Displacement of O2 and CO by cyanide from the active site of helix pomatia β-hemocyanin.: Formation of a mixed-liganded species

Addition of KCN to Helix pomatia β-hemocyanin fully saturated with either O₂ or CO results in a decrease of the spectroscopic properties of the protein (absorbance at 340 nm and luminescence at 550 nm) due to the displacement of the gaseous ligands (O₂ or CO) from the active site. The anionic form of cyanide (CN^?) is supposed to bind to the active site; its intrinsic affinity for the protein, as calculated from independent O₂ and CO displacement experiments, is between 2 and 6 × 10⁶M^?1. The replacement of O₂ or CO shows some differences which may be correlated with the different modes of binding at the active site. Thus, while displacement of oxygen by cyanide is hyperbolic, addition of cyanide to carbonylated hemocyanin shows a lag phase. This finding suggests the formation of a mixed liganded complex at the active site. The simultaneous presence of CO and CN^? at the active site of hemocyanin is also supported by the experiment in which addition of small amounts of KCN to hemocyanin partially saturated with O₂ and CO gives rise to an increase of emission intensity and a concomitant decrease of the O₂ absorption band. The mixed-liganded species displays luminescence properties similar to those of CO-saturated hemocyanin, and the formation of the complex is reversible on dialysis or oxygenation.     

The Influence of Oxygen on [NiFe]–Hydrogenase Cofactor Biosynthesis and How Ligation of Carbon Monoxide Precedes Cyanation

The class of [NiFe]–hydrogenases is characterized by a bimetallic cofactor comprising low–spin nickel and iron ions, the latter of which is modified with a single carbon monoxide (CO) and two cyanide (CN⁻) molecules. Generation of these ligands in vivo requires a complex maturation apparatus in which the HypC–HypD complex acts as a ‘construction site’ for the Fe–(CN)₂CO portion of the cofactor. The order of addition of the CO and CN^– ligands determines the ultimate structure and catalytic efficiency of the cofactor; however much debate surrounds the succession of events. Here, we present an FT–IR spectroscopic analysis of HypC–HypD isolated from a hydrogenase–competent wild–type strain of Escherichia coli. In contrast to previously reported samples, HypC–HypD showed spectral contributions indicative of an electron–rich Fe–CO cofactor, at the same time lacking any Fe–CN^– signatures. This immature iron site binds external CO and undergoes oxidative damage when in contact with O₂. Binding of CO protects the site against loss of spectral features associated with O₂ damage. Our findings strongly suggest that CO ligation precedes cyanation in vivo. Furthermore, the results provide a rationale for the deleterious effects of O₂ on in vivo cofactor biosynthesis.     

Reaction of carbon monoxide with hemocyanin: Stereochemical effects of a non-bridging ligand

The carbon monoxide binding equilibria and kinetics of a number of molluscan and arthropodal hemocyanins have been investigated employing the visible luminescence of the carbon monoxide-copper complex.Proteins from both phyla, in oligomeric and monomeric form, bind carbon monoxide non-co-operatively; the reaction is largely enthalpy driven is associated with a small unfavourable entropy change.Molluscan hemocyanins display a carbon monoxide affinity (p₅₀ = 1 to 10mm Hg) higher than that of arthropodal hemocyanins (p₅₀ = 100 to 700mm Hg), and only Panulirus interruptus hemocyanin, among those studied here, exhibits a small Bohr effect. The observed differences in equilibrium constant are kinetically reflected in differences in the carbon monoxide dissociation rate constant, which ranges from 20 to 70 s^?1 for molluscan hemocyanins and from 200 to 9000 s^?1 for arthropodal hemocyanins; on the other hand the differences in the combination rate constants between the two phyla are considerably smaller. A comparison of the equilibrium and kinetic results shows some discrepancies between the two sets of data, suggesting that carbon monoxide binding may be governed by a complex mechanism.The correlation between the ligand binding properties and the stereochemistry of the active site is discussed in the light of the knowledge that, while oxygen is bound to both copper atoms in a site, carbon monoxide is a “non-bridging” ligand, being bound to only one of the metals.     

