme displacement, as part of the activation mechanism. The computations also reveal that protein-induced distortion of the porphyrin ring, a prominent structural feature of the H-NOX protein TtTar4H (Thermoanaerobacter tengcongensis Tar4 protein heme domain), has surprisingly little effect on nuFeC or nuCO. However, another structural feature, strong H-bonding to the propionates, is suggested to account for the weakened back bonding that is evident in sGC. TtTar4H-CO itself has an elevated nuFeC, which is successfully modeled as a compression effect, resulting from steric crowding in the distal pocket. nuFeC/nuCO data, in conjunction with modeling, can provide valuable insight into mechanisms for heme-protein modulation.

Construction of a subnanosecond time-resolved, high-resolution ultraviolet resonance Raman measurement system and its application to reveal the dynamic structures of proteins

A subnanosecond time-resolved ultraviolet (UV) resonance Raman system has been developed to study protein structural dynamics. The system is based on a 1 kHz Nd:YLF-pumped Ti:Sapphire regenerative amplifier with harmonic generation that can deliver visible (412, 440, 458, and 488 nm) and UV (206, 220, 229, and 244 nm) pulses. A subnanosecond (0.2 ns) tunable near-infrared pulse from a custom-made Ti:Sapphire oscillator is used to seed the regenerative amplifier. A narrow linewidth of the subnanosecond pulse offers the advantage of high resolution of UV resonance Raman spectra, which is critical to obtain site-specific information on protein structures. By combination with a 1 m single spectrograph equipped with a 3600 grooves/mm holographic grating and a custom-made prism prefilter, the present system achieves excellent spectral (<10 cm(-1)) and frequency (approximately 1 cm(-1)) resolutions with a relatively high temporal resolution (<0.5 ns). We also report the application of this system to two heme proteins, hemoglobin A and CooA, with the 440 nm pump and 220 nm probe wavelengths. For hemoglobin A, a structural change during the transition to the earliest intermediate upon CO photodissociation is successfully observed, specifically, nanosecond cleavage of the A-E interhelical hydrogen bonds within each subunit at Trpalpha14 and Trpbeta15 residues. For CooA, on the other hand, rapid structural distortion (<0.5 ns) by CO photodissociation and nanosecond structural relaxation following CO geminate recombination are observed through the Raman bands of Phe and Trp residues located near the heme. These results demonstrate the high potential of this instrument to detect local protein motions subsequent to photoreactions in their active sites.

Mechanism of the CO-sensing heme protein CooA: new insights from the truncated heme domain and UVRR spectroscopy

The bacterial CO-sensing heme protein CooA activates expression of genes whose products perform CO-metabolism by binding its target DNA in response to CO binding. The required conformational change has been proposed to result from CO-induced displacement of the heme and of the adjacent C-helix, which connects the sensory and DNA-binding domains. Support for this proposal comes from UV Resonance Raman (UVRR) spectroscopy, which reveals a more hydrophobic environment for the C-helix residue Trp110 when CO binds. In addition, we find a tyrosine UVRR response, which is attributable to weakening of a Tyr55-Glu83 H-bond that anchors the proximal side of the heme. Both Trp and Tyr responses are augmented in the heme domain when the DNA-binding domain has been removed, apparently reflecting loss of the inter-domain restraint. This augmentation is abolished by a Glu83Gln substitution, which weakens the anchoring H-bond. The CO recombination rate following photolysis of the CO adduct is similar for truncated and full-length protein, though truncation does increase the rate of CO association in the absence of photolysis; together these data indicate that truncation causes a faster dissociation of the endogenous Pro2 ligand. These findings are discussed in the light of structural evidence that the N-terminal tail, once released from the heme, selects the proper orientation of the DNA-binding domain, via docking interactions.

Ultrafast dynamics of ligands within heme proteins

Physiological bond formation and bond breaking events between proteins and ligands and their immediate consequences are difficult to synchronize and study in general. However, diatomic ligands can be photodissociated from heme, and thus in heme proteins ligand release and rebinding dynamics and trajectories have been studied on timescales of the internal vibrations of the protein that drive many biochemical reactions, and longer. The rapidly expanding number of characterized heme proteins involved in a large variety of functions allows comparative dynamics-structure-function studies. In this review, an overview is given of recent progress in this field, and in particular on initial sensing processes in signaling proteins, and on ligand and electron transfer dynamics in oxidases and cytochromes.

Heme displacement mechanism of CooA activation: mutational and Raman spectroscopic evidence

The heme-containing protein CooA of Rhodospirillum rubrum regulates the expression of genes involved in CO oxidation. CooA binds its target DNA sequence in response to CO binding to its heme. Activity measurements and resonance Raman (RR) spectra are reported for CooA variants that bind DNA even in the absence of CO, those in which the wild-type residues at the 121-126 positions, TSCMRT, are replaced by the residues AYLLRL or RYLLRL, and also for variants that bind DNA poorly in the presence of CO, such as L120S and L120F. The Fe-C and C-O stretching resonance Raman (RR) frequencies of all CooAs examined deviate from the expected back-bonding correlation in a manner indicating weakening of the Fe-His-77 proximal ligand bond, and the extent of weakening correlates positively with DNA binding activity. The (A/R) YLLRL variants have detectable populations of a 5-coordinate heme resulting from partial dissociation of the endogenous distal ligand, Pro-2. Selective excitation of this population reveals downshifted Fe-His-77-stretching RR bands, confirming the proximal bond weakening. These results support our previous hypothesis that the conformational change required for DNA binding is initiated by displacement of the heme into an adjacent hydrophobic cavity once CO displaces the Pro-2 ligand. Examination of the crystal structure reveals a physical basis for these results, and a mechanism is proposed to link heme displacement to conformational change.

