Crystal structural analysis of human serum albumin complexed with hemin and fatty acid

Background

Human serum albumin (HSA) is an abundant plasma protein that binds a wide variety of hydrophobic ligands including fatty acids, bilirubin, thyroxine and hemin. Although HSA-heme complexes do not bind oxygen reversibly, it may be possible to develop modified HSA proteins or heme groups that will confer this ability on the complex.

Results

We present here the crystal structure of a ternary HSA-hemin-myristate complex, formed at a 1:1:4 molar ratio, that contains a single hemin group bound to subdomain IB and myristate bound at six sites. The complex displays a conformation that is intermediate between defatted HSA and HSA-fatty acid complexes; this is likely to be due to low myristate occupancy in the fatty acid binding sites that drive the conformational change. The hemin group is bound within a narrow D-shaped hydrophobic cavity which usually accommodates fatty acid; the hemin propionate groups are coordinated by a triad of basic residues at the pocket entrance. The iron atom in the centre of the hemin is coordinated by Tyr161.

Conclusion

The structure of the HSA-hemin-myristate complex (PDB ID 1o9x) reveals the key polar and hydrophobic interactions that determine the hemin-binding specificity of HSA. The details of the hemin-binding environment of HSA provide a structural foundation for efforts to modify the protein and/or the heme molecule in order to engineer complexes that have favourable oxygen-binding properties.

     

Dynamics of heme complexed with human serum albumin: a theoretical approach

Human serum albumin (HSA) is the most abundant protein in the blood serum. It binds several ligands and has an especially strong affinity for heme, hence becoming a natural candidate for oxygen transport. In order to analyze the interaction of HSA-heme, molecular dynamics simulations of HSA with bound heme were performed. Based on the results of X-ray diffraction, the binding site of the heme, localized in subdomain IB, was considered. We analyzed the fluctuations and their correlations along trajectories to detect collective motions. The role of H bonds and salt bridges in the stabilization of heme in its pocket was also investigated. Complementarily, the localization of water molecules in the hydrophobic pocket and the interaction with heme were discussed.     

The 2.6-A crystal structure of Pseudomonas putida cytochrome P-450

The crystal structure of Pseudomonas putida cytochrome P-450cam in the ferric, camphor bound form has been determined and partially refined to R = 0.23 at 2.6 A. The single 414 amino acid polypeptide chain (Mr = 45,000) approximates a triangular prism with a maximum dimension of approximately 60 A and a minimum of approximately 30 A. Twelve helical segments (A through L) account for approximately 40% of the structure while antiparallel beta pairs account for only approximately 10%. The unexposed iron protoporphyrin IX is sandwiched between two parallel helices designated the proximal and distal helices. The heme iron atom is pentacoordinate with the axial sulfur ligand provided by Cys 357 which extends from the N-terminal end of the proximal (L) helix. A substrate molecule, 2-bornanone (camphor), is buried in an internal pocket just above the heme distal surface adjacent to the oxygen binding site. The substrate molecule is held in place by a hydrogen bond between the side chain hydroxyl group of Tyr 96 and the camphor carbonyl oxygen atom in addition to complementary hydrophobic contacts between the camphor molecule and neighboring aliphatic and aromatic residues. The camphor is oriented such that the exo-surface of C5 would contact an iron bound, "activated" oxygen atom for stereoselective hydroxylation.     

Redox-dependent structural changes in the Azotobacter vinelandii bacterioferritin: new insights into the ferroxidase and iron transport mechanism