Kinetic studies of the reactions of O2 and NO with reduced Thermus thermophilus ba3 and bovine aa3 using photolabile carriers

The reactions of molecular oxygen (O₂) and nitric oxide (NO) with reduced Thermus thermophilus (Tt) ba₃ and bovine heart aa₃ were investigated by time-resolved optical absorption spectroscopy to establish possible relationships between the structural diversity of these enzymes and their reaction dynamics. To determine whether the photodissociated carbon monoxide (CO) in the CO flow-flash experiment affects the ligand binding dynamics, we monitored the reactions in the absence and presence of CO using photolabile O₂ and NO complexes. The binding of O₂/NO to reduced ba₃ in the absence of CO occurs with a second-order rate constant of 1 × 10⁹ M^? 1 s^? 1. This rate is 10-times faster than for the mammalian enzyme, and which is attributed to structural differences in the ligand channels of the two enzymes. Moreover, the O₂/NO binding in ba₃ is 10-times slower in the presence of the photodissociated CO while the rates are the same for the bovine enzyme. This indicates that the photodissociated CO directly or indirectly impedes O₂ and NO access to the active site in Tt ba₃, and that traditional CO flow-flash experiments do not accurately reflect the O₂ and NO binding kinetics in ba₃. We suggest that in ba₃ the binding of O₂ (NO) to heme a₃^2 + causes rapid dissociation of CO from Cu_B⁺ through steric or electronic effects or, alternatively, that the photodissociated CO does not bind to Cu_B⁺. These findings indicate that structural differences between Tt ba₃ and the bovine aa₃ enzyme are tightly linked to mechanistic differences in the functions of these enzymes. This article is part of a Special Issue entitled: Respiratory Oxidases.     

The effect of mitochondrial energization on cytochrome c oxidase kinetics as measured at low temperatures. I. The reaction with carbon monoxide

The kinetics of CO binding by the cytochrome c oxidase of pigeon heart mitochondria were studied as a function of membrane energization at temperatures from 180 to 280°K in an ethylene glycol/water medium. Samples energized by ATP showed acceleration of CO binding compared to those untreated or uncoupled by carbonylcyanide p-trifluoromethoxyphenylhydrazone but only at relatively low temperatures and high CO concentrations. Experiments using samples in a “mixed valency” (partially oxidized) state showed that the acceleration of ligand binding is not due to the formation of a partially oxidized state via reverse electron transport.It is concluded that in the deenergized state one CO molecule can be closely associated with the cytochrome a₃ heme site without actually being bound to the heme iron; in the energized state, two or more ligand molecules can occupy this intermediate position.The change in the apparent ligand capacity of a region near the heme iron in response to energization is evidence for an interaction between cytochrome oxidase and the ATPase system. Furthermore, these results suggest a control mechanism for O₂ binding.     

The Reactions of O2 and NO with Mixed-Valence ba3 Cytochrome c Oxidase from Thermus thermophilus

Earlier CO flow-flash experiments on the fully reduced Thermus thermophilus ba₃ (Tt ba₃) cytochrome oxidase revealed that O₂ binding was slowed down by a factor of 10 in the presence of CO (Szundi et al., 2010, PNAS 107, 21010–21015). The goal of the current study is to explore whether the long apparent lifetime (∼50 ms) of the Cu_B⁺-CO complex generated upon photolysis of the CO-bound mixed-valence Tt ba₃ (Koutsoupakis et al., 2019, Acc. Chem. Res. 52, 1380–1390) affects O₂ and NO binding and the ability of Cu_B to act as an electron donor during O-O bond splitting. The CO recombination, NO binding, and the reaction of mixed-valence Tt ba₃ with O₂ were investigated by time-resolved optical absorption spectroscopy using the CO flow-flash approach and photolabile O₂ and NO carriers. No electron backflow was detected after photolysis of the mixed-valence CO-bound Tt ba₃. The rate of O₂ and NO binding was two times slower than in the fully reduced enzyme in the presence of CO and 20 times slower than in the absence of CO. The purported long-lived Cu_B⁺-CO complex did not prevent O-O bond splitting and the resulting P_M formation, which was significantly faster (5–10 times) than in the bovine heart enzyme. We propose that O₂ binding to heme a₃ in Tt ba₃ causes CO to dissociate from Cu_B⁺ in a concerted manner through steric and/or electronic effects, thus allowing Cu_B⁺ to act as an electron donor in the mixed-valence enzyme. The significantly faster O₂ binding and O-O bond cleavage in Tt ba₃ compared to analogous steps in the aa₃ oxidases could reflect evolutionary adaptation of the enzyme to the microaerobic conditions of the T. thermophilus HB8 species.     