Dynamic Ligation Properties of the Escherichia coli Heme Chaperone CcmE to Non-covalently Bound Heme

The cytochrome c maturation protein CcmE is an essential membrane-anchored heme chaperone involved in the post-translational covalent attachment of heme to c-type cytochromes in Gram-negative bacteria such as Escherichia coli. Previous in vitro studies have shown that CcmE can bind heme both covalently (via a histidine residue) and non-covalently. In this work we present results on the latter form of heme binding to a soluble form of CcmE. Examination of a number of site-directed mutants of E. coli CcmE by resonance Raman spectroscopy has identified ligands of the heme iron and provided insight into the initial steps of heme binding by CcmE before it binds the heme covalently. The heme binding histidine (His-130) appears to ligate the heme iron in the ferric oxidation state, but two other residues ligate the iron in the ferrous form, thereby freeing His-130 to undergo covalent attachment to a heme vinyl group. It appears that the heme ligation in the non-covalent form is different from that in the holo-form, suggesting that a change in ligation could act as a trigger for the formation of the covalent bond and showing the dynamic and oxidation state-sensitive ligation properties of CcmE.

Evidence for displacements of the C-helix by CO ligation and DNA binding to CooA revealed by UV resonance Raman spectroscopy

The UV and visible resonance Raman spectra are reported for CooA from Rhodospirillum rubrum, which is a transcriptional regulator activated by growth in a CO atmosphere. CO binding to heme in its sensor domain causes rearrangement of its DNA-binding domain, allowing binding of DNA with a specific sequence. The sensor and DNA-binding domains are linked by a hinge region that follows a long C-helix. UV resonance Raman bands arising from Trp-110 in the C-helix revealed local movement around Trp-110 upon CO binding. The indole side chain of Trp-110, which is exposed to solvent in the CO-free ferrous state, becomes buried in the CO-bound state with a slight change in its orientation but maintains a hydrogen bond with a water molecule at the indole nitrogen. This is the first experimental data supporting a previously proposed model involving displacement of the C-helix and heme sliding. The UV resonance Raman spectra for the CooA-DNA complex indicated that binding of DNA to CooA induces a further displacement of the C-helix in the same direction during transition to the complete active conformation. The Fe-CO and C-O stretching bands showed frequency shifts upon DNA binding, but the Fe-His stretching band did not. Moreover, CO-geminate recombination was more efficient in the DNA-bound state. These results suggest that the C-helix displacement in the DNA-bound form causes the CO binding pocket to narrow and become more negative.

Electrochemically induced FTIR difference spectroscopy in the mid- to far infrared (200 μm) domain: A new setup for the analysis of metal–ligand interactions in redox proteins

We report the setup of an electrochemical cell with chemical-vapor deposition diamond windows and the use of a Bruker 66 SX FTIR spectrometer equipped with DTGS and Si-bolometer detectors and KBr and mylar beam splitters, to record on the same sample, FTIR difference spectra corresponding to the structural changes associated with the change in redox state of active sites in proteins in the whole 1800-50 cm(-1) region. With cytochrome c we show that reliable reduced-minus-oxidized FTIR difference spectra are obtained, which correspond to single molecular vibrations. Redox-sensitive IR modes of the cytochrome c are detected until 140 cm(-1) with a good signal to noise. This new setup is promising to analyze the infrared spectral region where metal-ligand vibrations are expected to contribute and to extend the analysis of vibrational properties to metal sites or redox states not accessible to (resonance) Raman spectroscopy.

Characterization of functional heme domains from soluble guanylate cyclase

Soluble guanylate cyclase (sGC) is a heterodimeric, nitric oxide (NO)-sensing hemoprotein composed of two subunits, alpha1 and beta1. NO binds to the heme cofactor in the beta1 subunit, forming a five-coordinate NO complex that activates the enzyme several hundred-fold. In this paper, the heme domain has been localized to the N-terminal 194 residues of the beta1 subunit. This fragment represents the smallest construct of the beta1 subunit that retains the ligand-binding characteristics of the native enzyme, namely, tight affinity for NO and no observable binding of O(2). A functional heme domain from the rat beta2 subunit has been localized to the first 217 amino acids beta2(1-217). These proteins are approximately 40% identical to the rat beta1 heme domain and form five-coordinate, low-spin NO complexes and six-coordinate, low-spin CO complexes. Similar to sGC, these constructs have a weak Fe-His stretch [208 and 207 cm(-)(1) for beta1(1-194) and beta2(1-217), respectively]. beta2(1-217) forms a CO complex that is very similar to sGC and has a high nu(CO) stretching frequency at 1994 cm(-)(1). The autoxidation rate of beta1(1-194) was 0.073/min, while the beta2(1-217) was substantially more stable in the ferrous form with an autoxidation rate of 0.003/min at 37 degrees C. This paper has identified and characterized the minimum functional ligand-binding heme domain derived from sGC, providing key details toward a comprehensive characterization.