In this work, we report the X-ray crystal structure of the aerobically isolated (oxidized) and the anaerobic dithionite-reduced (at pH 8.0) forms of the native Azotobacter vinelandii bacterioferritin to 2.7 and 2.0 A resolution, respectively. Iron K-edge multiple anomalous dispersion (MAD) experiments unequivocally identified the presence of three independent iron-containing sites within the protein structure. Specifically, a dinuclear (ferroxidase) site, a b-type heme site, and the binding of a single iron atom at the four-fold molecular axis of the protein shell were observed. In addition to the novel observation of iron at the four-fold pore, these data also reveal that the oxidized form of the protein has a symmetrical ferroxidase site containing two five-coordinate iron atoms. Each iron atom is ligated by four carboxylate oxygen atoms and a single histidyl nitrogen atom. A single water molecule is found within hydrogen bonding distance of the ferroxidase site that bridges the two iron atoms on the side opposite the histidine ligands. Chemical reduction of the protein under anaerobic conditions results in an increase in the average Fe-Fe distance in the ferroxidase site from approximately 3.5 to approximately 4.0 A and the loss of one of the ligands, H130. In addition, there is significant movement of the bridging water molecule and several other amino acid side chains in the vicinity of the ferroxidase site and along the D helix to the three-fold symmetry axis. In contrast to previous work, the higher-resolution data for the dithionite-reduced structure suggest that the heme may be bound in multiple conformations. Taken together, these data allow a molecular movie of the ferroxidase gating mechanism to be developed and provide further insight into the iron uptake and/or release and mineralization mechanism of bacterioferritins in general.     

Pivotal role of water in the mechanism of P450BM-3

Cytochrome P450s constitute a superfamily of enzymes that catalyze the oxidation of a vast number of structurally and chemically diverse hydrophobic substrates. Herein, we describe the crystal structure of a complex between the bacterial P450BM-3 and the novel substrate N-palmitoylglycine at a resolution of 1.65 A, which reveals previously unrecognizable features of active site reorganization upon substrate binding. N-palmitoylglycine binds with higher affinity than any other known substrate and reacts with a higher turnover number than palmitic acid but with unaltered regiospecificity along the fatty acid moiety. Substrate binding induces conformational changes in distinct regions of the enzyme including part of the I-helix adjacent to the active site. These changes cause the displacement by about 1 A of the pivotal water molecule that ligands the heme iron, resulting in the low-spin to high-spin conversion of the iron. The water molecule is trapped close to the heme group, which allows it to partition between the iron and the new binding site. This partitioning explains the existence of a high-spin-low-spin equilibrium after substrate binding. The close proximity of the water molecule to the heme iron indicates that it may also participate in the proton-transfer cascade that leads to heterolytic bond scission of oxygen in P450BM-3.     

The crystal structure and amino acid sequence of dehaloperoxidase from Amphitrite ornata indicate common ancestry with globins

The full-length, protein coding sequence for dehaloperoxidase was obtained using a reverse genetic approach and a cDNA library from marine worm Amphitrite ornata. The crystal structure of the dehaloperoxidase (DHP) was determined by the multiple isomorphous replacement method and was refined at 1.8-A resolution. The enzyme fold is that of the globin family and, together with the amino acid sequence information, indicates that the enzyme evolved from an ancient oxygen carrier. The peroxidase activity of DHP arose mainly through changes in the positions of the proximal and distal histidines relative to those seen in globins. The structure of a complex of DHP with 4-iodophenol is also reported, and it shows that in contrast to larger heme peroxidases DHP binds organic substrates in the distal cavity. The binding is facilitated by the histidine swinging in and out of the cavity. The modeled position of the oxygen atom bound to the heme suggests that the enzymatic reaction proceeds via direct attack of the oxygen atom on the carbon atom bound to the halogen atom.     

Molecular Dynamic Simulations Reveal the Structural Determinants of Fatty Acid Binding to Oxy-Myoglobin