The two CO-dehydrogenases of Thermococcus sp. AM4

Ni-containing CO-dehydrogenases (CODHs) allow some microorganisms to couple ATP synthesis to CO oxidation, or to use either CO or CO₂ as a source of carbon. The recent detailed characterizations of some of them have evidenced a great diversity in terms of catalytic properties and resistance to O₂. In an effort to increase the number of available CODHs, we have heterologously produced in Desulfovibrio fructosovorans, purified and characterized the two CooS-type CODHs (CooS1 and CooS2) from the hyperthermophilic archaeon Thermococcus sp. AM4 (Tc). We have also crystallized CooS2, which is coupled in vivo to a hydrogenase. CooS1 and CooS2 are homodimers, and harbour five metalloclusters: two [Ni4Fe-4S] C clusters, two [4Fe-4S] B clusters and one interfacial [4Fe-4S] D cluster. We show that both are dependent on a maturase, CooC1 or CooC2, which is interchangeable. The homologous protein CooC3 does not allow Ni insertion in either CooS. The two CODHs from Tc have similar properties: they can both oxidize and produce CO. The Michaelis constants (K_m) are in the microM range for CO and in the mM range (CODH 1) or above (CODH 2) for CO₂. Product inhibition is observed only for CO₂ reduction, consistent with CO₂ binding being much weaker than CO binding. The two enzymes are rather O₂ sensitive (similarly to CODH II from Carboxydothermus hydrogenoformans), and react more slowly with O₂ than any other CODH for which these data are available.     

Role of cis-Acting Sites in Stimulation of the Phage λ PRM Promoter by CI-Mediated Looping

The lysogenic state of phage λ is maintained by the CI repressor. CI binds to three operators each in the right operator (O_R) and left operator (O_L) regions, which lie 2.4 kb apart. At moderate CI levels, the predominant binding pattern is two dimers of CI bound cooperatively at each regulatory region. The resulting tetramers can then interact, forming an octamer and a loop of the intervening DNA. CI is expressed from the P_RM promoter, which lies in the O_R region and is subjected to multiple regulatory controls. Of these, the most recently discovered is stimulation by loop formation. In this work, we have investigated the mechanism by which looping stimulates P_RM. We find that two cis-acting sites lying in the O_L region are involved. One site, an UP element, is required for stimulation. Based on the behavior of other promoters with UP elements located upstream of the −35 region, we suggest that a subunit of RNA polymerase (RNAP) bound at P_RM binds to the UP element located in the O_L region. In addition, adjacent to the UP element lies a binding site for integration host factor (IHF); this site plays a less critical role but is required for stimulation of the weak prm240 allele. A loop with CI at the O_L2 and O_L3 operators does not stimulate P_RM, while one with CI only at O_L2 provides some stimulation. We discuss possible mechanisms for stimulation.     

Structural dynamics of proximal heme pocket in HemAT-Bs associated with oxygen dissociation

HemAT from Bacillus subtilis (HemAT-Bs) is a heme-containing O₂ sensor protein that acts as a chemotactic signal transducer. Binding of O₂ to the heme in the sensor domain of HemAT-Bs induces a conformational change in the protein matrix, and this is transmitted to a signaling domain. To characterize the specific mechanism of O₂-dependent conformational changes in HemAT-Bs, we investigated time-resolved resonance Raman spectra of the truncated sensor domain and the full-length HemAT-Bs upon O₂ and CO dissociation. A comparison between the O₂ and CO complexes provides insights on O₂/CO discrimination in HemAT-Bs. While no spectral changes upon CO dissociation were observed in our experimental time window between 10 ns and 100 μs, the band position of the stretching mode between the heme iron and the proximal histidine, ν(Fe–His), for the O₂-dissociated HemAT-Bs was lower than that for the deoxy form on time-resolved resonance Raman spectra. This spectral change specific to O₂ dissociation would be associated with the O₂/CO discrimination in HemAT-Bs. We also compared the results obtained for the truncated sensor domain and the full-length HemAT-Bs, which showed that the structural dynamics related to O₂ dissociation for the full-length HemAT-Bs are faster than those for the sensor domain HemAT-Bs. This indicates that the heme proximal structural dynamics upon O₂ dissociation are coupled with signal transduction in HemAT-Bs.     