Temperature-dependent studies of NO recombination to heme and heme proteins

The rebinding kinetics of NO to the heme iron of myoglobin (Mb) is investigated as a function of temperature. Below 200 K, the transition-state enthalpy barrier associated with the fastest (approximately 10 ps) recombination phase is found to be zero and a slower geminate phase (approximately 200 ps) reveals a small enthalpic barrier (approximately 3 +/- 1 kJ/mol). Both of the kinetic rates slow slightly in the myoglobin (Mb) samples above 200 K, suggesting that a small amount of protein relaxation takes place above the solvent glass transition. When the temperature dependence of the NO recombination in Mb is studied under conditions where the distal pocket is mutated (e.g., V68W), the rebinding kinetics lack the slow phase. This is consistent with a mechanism where the slower (approximately 200 ps) kinetic phase involves transitions of the NO ligand into the distal heme pocket from a more distant site (e.g., in or near the Xe4 cavity). Comparison of the temperature-dependent NO rebinding kinetics of native Mb with that of the bare heme (PPIX) in glycerol reveals that the fast (enthalpically barrierless) NO rebinding process observed below 200 K is independent of the presence or absence of the proximal histidine ligand. In contrast, the slowing of the kinetic rates above 200 K in MbNO disappears in the absence of the protein. Generally, the data indicate that, in contrast to CO, the NO ligand binds to the heme iron through a "harpoon" mechanism where the heme iron out-of-plane conformation presents a negligible enthalpic barrier to NO rebinding. These observations strongly support a previous analysis (Srajer et al. J. Am. Chem. Soc. 1988, 110, 6656-6670) that primarily attributes the low-temperature stretched exponential rebinding of MbCO to a quenched distribution of heme geometries. A simple model, consistent with this prior analysis, is presented that explains a variety of MbNO rebinding experiments, including the dependence of the kinetic amplitudes on the pump photon energy.

Spectroscopic and redox properties of a CooA homologue from Carboxydothermus hydrogenoformans

CooA is a CO-sensing transcriptional activator that contains a b-type heme as the active site for sensing its physiological effector, CO. In this study, the spectroscopic and redox properties of a new CooA homologue from Carboxydothermus hydrogenoformans (Ch-CooA) were studied. Spectroscopic and mutagenesis studies revealed that His-82 and the N-terminal alpha-amino group were the axial ligands of the Fe(III) and Fe(II) hemes in Ch-CooA and that the N-terminal alpha-amino group was replaced by CO upon CO binding. Two neutral ligands, His-82 and the N-terminal alpha-amino group, are coordinated to the Fe(III) heme in Ch-CooA, whereas two negatively charged ligands, a thiolate from Cys-75 and the nitrogen atom of the N-terminal Pro, are the axial ligands of the Fe(III) heme in Rr-CooA. The difference in the coordination structure of the Fe(III) heme resulted in a large positive shift of redox potentials of Ch-CooA compared with Rr-CooA. Comparing the properties of Ch-CooA and Rr-CooA demonstrates that the essential elements for CooA function will be: (i) the heme is six-coordinate in the Fe(III), Fe(II), and Fe(II)-CO forms; (ii) the N-terminal is coordinated to the heme as an axial ligand, and (iii) CO replaces the N-terminal bound to the heme upon CO binding.

CO-sensing mechanisms

Carbon monoxide (CO) has long been known to have dramatic physiological effects on organisms ranging from bacteria to humans, but recently there have a number of suggestions that organisms might have specific sensors for CO. This article reviews the current evidence for a variety of proteins with demonstrated or potential CO-sensing ability. Particular emphasis is placed on the molecular description of CooA, a heme-containing CO sensor from Rhodospirillum rubrum, since its biological role as a CO sensor is clear and we have substantial insight into the basis of its sensing ability.

The C-helix in CooA Rolls upon CO Binding to Ferrous Heme

CooA is a homodimeric transcriptional activator from Rhodospirillum rubrum containing one heme in each subunit. CO binding to the heme in its sensor domain activates CooA, facilitating the binding to DNA by its DNA-binding domain. The C-helix links the two domains and shapes an interface between the subunits. To probe the nature of CO activation, residues at positions 112-121 on the C-helix were replaced by Asn or Gln and their effects were evaluated by resonance Raman spectroscopy and by the measurements of CO binding affinity. The nu(Fe-CO) stretching Raman line in CO-bound wild-type CooA was up-shifted by 6 cm(-1) in the L116Q, G117N, and L120Q mutants, indicating unequivocally that these residues are close to the bound CO. Residues Leu116 and Leu120 from each subunit form contacts with the corresponding residues in the opposite subunit, enabling hydrophobic interactions in the inactive ferrous form. Thus, in the CO-bound activated form, both C-helices appear to roll to direct these residues toward the heme, forming a hydrophobic pocket for the bound CO. The CO affinity is approximately one order of magnitude higher in the L112Q, I115Q, L116Q, G117N, L120Q, and T121N mutants but reduced in A114N mutant. The variation indicates that these residues are close to the heme in the ferrous and/or CO-bound forms and are responsible for CooA activation. A roll-and-slide mechanism is proposed for CO activation of CooA.