The mechanism(s) by which fatty acids are sequestered and transported in muscle have not been fully elucidated. A potential key player in this process is the protein myoglobin (Mb). Indeed, there is a catalogue of empirical evidence supporting direct interaction of globins with fatty acid metabolites; however, the binding pocket and regulation of the interaction remains to be established. In this study, we employed a computational strategy to elucidate the structural determinants of fatty acids (palmitic & oleic acid) binding to Mb. Sequence analysis and docking simulations with a horse (Equus caballus) structural Mb reference reveals a fatty acid-binding site in the hydrophobic cleft near the heme region in Mb. Both palmitic acid and oleic acid attain a “U” shaped structure similar to their conformation in pockets of other fatty acid-binding proteins. Specifically, we found that the carboxyl head group of palmitic acid coordinates with the amino group of Lys45, whereas the carboxyl group of oleic acid coordinates with both the amino groups of Lys45 and Lys63. The alkyl tails of both fatty acids are supported by surrounding hydrophobic residues Leu29, Leu32, Phe33, Phe43, Phe46, Val67, Val68 and Ile107. In the saturated palmitic acid, the hydrophobic tail moves freely and occasionally penetrates deeper inside the hydrophobic cleft, making additional contacts with Val28, Leu69, Leu72 and Ile111. Our simulations reveal a dynamic and stable binding pocket in which the oxygen molecule and heme group in Mb are required for additional hydrophobic interactions. Taken together, these findings support a mechanism in which Mb acts as a muscle transporter for fatty acid when it is in the oxygenated state and releases fatty acid when Mb converts to deoxygenated state.     

The structure of Paracoccus denitrificans cytochrome c550.

The crystal structure of Paracoccus (formerly Micrococcus) denitrificans cytochrome c550 has been solved by x-ray diffraction to a resolution of 2.45 A. In both amino acid sequence and molecular structure it is evolutionarily homologous with mitochondrial cytochrome c from eukaryotes and photosynthetic cytochrome c2 from purple non-sulfur bacteria. All of these cytochromes c have the same basic folding pattern, with surface insertions of extra amino acids in c550. Various strains of c2 have all, some, or none of the extra insertions observed in c550. The hydrophobic heme environment, position of aromatic rings, and structure and environment of the heme crevice, are virtually identical in cytochromes c55o, c, and c2. Radical changes observed at all regions on the molecular surface except the heme crevice argue for the importance of the crevice and the exposed edge of the heme in the transfer of electrons to and from the cytochrome molecule.     

Resolution of Holliday junction substrates by human topoisomerase I

Prompted by the close relationship between tyrosine recombinases and type IB topoisomerases we have investigated the ability of human topoisomerase I to resolve the typical intermediate of recombinase catalysis, the Holliday junction. We demonstrate that human topoisomerase I catalyzes unidirectional resolution of a synthetic Holliday junction substrate containing two preferred cleavage sites surrounded by DNA sequences supporting branch migration. Deleting part of the N-terminal domain (amino acid residues 1-202) did not affect topoisomerase I resolution activity, whereas a topoisomerase I variant lacking both the N-terminal domain and amino acid residues 660-688 of the linker domain was unable to resolve the Holliday junction substrate. The inability of the double deleted variant to mediate resolution correlated with the inability of this enzyme to introduce concomitant cleavage at the two preferred cleavage sites in a single Holliday junction substrate, which is a prerequisite for resolution. As determined by the gel electrophoretic mobility of native enzyme or enzyme crosslinked by disulfide bridging, the double deleted mutant existed almost entirely in a dimeric form. The impairment of this enzyme in performing double cleavages on the Holliday junction substrate may be explained by only one cleavage competent active site being formed at a time within the dimer. The assembly of only one active site within dimers is a well-known characteristic of the tyrosine recombinases. Hence, the obtained results may suggest a recombinase-like active site assembly of the double deleted topoisomerase I variant. Taken together the presented results consolidate the relationship between type IB topoisomerases and tyrosine recombinases.     

Crystal structure of heme oxygenase-1 from cyanobacterium Synechocystis sp. PCC 6803 in complex with heme.