The Hydrogenase Activity of the Molybdenum/Copper-containing Carbon Monoxide Dehydrogenase of Oligotropha carboxidovorans

The reaction of the air-tolerant CO dehydrogenase from Oligotropha carboxidovorans with H₂ has been examined. Like the Ni-Fe CO dehydrogenase, the enzyme can be reduced by H₂ with a limiting rate constant of 5.3 s⁻¹ and a dissociation constant K_d of 525 μm; both k_red and k_red/K_d, reflecting the breakdown of the Michaelis complex and the reaction of free enzyme with free substrate in the low [S] regime, respectively, are largely pH-independent. During the reaction with H₂, a new EPR signal arising from the Mo/Cu-containing active site of the enzyme is observed which is distinct from the signal seen when the enzyme is reduced by CO, with greater g anisotropy and larger hyperfine coupling to the active site ^63,65Cu. The signal also exhibits hyperfine coupling to at least two solvent-exchangeable protons of bound substrate that are rapidly exchanged with solvent. Proton coupling is also evident in the EPR signal seen with the dithionite-reduced native enzyme, and this coupling is lost in the presence of bicarbonate. We attribute the coupled protons in the dithionite-reduced enzyme to coordinated water at the copper site in the native enzyme and conclude that bicarbonate is able to displace this water from the copper coordination sphere. On the basis of our results, a mechanism for H₂ oxidation is proposed which involves initial binding of H₂ to the copper of the binuclear center, displacing the bound water, followed by sequential deprotonation through a copper-hydride intermediate to reduce the binuclear center.     

Weak O2 binding and strong H2O2 binding at the non-heme diiron center of trypanosome alternative oxidase

Alternative oxidase (AOX) catalyzes the four-electron reduction of dioxygen to water as an additional terminal oxidase, and the catalytic reaction is critical for the parasite to survive in its bloodstream form. Recently, the X-ray crystal structure of trypanosome alternative oxidase (TAO) complexed with ferulenol was reported and the molecular structure of the non-heme diiron center was determined. The binding of O₂ was a unique side-on type compared to other iron proteins. In order to characterize the O₂ binding state of TAO, the O₂ binding states were searched at a quantum mechanics/molecular mechanics (QM/MM) theoretical level in the present study. We found that the most stable O₂ binding state is the end-on type, and the binding states of the side-on type are higher in energy. Based on the binding energies and electronic structure analyses, O₂ binds very weakly to the TAO iron center (ΔE =6.7 kcal mol^?1) in the electronic state of Fe(II)…OO, not in the suggested charge transferred state such as the superoxide state (Fe(III)OO· ^–) as seen in hemerythrin. Coordination of other ligands such as water, Cl^?, CN^?, CO, N₃^? and H₂O₂ was also examined, and H₂O₂ was found to bind most strongly to the Fe(II) site by ΔE = 14.0 kcal mol^?1. This was confirmed experimentally through the measurement of ubiquinol oxidase activity of TAO and Cryptosporidium parvum AOX which was found to be inhibited by H₂O₂ in a dose-dependent and reversible manner.     

Structural insights into RNA-dependent eukaryal and archaeal selenocysteine formation

The micronutrient selenium is present in proteins as selenocysteine (Sec). In eukaryotes and archaea, Sec is formed in a tRNA-dependent conversion of O-phosphoserine (Sep) by O-phosphoseryl-tRNA:selenocysteinyl-tRNA synthase (SepSecS). Here, we present the crystal structure of Methanococcus maripaludis SepSecS complexed with PLP at 2.5 Å resolution. SepSecS, a member of the Fold Type I PLP enzyme family, forms an (α₂)₂ homotetramer through its N-terminal extension. The active site lies on the dimer interface with each monomer contributing essential residues. In contrast to other Fold Type I PLP enzymes, Asn247 in SepSecS replaces the conserved Asp in binding the pyridinium nitrogen of PLP. A structural comparison with Escherichia coli selenocysteine lyase allowed construction of a model of Sep binding to the SepSecS catalytic site. Mutations of three conserved active site arginines (Arg72, Arg94, Arg307), protruding from the neighboring subunit, led to loss of in vivo and in vitro activity. The lack of active site cysteines demonstrates that a perselenide is not involved in SepSecS-catalyzed Sec formation; instead, the conserved arginines may facilitate the selenation reaction. Structural phylogeny shows that SepSecS evolved early in the history of PLP enzymes, and indicates that tRNA-dependent Sec formation is a primordial process.     