Activation mechanisms of transcriptional regulator CooA revealed by small-angle X-ray scattering

CooA, a heme-containing transcriptional activator, binds CO to the heme moiety and then undergoes a structural change that promotes the specific binding to the target DNA. To elucidate the activation mechanism coupled to CO binding, we investigated the CO-dependent structural transition of CooA with small-angle X-ray scattering (SAXS). In the absence of CO, the radius of gyration Rg and the second virial coefficient (A2) were 25.3(+/-0.5)A and -0.39(+/-0.25) x 10(-4)ml mol g(-2), respectively. CO binding caused a slight increase in Rg (by 0.5A) and a marked decrease in A2 (by 5.09 x 10(-4)ml mol g(-2)). The observed decrease in A2 points to higher attractive interactions between CO-bound CooA molecules in solution compared with CO-free CooA. Although the minor alternation of Rg rules out changes in the overall structure, the marked change in the surface properties points to a CO-induced conformational transition. The experimental Rg and SAXS curves of the two states did not agree with the crystal structure of CO-free CooA. We thus simulated the solution structures of CooA based on the experimental data using rigid-body refinements as well as low-resolution model reconstructions. Both results demonstrate that the hinge region connecting the N-terminal heme domain and C-terminal DNA-binding domain is kinked in CO-free CooA, so that the two domains are positioned close to each other. The CO-dependent structural change observed by SAXS corresponds to a slight swing of the DNA-binding domains away from the heme domains coupled with their rotation by about 8 degrees around the axis of 2-fold symmetry.

Changing the ligand specificity of CooA, a highly specific heme-based CO sensor

The CO-specific heme-based sensor CooA regulates the ability of Rhodospirillum rubrum to grow on CO as an energy source. Only CO triggers the conformational change of CooA essential for the protein to function as a transcriptional activator. A structurally informed mutagenesis, followed by an in vivo screening method, allowed the isolation of a series of novel CooA variants that show very substantial response to imidazole. Compared with wild-type CooA, the ligand selectivity between imidazole and CO had been changed in some variants by roughly three orders of magnitude. Remarkably, different CooA variants also showed the ability to discriminate among imidazole derivatives, strongly implying a mechanism of precise interactions between the affected residues and the various ligands. Although wild-type CooA and imidazole-responsive CooA variants appear to recognize their respective ligands by fundamentally different mechanisms, several lines of evidence suggest that they respond by a similar C-helix repositioning that results in the rearrangement of the DNA-binding domains responsible for specific DNA contact. These results have implications for the molecular basis of both the imidazole responsiveness in the variants and the stringent CO specificity of wild-type CooA.

Roles of Heme Axial Ligands in the Regulation of CO Binding to CooA

CooA is a CO-dependent transcription factor of the bacterium Rhodospirillum rubrum that contains a six-coordinate heme. It has as its heme axial ligands Pro(2) and Cys(75) in the ferric state and Pro(2) and His(77) in the ferrous state. To probe the regulation of CO binding and the ligand switching mechanism in CooA, we have prepared site-directed mutants in which the residues contributing the axial ligands are substituted. The properties of these mutants were investigated by resonance Raman and CO titration methods. Wild-type CooA binds CO with a modest dissociation constant (K(d)) of 11 microm, this value being typical for gas-sensing heme proteins. The K(d) value was greatly decreased in the P2H mutant, indicating that Pro(2) coordination fine tunes CO sensing in CooA. The bound CO in P2H gives rise to a nu(Fe-CO) stretching Raman line at 490 cm(-1), which is similar to that in wild-type CooA. Thus, Pro(2) is the ligand that is replaced by exogenous CO. In the H77A mutant, equilibrium CO binding is biphasic, and at high CO pressures two CO molecules occupy both axial sites. The nu(Fe-CO) stretching Raman line for the first CO molecule was observed at 497 cm(-1). Some of the His(77) mutants showed an additional nu(Fe-CO) line at 525 cm(-1). The binding affinity of the second CO molecule correlates with the five-coordinate component in the ferrous His(77) mutants and also with the acidity of the side chain at position 77. Thus, we propose the Cys(75)-His(77) ligand switch is controlled by His(77) acting as a proton reservoir.