Heme oxygenase (HO) catalyzes the oxidative degradation of heme utilizing molecular oxygen and reducing equivalents. In photosynthetic organisms, HO functions in the biosynthesis of such open-chain tetrapyrroles as phyto-chromobilin and phycobilins, which are involved in the signal transduction for light responses and light harvesting for photosynthesis, respectively. We have determined the first crystal structure of a HO-1 from a photosynthetic organism, Synechocystis sp. PCC 6803 (Syn HO-1), in complex with heme at 2.5 A resolution. Heme-Syn HO-1 shares a common folding with other heme-HOs. Although the heme pocket of heme-Syn HO-1 is, for the most part, similar to that of mammalian HO-1, they differ in such features as the flexibility of the distal helix and hydrophobicity. In addition, 2-propanol derived from the crystallization solution occupied the hydrophobic cavity, which is proposed to be a CO trapping site in rat HO-1 that suppresses product inhibition. Although Syn HO-1 and mammalian HO-1 are similar in overall structure and amino acid sequence (57% similarity vs. human HO-1), their molecular surfaces differ in charge distribution. The surfaces of the heme binding sides are both positively charged, but this patch of Syn HO-1 is narrow compared to that of mammalian HO-1. This feature is suited to the selective binding of ferredoxin, the physiological redox partner of Syn HO-1; the molecular size of ferredoxin is approximately 10 kDa whereas the size of NADPH-cytochrome P450 reductase, a reducing partner of mammalian HO-1, is approximately 77 kDa. A docking model of heme-Syn HO-1 and ferredoxin suggests indirect electron transfer from an iron-sulfur cluster in ferredoxin to the heme iron of heme-Syn HO-1.     

Secondary structure of the pore-forming colicin A and its C-terminal fragment. Experimental fact and structure prediction

Conformational investigations, using circular dichroism, on the pore-forming protein, colicin A (Mr 60 000), and a C-terminal bromelain fragment (Mr 20 000) were undertaken to estimate their secondary structure and to search for pH-dependent conformational changes. Colicin A and the bromelain peptide are mainly alpha-helical with an enrichment of the alpha-helical content in the C-terminal domain carrying the ionophoric activity. The non-negligible beta-sheet structure in the C-terminal domain is unstable and is easily transformed into alpha-helix upon decreasing the polarity of the solvent. No evidence of pH-dependent conformational modification, correlated with modification of colicin A activity, could be obtained. The secondary structure estimated on the basis of experimental data favoured a model in which the pore is built of a minimal number of six transmembrane alpha-helical segments. Search for such segments in the amino acid sequence of the C-terminal domain of colicin A was carried out by combining secondary structure prediction methods with hydrophobicity and hydrophobic movement calculations. Similar calculations on the C-terminal domains of colicin E1 and IB indicate a common structure of the pores formed by colicin A, E1 and IB. Only two or three putative transmembrane segments could be selected in the sequences of colicin A, IB or E1. As a result, it is concluded that the channel is probably not built by a single colicin molecule but more likely by an oligomer.     

Crystal structures of an oxygen-binding cytochrome c from Rhodobacter sphaeroides

The photosynthetic bacterium Rhodobacter sphaeroides produces a heme protein (SHP), which is an unusual c-type cytochrome capable of transiently binding oxygen during autooxidation. Similar proteins have not only been observed in other photosynthetic bacteria but also in the obligate methylotroph Methylophilus methylotrophus and the metal reducing bacterium Shewanella putrefaciens. A three-dimensional structure of SHP was derived using the multiple isomorphous replacement phasing method. Besides a model for the oxidized state (to 1.82 A resolution), models for the reduced state (2.1 A resolution), the oxidized molecule liganded with cyanide (1. 90 A resolution), and the reduced molecule liganded with nitric oxide (2.20 A resolution) could be derived. The SHP structure represents a new variation of the class I cytochrome c fold. The oxidized state reveals a novel sixth heme ligand, Asn(88), which moves away from the iron upon reduction or when small molecules bind. The distal side of the heme has a striking resemblance to other heme proteins that bind gaseous compounds. In SHP the liberated amide group of Asn(88) stabilizes solvent-shielded ligands through a hydrogen bond.     

Crystal structure of horse carbonmonoxyhemoglobin-bezafibrate complex at 1.55-A resolution. A novel allosteric binding site in R-state hemoglobin