The mitochondrial DNA polymerase as a target of oxidative damage

The mitochondrial respiratory chain is a source of reactive oxygen species (ROS) that are responsible for oxidative modification of biomolecules, including proteins. Due to its association with mitochondrial DNA, DNA polymerase γ (pol γ) is in an environment to be oxidized by hydrogen peroxide and hydroxyl radicals that may be generated in the presence of iron ions associated with DNA. We tested whether human pol γ was a possible target of ROS with H₂O₂ and investigated the effect on the polymerase activities and DNA binding efficiency. A 1 h treatment with 250 µM H₂O₂ significantly inhibited DNA polymerase activity of the p140 subunit and lowered its DNA binding efficiency. Addition of p55 to the p140 catalytic subunit prior to H₂O₂ treatment offered protection from oxidative inactivation. Oxidatively modified amino acid residues in pol γ  resulting from H₂O₂ treatment were observed in vitro as well as in vivo, in SV40-transfected human fibroblasts. Pol γ was detected as one of the major oxidized mitochondrial matrix proteins, with a detectable decline in polymerase activity. These results suggest pol γ as a target of oxidative damage, which may result in a reduction in mitochondrial DNA replication and repair capacities.     

Hemoglobin–Albumin Cluster Incorporating a Pt Nanoparticle: Artificial O2 Carrier with Antioxidant Activities

A covalent core–shell structured protein cluster composed of hemoglobin (Hb) at the center and human serum albumins (HSA) at the periphery, Hb-HSA_m, is an artificial O₂ carrier that can function as a red blood cell substitute. Here we described the preparation of a novel Hb-HSA₃ cluster with antioxidant activities and its O₂ complex stable in aqueous H₂O₂ solution. We used an approach of incorporating a Pt nanoparticle (PtNP) into the exterior HSA unit of the cluster. A citrate reduced PtNP (1.8 nm diameter) was bound tightly within the cleft of free HSA with a binding constant (K) of 1.1×10⁷ M⁻¹, generating a stable HSA-PtNP complex. This platinated protein showed high catalytic activities for dismutations of superoxide radical anions (O₂ ^•–) and hydrogen peroxide (H₂O₂), i.e., superoxide dismutase and catalase activities. Also, Hb-HSA₃ captured PtNP into the external albumin unit (K = 1.1×10⁷ M⁻¹), yielding an Hb-HSA₃(PtNP) cluster. The association of PtNP caused no alteration of the protein surface net charge and O₂ binding affinity. The peripheral HSA-PtNP shell prevents oxidation of the core Hb, which enables the formation of an extremely stable O₂ complex, even in H₂O₂ solution.     

Effective Pumping Proton Collection Facilitated by a Copper Site (CuB) of Bovine Heart Cytochrome c Oxidase,Revealed by a Newly Developed Time-resolved Infrared System

X-ray structural and mutational analyses have shown that bovine heart cytochrome c oxidase (CcO) pumps protons electrostatically through a hydrogen bond network using net positive charges created upon oxidation of a heme iron (located near the hydrogen bond network) for O₂ reduction. Pumping protons are transferred by mobile water molecules from the negative side of the mitochondrial inner membrane through a water channel into the hydrogen bond network. For blockage of spontaneous proton back-leak, the water channel is closed upon O₂ binding to the second heme (heme a₃) after complete collection of the pumping protons in the hydrogen bond network. For elucidation of the structural bases for the mechanism of the proton collection and timely closure of the water channel, conformational dynamics after photolysis of CO (an O₂ analog)-bound CcO was examined using a newly developed time-resolved infrared system feasible for accurate detection of a single C=O stretch band of α-helices of CcO in H₂O medium. The present results indicate that migration of CO from heme a₃ to Cu_B in the O₂ reduction site induces an intermediate state in which a bulge conformation at Ser-382 in a transmembrane helix is eliminated to open the water channel. The structural changes suggest that, using a conformational relay system, including Cu_B, O₂, heme a₃, and two helix turns extending to Ser-382, Cu_B induces the conformational changes of the water channel that stimulate the proton collection, and senses complete proton loading into the hydrogen bond network to trigger the timely channel closure by O₂ transfer from Cu_B to heme a₃.     