Functionally critical elements of CooA-related CO sensors

CooA is a heme-containing transcriptional activator that enables Rhodospirillum rubrum to sense and grow on CO as a sole energy source. We have identified a number of CooA homologs through database searches, expressed these heterologously in Escherichia coli, and monitored their ability to respond to CO in vivo. Further in vitro analysis of two CooA homologs from Azotobacter vinelandii and Carboxydothermus hydrogenoformans corroborated the in vivo data by revealing the ability of CO to bind to these hemoproteins and stimulate their binding at specific DNA sequences. These data, as well as the patterns of conserved residues in the homologs, are compared to what is already known about functionally important residues in the CooA protein of R. rubrum. The results identify critical regions of CooA and indicate features that distinguish CooAs from the general family of cyclic AMP receptor proteins.

Dynamics of carbon monoxide binding to CooA

CooA is a dimeric CO-sensing heme protein from Rhodospirillum rubrum. The heme iron in reduced CooA is six-coordinate; the axial ligands are His-77 and Pro-2. CO displaces Pro-2 and induces a conformation change that allows CooA to bind DNA and activate transcription of coo genes. Equilibrium CO binding is cooperative, with a Hill coefficient of n = 1.4, P(50) = 2.2 microm, and estimated Adair constants K(1) = 0.16 and K(2) = 1.3 microm(-1). The rates of CO binding and release are both strongly biphasic, with roughly equal amplitudes for the fast and slow phases. The association rates show a hyperbolic dependence on [CO], consistent with Pro-2 dissociation being rate-limiting. The kinetic characteristics of the transiently formed five-coordinate heme are probed via flash photolysis. These observations are integrated into a kinetic model, in which CO binding to one subunit decreases the rate of Pro-2 rebinding in the second, leading to a net increase in affinity for the second CO. The CO adduct exists in slowly interconverting "open" and "closed" forms. This interconversion probably involves the large-scale motions required to bring the DNA-binding domains into proper orientation. The combination of low CO affinity, slow CO binding, and slow conformational transitions ensures that activation of CooA only occurs at high (micromolar) and sustained (> or =1 min) levels of CO. When micromolar levels do occur, positive cooperativity allows efficient activation over a narrow range of CO concentrations.

Activation of heme-regulated eukaryotic initiation factor 2alpha kinase by nitric oxide is induced by the formation of a five-coordinate NO-heme complex: optical absorption, electron spin resonance, and resonance raman spectral studies

Heme-regulated eukaryotic initiation factor 2alpha kinase (HRI) regulates the synthesis of hemoglobin in reticulocytes in response to heme availability. HRI contains a tightly bound heme at the N-terminal domain. Earlier reports show that nitric oxide (NO) regulates HRI catalysis. However, the mechanism of this process remains unclear. In the present study, we utilize in vitro kinase assays, optical absorption, electron spin resonance (ESR), and resonance Raman spectra of purified full-length HRI for the first time to elucidate the regulation mechanism of NO. HRI was activated via heme upon NO binding, and the Fe(II)-HRI(NO) complex displayed 5-fold greater eukaryotic initiation factor 2alpha kinase activity than the Fe(III)-HRI complex. The Fe(III)-HRI complex exhibited a Soret peak at 418 nm and a rhombic ESR signal with g values of 2.49, 2.28, and 1.87, suggesting coordination with Cys as an axial ligand. Interestingly, optical absorption, ESR, and resonance Raman spectra of the Fe(II)-NO complex were characteristic of five-coordinate NO-heme. Spectral findings on the coordination structure of full-length HRI were distinct from those obtained for the isolated N-terminal heme-binding domain. Specifically, six-coordinate NO-Fe(II)-His was observed but not Cys-Fe(III) coordination. It is suggested that significant conformational change(s) in the protein induced by NO binding to the heme lead to HRI activation. We discuss the role of NO and heme in catalysis by HRI, focusing on heme-based sensor proteins.

Activation mechanism of the CO sensor CooA. Mutational and resonance Raman spectroscopic studies

CooA is a CO-dependent heme protein transcription factor of the bacterium Rhodospirillum rubrum. CO binding to its heme causes CooA to bind DNA and activate expression of genes for CO metabolism. To understand the nature of CO activation, several CooA mutational variants have been studied by resonance Raman spectroscopy, in vivo activity measurements, and DNA binding assays. Analysis of the Fe-C and C-O stretching Raman spectroscopy bands permits the conclusion that when CO displaces the Pro2 heme ligand, the protein forms a hydrophobic pocket in which the C-helix residues Gly117, Leu116, and Ile113 are close to the bound CO. The displaced Pro2 terminus is expelled from this pocket, unless the pH is raised above the pKa, in which case the terminus remains in H-bond contact. The pKa for this transition is 8.6, two units below that of aqueous proline, reflecting the hydrophobic nature of the pocket. The proximal Fe-His bond in Fe[II]CooA is as strong as it is in myoglobin but is weakened by CO binding, an effect attributable to loss of an H-bond from the proximal His77 ligand to the adjacent Asn42 side chain. A structural model is proposed for the position of the CO-bound heme in the active form of CooA, which has implications for the mechanism of CO activation.