Bezafibrate, an antilipidemic drug, is known as a potent allosteric effector of hemoglobin. The previously proposed mechanism for the allosteric potency of this drug was that it stabilizes and constrains the T-state of hemoglobin by specifically binding to the large central cavity of the T-state. Here we report a new allosteric binding site of fully liganded R-state hemoglobin for this drug. The high resolution crystal structure of horse carbonmonoxyhemoglobin in complex with bezafibrate reveals that the bezafibrate molecule lies near the surface of the E-helix of each alpha subunit and the complex maintains the quaternary structure of the R-state. Binding is caused by the close fit of bezafibrate into the binding pocket, which is composed of some hydrophobic residues and the heme edge, suggesting the importance of hydrophobic interactions. Upon binding of bezafibrate, the distance between Fe and the N epsilon(2) of distal His E7(alpha 58) is shortened by 0.22 A in the alpha subunit, whereas no significant structural changes are transmitted to the beta subunit. Oxygen equilibrium studies of R-state-locked hemoglobin with bezafibrate in a wet porous sol-gel indicate that bezafibrate selectively lowers the oxygen affinity of one type of subunit within the R-state, consistent with the structural data. These results disclose a new allosteric mechanism of bezafibrate and offer the first demonstration of how the allosteric effector interacts with R-state hemoglobin.     

Structure of Cinaciguat (BAY 58–2667) Bound to Nostoc H-NOX Domain Reveals Insights into Heme-mimetic Activation of the Soluble Guanylyl Cyclase

Heme is a vital molecule for all life forms with heme being capable of assisting in catalysis, binding ligands, and undergoing redox changes. Heme-related dysfunction can lead to cardiovascular diseases with the oxidation of the heme of soluble guanylyl cyclase (sGC) critically implicated in some of these cardiovascular diseases. sGC, the main nitric oxide (NO) receptor, stimulates second messenger cGMP production, whereas reactive oxygen species are known to scavenge NO and oxidize/inactivate the heme leading to sGC degradation. This vulnerability of NO-heme signaling to oxidative stress led to the discovery of an NO-independent activator of sGC, cinaciguat (BAY 58–2667), which is a candidate drug in clinical trials to treat acute decompensated heart failure. Here, we present crystallographic and mutagenesis data that reveal the mode of action of BAY 58–2667. The 2.3-Å resolution structure of BAY 58–2667 bound to a heme NO and oxygen binding domain (H-NOX) from Nostoc homologous to that of sGC reveals that the trifurcated BAY 58–2667 molecule has displaced the heme and acts as a heme mimetic. Carboxylate groups of BAY 58–2667 make interactions similar to the heme-propionate groups, whereas its hydrophobic phenyl ring linker folds up within the heme cavity in a planar-like fashion. BAY 58–2667 binding causes a rotation of the αF helix away from the heme pocket, as this helix is normally held in place via the inhibitory His¹⁰⁵–heme covalent bond. The structure provides insights into how BAY 58–2667 binds and activates sGC to rescue heme-NO dysfunction in cardiovascular diseases.     

Binding of salicylhydroxamic acid and several aromatic donor molecules to Arthromyces ramosus peroxidase, investigated by X-ray crystallography, optical difference spectroscopy, NMR relaxation, molecular dynamics, and kinetics.

The X-ray crystal structure of the complex of salicylhydroxamic acid (SHA) with Arthromyces ramosus peroxidase (ARP) has been determined at 1.9 A resolution. The position of SHA in the active site of ARP is similar to that of the complex of benzhydroxamic acid (BHA) with ARP [Itakura, H., et al. (1997) FEBS Lett. 412, 107-110]. The aromatic ring of SHA binds to a hydrophobic region at the opening of the distal pocket, and the hydroxamic acid moiety forms hydrogen bonds with the His56, Arg52, and Pro154 residues but is not asscoiated with the heme iron. X-ray analyses of ARP-resorcinol and ARP-p-cresol complexes failed to identify the aromatic donor molecules, most likely due to the very low affinities of these aromatic donors for ARP. Therefore, we examined the locations of these and other aromatic donors on ARP by the molecular dynamics method and found that the benzene rings are trapped similarly by hydrophobic interactions with the Ala92, Pro156, Leu192, and Phe230 residues at the entrance of the heme pocket, but the dihedral angles between the benzene rings and the heme plane vary from donor to donor. The distances between the heme iron and protons of SHA and resorcinol are similar to those obtained by NMR relaxation. Although SHA and BHA are usually considered potent inhibitors for peroxidase, they were found to reduce compound I and compound II of ARP and horseradish peroxidase C in the same manner as p-cresol and resorcinol. The aforementioned spatial relationships of these aromatic donors to the heme iron in ARP are discussed with respect to the quantum chemical mechanism of electron transfer in peroxidase reactions.     