Effects of hydrogen sulfide on the heme coordination structure and catalytic activity of the globin-coupled oxygen sensor <Emphasis Type="Italic">Af</Emphasis>GcHK

AfGcHK is a globin-coupled histidine kinase that is one component of a two-component signal transduction system. The catalytic activity of this heme-based oxygen sensor is due to its C-terminal kinase domain and is strongly stimulated by the binding of O₂ or CO to the heme Fe(II) complex in the N-terminal oxygen sensing domain. Hydrogen sulfide (H₂S) is an important gaseous signaling molecule and can serve as a heme axial ligand, but its interactions with heme-based oxygen sensors have not been studied as extensively as those of O₂, CO, and NO. To address this knowledge gap, we investigated the effects of H₂S binding on the heme coordination structure and catalytic activity of wild-type AfGcHK and mutants in which residues at the putative O₂-binding site (Tyr45) or the heme distal side (Leu68) were substituted. Adding Na₂S to the initial OH-bound 6-coordinate Fe(III) low-spin complexes transformed them into SH-bound 6-coordinate Fe(III) low-spin complexes. The Leu68 mutants also formed a small proportion of verdoheme under these conditions. Conversely, when the heme-based oxygen sensor EcDOS was treated with Na₂S, the initially formed Fe(III)–SH heme complex was quickly converted into Fe(II) and Fe(II)–O₂ complexes. Interestingly, the autophosphorylation activity of the heme Fe(III)–SH complex was not significantly different from the maximal enzyme activity of AfGcHK (containing the heme Fe(III)–OH complex), whereas in the case of EcDOS the changes in coordination caused by Na₂S treatment led to remarkable increases in catalytic activity.     

The diffusion-controlled reaction kinetics of the binding of CO and O2 to myoglobin in glycerol-water mixtures of high viscosity

The kinetics of the reaction of myoglobin (Mb) with CO and O₂ have been studied as a function of temperature by flash photolysis in mixtures of glycerol and water of high viscosities. This was done in order to examine the importance of diffusion-controlled kinetics on protein-ligand reactions. The apparent activation enthalpies of the binding reaction show changes with temperature consistent with a change from chemical activation control of the reaction at higher temperatures to diffusion control at the lower temperatures and higher viscosities. The activation enthalpies for ligand binding in the diffusion-controlled temperature region are similar in value to the viscosity activation energies of the particular solvent mixture as might be expected for a diffusion-controlled reaction. Curve fitting of the rate-temperature data yields factors by which the diffusion-controlled reaction departs from that predicted for reaction between spherically symmetric, uniformly reactive molecules of equal radii. This factor is between 0.1 and 6, depending both upon the solvent mixture and the ligand. Various models for diffusion-controlled reaction with steric requirements are examined in order to rationalize these results. The existence of a linear correlation between ΔH3 and ΔS3 for the chemica activation-controlled portions of reaction yield isokinetic temperatures of 305 and 288 °K for the CO and O₂ reactions, respectively.     

Isonicotinic Acid Hydrazide Conversion to Isonicotinyl-NAD by Catalase-peroxidases

Activation of the pro-drug isoniazid (INH) as an anti-tubercular drug in Mycobacterium tuberculosis involves its conversion to isonicotinyl-NAD, a reaction that requires the catalase-peroxidase KatG. This report shows that the reaction proceeds in the absence of KatG at a slow rate in a mixture of INH, NAD⁺, Mn²⁺, and O₂, and that the inclusion of KatG increases the rate by >7 times. Superoxide, generated by either Mn²⁺- or KatG-catalyzed reduction of O₂, is an essential intermediate in the reaction. Elimination of the peroxidatic process by mutation slows the rate of reaction by 60% revealing that the peroxidatic process enhances, but is not essential for isonicotinyl-NAD formation. The isonicotinyl-NAD^•+ radical is identified as a reaction intermediate, and its reduction by superoxide is proposed. Binding sites for INH and its co-substrate, NAD⁺, are identified for the first time in crystal complexes of Burkholderia pseudomallei catalase-peroxidase with INH and NAD⁺ grown by co-crystallization. The best defined INH binding sites were identified, one in each subunit, on the opposite side of the protein from the entrance to the heme cavity in a funnel-shaped channel. The NAD⁺ binding site is ∼20 Å from the entrance to the heme cavity and involves interactions primarily with the AMP portion of the molecule in agreement with the NMR saturation transfer difference results.