Repositioning about the dimer interface of the transcription regulator CooA: a major signal transduction pathway between the effector and DNA-binding domains

Activation of the homodimeric transcriptional regulator CooA depends on the coupling of CO binding at an effector domain heme with the allosteric repositioning of the DNA-binding domain F-helix that promotes specific DNA interaction. By analogy to the homologous cAMP receptor protein (CRP), it has been proposed that effector binding elicits subunit reorientation about their coiled-coil C-helix interface, and that this effector domain reorientation stabilizes the active position of the DNA-binding domains. Here, we describe experiments in which effector-independent "CooA*" variants were selected following randomization of a six-residue portion of the C-helix dimerization domain. Subsequent activity analyses, both in vivo and in vitro, were consistent with a model wherein improved C-helix "leucine zipper" interactions modestly shifted the regulator population equilibrium towards the active conformation, although full activation remained CO-dependent. However, in addition to the improved leucine zipper, maximal CooA* activity required additional C-helix changes which in a WT background decreased normal CO-dependent DNA-binding 100-fold. This seemingly paradoxical combination suggested that maximal CooA* activity depended both on the improved coiled-coil interactions and the decoupling of the signal pathway within the effector domain. Both types of C-helix changes indicate that its repositioning is crucial for the allosteric shift in the inactive/active equilibrium of the DNA-binding domain.

Analysis of the L116K variant of CooA, the heme-containing CO sensor, suggests the presence of an unusual heme ligand resulting in novel activity

CooA is the CO-sensing transcriptional activator from Rhodospirillum rubrum, in which CO binding to its heme prosthetic group triggers a conformational change of CooA that allows the protein to bind its cognate target DNA sequence. By a powerful in vivo screening method following the simultaneous randomization of the codons for two C-helix residues, 113 and 116, near the distal heme pocket of CooA, we have isolated a series of novel CooA variants. In vivo, these show very high CO-independent activities (comparable with that of wild-type CooA in the presence of CO) and diminished CO-dependent activities. Sequence analysis showed that this group of variants commonly contains lysine at position 116 with a variety of residues at position 113. DNA-binding analysis of a representative purified variant, L116K CooA, revealed that this protein is competent to bind target DNA with K(d) values of 56 nm for Fe(III), 36 nm for Fe(II), and 121 nm for Fe(II)-CO CooA forms. Electron paramagnetic resonance and electronic absorption spectroscopies, combined with additional mutagenic studies, showed that L116K CooA has a new ligand replacing Pro(2) in both Fe(III) and Fe(II) states. The most plausible replacement ligand is the substituted lysine at position 116, so that the ligands of Fe(III) L116K CooA are Cys(75) and Lys(116) and those in the Fe(II) form are His(77) and Lys(116). A possible explanation for CO-independent activity in L116K CooA is that ligation of Lys(116) results in a repositioning of the C-helices at the CooA dimer interface. This result is consistent with that repositioning being an important aspect of the activation of wild-type CooA by CO.

Stationary and time-resolved resonance Raman spectra of His77 and Met95 mutants of the isolated heme domain of a direct oxygen sensor from Escherichia coli

The heme environments of Met(95) and His(77) mutants of the isolated heme-bound PAS domain (Escherichia coli DOS PAS) of a direct oxygen sensing protein from E. coli (E. coli DOS) were investigated with resonance Raman (RR) spectroscopy and compared with the wild type (WT) enzyme. The RR spectra of both the reduced and oxidized WT enzyme were characteristic of six-coordinate low spin heme complexes from pH 4 to 10. The time-resolved RR spectra of the photodissociated CO-WT complex had an iron-His stretching band (nu(Fe-His)) at 214 cm(-1), and the nu(Fe-CO) versus nu(CO) plot of CO-WT E. coli DOS PAS fell on the line of His-coordinated heme proteins. The photodissociated CO-H77A mutant complex did not yield the nu(Fe-His) band but gave a nu(Fe-Im) band in the presence of imidazole. The RR spectrum of the oxidized M95A mutant was that of a six-coordinate low spin complex (i.e. the same as that of the WT enzyme), whereas the reduced mutant appeared to contain a five-coordinate heme complex. Taken together, we suggest that the heme of the reduced WT enzyme is coordinated by His(77) and Met(95), and that Met(95) is displaced by CO and O(2). Presumably, the protein conformational change that occurs upon exchange of an unknown ligand for Met(95) following heme reduction may lead to activation of the phosphodiesterase domain of E. coli DOS.

Resonance Raman and ligand binding studies of the oxygen-sensing signal transducer protein HemAT from Bacillus subtilis

HemAT-Bs is a heme-containing signal transducer protein responsible for aerotaxis of Bacillus subtilis. The recombinant HemAT-Bs expressed in Escherichia coli was purified as the oxy form in which oxygen was bound to the ferrous heme. Oxygen binding and dissociation rate constants were determined to be k(on) = 32 microm(-1) s(-1) and k(off) = 23 s(-1), respectively, revealing that HemAT-Bs has a moderate oxygen affinity similar to that of sperm whale myoglobin (Mb). The rate constant for autoxidation at 37 degrees C was 0.06 h(-1), which is also close to that of Mb. Although the electronic absorption spectra of HemAT-Bs were similar to those of Mb, HemAT-Bs showed some unique characteristics in its resonance Raman spectra. Oxygen-bound HemAT-Bs gave the nu(Fe-O(2)) band at a noticeably low frequency (560 cm(-1)), which suggests a unique hydrogen bonding between a distal amino acid residue and the proximal atom of the bound oxygen molecule. Deoxy HemAT-Bs gave the nu(Fe-His) band at a higher frequency (225 cm(-1)) than those of ordinary His-coordinated deoxy heme proteins. CO-bound HemAT-Bs gave the nu(Fe-CO) and nu(C-O) bands at 494 and 1964 cm(-1), respectively, which fall on the same nu(C-O) versus nu(Fe-CO) correlation line as that of Mb. Based on these results, the structural and functional properties of HemAT-Bs are discussed.

Mapping CooA.RNA polymerase interactions. Identification of activating regions 2 and 3 in CooA, the co-sensing transcriptional activator

CooA is a CO-sensing protein that activates the transcription of genes encoding the CO-oxidation (coo) regulon, whose polypeptide products are required for utilizing CO as an energy source in Rhodospirillum rubrum. CooA binds to a position overlapping the -35 element of the P(cooF) promoter, similar to the arrangement of class II CRP (cAMP receptor protein)- and FNR (fumarate and nitrate reductase activator protein)-dependent promoters when expressed in Escherichia coli. Gain-of-function CooA variants were isolated in E. coli following mutagenesis of the portion of cooA encoding the effector-binding domain. Some of the mutations affect regions of CooA that are homologous to the activating regions (AR2 and AR3) previously identified in CRP and FNR, whereas others affect residues that lie in a region of CooA between AR2 and AR3. These CooA variants are comparable to wild-type (WT) CooA in DNA binding affinity in response to CO but differ in transcription activation, presumably because of altered interactions with E. coli RNA polymerase. Based on predictions of similarity to CRP and FNR, loss-of-function CooA variants were obtained in the AR2 and AR3 regions that have minimal transcriptional activity, yet have WT-like DNA binding affinities in response to CO. This study demonstrates that WT CooA contains AR2- and AR3-like surfaces that are required for optimal transcription activation.

Ligand-switching intermediates for the CO-sensing transcriptional activator CooA measured by pulse radiolysis

CooA is a heme-containing and CO-sensing transcriptional activator whose activity is regulated by CO. The protoheme that acts as a CO sensor in CooA shows unique properties for its coordination structure. The Cys75 axial ligand of the ferric heme is replaced by His77 upon the reduction of the heme iron and vice versa. In this work, the ligand-switching process induced by the reduction of the heme was investigated by the technique of pulse radiolysis. Hydrated electron reduced the heme iron in ferric CooA within 1 micros to form the first intermediate with the Soret peak at 440 nm, suggesting that a six-coordinate ferrous heme with a thiolate axial ligand was formed initially. The first intermediate was converted into the second intermediate with the time constant of 40 micros (k = 2.5 x 10(4) x s(-1)). In the second intermediate, the thiolate from Cys75 was thought to be protonated and/or the Fe-S bond was thought to be elongated. The second intermediate was converted into the final reduced form with the time constant of 2.9 ms (k = 3.5 x 10(2) x s(-1)) for wild-type CooA. The ligand exchange between Cys75 and His77 took place during the conversion of the second intermediate into the final reduced form.

A quantum chemical survey of metalloporphyrin-nitrosyl linkage isomers: insights into the observation of multiple FeNO conformations in a recent crystallographic determination of nitrophorin 4

Using density functional theory-based geometry optimizations, we have searched for eta(1)-NO, eta(1)-ON (isonitrosyl), and eta(2)-NO (side-on bound NO) linkage isomers of a number of metalloporphyrin-NO complexes, M(Por)(NO)(L), where Por = porphinato dianion, M = Mn(II), Fe(II), Fe(III), Ru(II), Ru(III), Co(II), and Rh(II), and L = no ligand, SMe, Ph, and imidazole. The eta(1)-NO isomer had the lowest energy in all cases, and the isonitrosyl isomer was also located as a higher energy potential energy minimum in a number of cases. The eta(2)-NO isomer was only located as a minimum for Mn(II) (L = no ligand), Fe(III) (L = no ligand), and Ru(III) (L = Ph, imidazole, pyrdine), suggesting that an [MNO](6) electron count is important for stabilization of the eta(2) mode of ligation. However, in the presence of axial ligands L, the side-on isomers of [FeNO](6) complexes were not stable and opened up to an unusual geometry where the FeN(O) and NO vectors were tilted in opposite directions relative to the heme normal. Exactly such a geometry, as well as a "normal" upright geometry, has been observed in a recent crystallographic determination of nitrophorin 4 (Nature Struct. Biol. 2000, 7, 551), a salivary protein from the blood-sucking insect Rhodnius prolixus. Together, the calculated and experimental result illustrate the extreme softness of the FeNO potential energy surface toward various forms of tilting and bending deformations.

Redox-mediated transcriptional activation in a CooA variant

CooA, the carbon monoxide-sensing transcription factor from Rhodospirillum rubrum, binds CO at a reduced (Fe(II)) heme moiety with resulting conformational changes that promote DNA binding. In this study, we report a variant of CooA, M124R, that is active in transcriptional activation in a redox-dependent manner. Where wild-type CooA is active only in the Fe(II) + CO form, M124R CooA is active in both Fe(II) + CO and Fe(III) forms. Analysis of the pH dependence of the activity of Fe(III) M124R CooA demonstrated that the activity was also coordination state-dependent with a five-coordinate, high-spin species identified as the active form and Cys(75) as the retained ligand. In contrast, the active Fe(II) + CO forms of both wild-type and M124R CooA are six-coordinate and low-spin with a protein ligand other than Cys(75), so that WT and Fe(III) M124R CooA are apparently achieving an active conformation despite two different heme coordination and ligation states. A hypothesis to explain these results is proposed. This study demonstrates the utility of CooA as a model system for the isolation of functionally interesting heme proteins.

Binding of CO at the Pro2 side is crucial for the activation of CO-sensing transcriptional activator CooA. (1)H NMR spectroscopic studies

CooA is a heme-containing transcriptional activator that anaerobically binds to DNA at CO atmosphere. To obtain information on the conformational transition of CooA induced by CO binding to the heme, we assigned ring current-shifted (1)H NMR signals of CooA using two mutants whose axial ligands of the heme were replaced. In the absence of CO, the NMR spectral pattern of H77Y CooA, in which the axial histidine (His(77)) was replaced with tyrosine, was similar to that of wild-type CooA. In contrast, the spectra of CooADeltaN5, in which the NH(2) termini including the other axial ligand (Pro(2)) were deleted, were drastically modulated. We assigned three signals of wild-type CooA at -4.5, -3.6, and -2.8 ppm to delta(1)-, alpha-, and delta(2)-protons of Pro(2), respectively. The Pro(2) signals were undetectable in the upfield region of the spectrum of the CO-bound state, which confirms that CO displaces Pro(2). Interestingly, the Pro(2) signals were observed for CO-bound H77Y CooA, implying that CO binds to the trans position of Pro(2) in H77Y CooA. The abolished CO-dependent transcriptional activity of H77Y CooA is therefore the consequence of Pro(2) ligation. These observations are consistent with the view that the movement of the NH(2) terminus triggers the conformational transition to the DNA binding form.

Recent advances in heme-protein sensors

In recent years, an increasing number of proteins have been discovered which utilize heme cofactors to sense oxygen, carbon monoxide and nitric oxide. The identification and characterization of these proteins are revising our understanding of heme-mediated allostery first established in the early 1960s. Biochemical and structural studies are revealing new mechanisms for heme-driven conformational changes distinct from the classical hemoglobin model.

Redox properties and coordination structure of the heme in the co-sensing transcriptional activator CooA

The CO-sensing transcriptional activator CooA contains a six-coordinate protoheme as a CO sensor. Cys(75) and His(77) are assigned to the fifth ligand of the ferric and ferrous hemes, respectively. In this study, we carried out alanine-scanning mutagenesis and EXAFS analyses to determine the coordination structure of the heme in CooA. Pro(2) is thought to be the sixth ligand of the ferric and ferrous hemes in CooA, which is consistent with the crystal structure of ferrous CooA (Lanzilotta, W. N., Schuller, D. J., Thorsteinsson, M. V., Kerby, R. L., Roberts, G. P., and Poulos, T. L. (2000) Nat. Struct. Biol. 7, 876-880). CooA exhibited anomalous redox chemistry, i.e. hysteresis was observed in electrochemical redox titrations in which the observed reduction and oxidation midpoint potentials were -320 mV and -260 mV, respectively. The redox-controlled ligand exchange of the heme between Cys(75) and His(77) is thought to cause the difference between the reduction and oxidation midpoint potentials.

Dissociation and recombination between ligands and heme in a CO-sensing transcriptional activator CooA. A flash photolysis study

CooA from Rhodospirillum rubrum is a transcriptional activator in which a heme prosthetic group acts as a CO sensor and regulates the activity of the protein. In this study, the electronic relaxation of the heme, and the concurrent recombination between ligands and the heme at approximately 280 K were examined in an effort to understand the environment around the heme and the dynamics of the ligands. Upon photoexcitation of the reduced CooA at 400 nm, electronic relaxation of the heme occurred with time constants of 0.8 and 1.7 ps. The ligand rebinding was substantially completed with a time constant of 6.5 ps, followed by a slow relaxation process with a time constant of 173 ps. In the case of CO-bound CooA, relaxation of the excited heme occurred with two time constants, 1.1 and 2.4 ps, which were largely similar to those with reduced CooA. The subsequent CO recombination process was remarkably fast compared with that of other CO-bound heme proteins. It was well described as a biphasic geminate recombination process with time constants of 78 ps (60%) and 386 ps (30%). About 10% of the excited heme remained unligated at 1.9 ns. The dynamics of rebinding of CO thus will help us to understand how the physiologically relevant diatomic molecule approaches the heme binding site in CooA with picosecond resolution.