Nuclear magnetic resonance studies on the spatial relationship of aromatic donor molecules to the heme iron of horseradish peroxidase

The geometry of hydrogen donor molecules bound to horseradish peroxidase was investigated using nuclear magnetic resonance techniques. Between resorcinol and 2-methoxy-4-methylphenol which showed different optical difference spectra, little difference was observed in the orientation of the molecules bound to horseradish peroxidase: the minimal distances between the enzyme iron and the protons of the phenol rings are in the range of 8.4-11.0 A. This situation was not greatly different for the third compound studied in this paper, benzhydroxamic acid, providing evidence against the view that its side chain coordinates to the heme iron. Furthermore, it was found that transferred nuclear Overhauser effect for the signals of these compounds was observable only when the heme peripheral 8-methyl proton signal was irradiated. These results, together with a hypothetical model of the enzyme structure obtained by computer-aided simulation procedures, suggest that the binding of these donor molecules and competitive inhibitors occur in the vicinity of the heme peripheral 8-methyl group, with hydrophobic interactions probably with Tyr-185 and with hydrogen bond with adjacent amino acid residues such as Arg-183.     

Degradation of heme by a soluble peptide of heme oxygenase obtained from rat liver microsomes by mild trypsinization.

A tryptic peptide of heme oxygenase obtained after solubilization of rat liver microsomes by mild trypsin treatment was purified. The purified peptide gave only a single protein band with a molecular mass of 28 kDa on SDS/PAGE. The tryptic peptide, like the native heme oxygenase, readily bound with substrate heme forming a hemeprotein transiently. The absorption spectra of the ferric, ferrous, ferrous-CO and ferrous-O2 forms of the resulting complex resembled those of the corresponding forms of the complex of heme and the native enzyme. Ferric heme bound to the tryptic peptide was quantitatively decomposed to biliverdin on incubation with a mixture of ascorbic acid and desferrioxamine, indicating that the tryptic peptide still retained catalytic activity. These observations suggest that heme oxygenase has two domains, a hydrophilic and a hydrophobic domain, and that the two domains are folded almost independently of each other. An NADPH-cytochrome-P-450 reductase system composed of NADPH and detergent-solubilized NADPH-cytochrome-P-450 reductase readily reduced the ferric heme bound to the tryptic peptide, but failed to transfer the second electron required for rapid heme degradation, suggesting that the hydrophobic domain of heme oxygenase is important for receiving the second electron from the reductase.     

Comparison of beef liver and Penicillium vitale catalases

The structures of Penicillium vitale and beef liver catalase have been determined to atomic resolution. Both catalases are tetrameric proteins with deeply buried heme groups. The amino acid sequence of beef liver catalase is known and contains (at least) 506 amino acid residues. Although the sequence of P. vitale catalase has not yet been determined chemically, 670 residues have been built into the 2 A resolution electron density map and have been given tentative assignments. A large portion of each catalase molecule (91% of residues in beef liver catalase and 68% of residues in P. vitale catalase) shows structural homology. The root-mean-square deviation between 458 equivalenced C alpha atoms is 1.17 A. The dissimilar parts include a small fragment of the N-terminal arm and an additional "flavodoxin-like" domain at the carboxy end of the polypeptide chain of P. vitale catalase. In contrast, beef liver catalase contains one bound NADP molecule per subunit in a position equivalent to the chain region, leading to the flavodoxin-like domain, of P. vitale catalase. The position and orientation of the buried heme group in the two catalases, relative to the mutually perpendicular molecular dyad axes, are identical within experimental error. A mostly hydrophobic channel leads to the buried heme group. The surface opening to the channel differs due to the different disposition of the amino-terminal arm and the presence of the additional flavodoxin-like domain in P. vitale catalase. Possible functional implications of these comparisons are discussed.     

Structure of beef liver catalase

The three-dimensional structure of beef liver catalase has been determined to 2.5 å resolution by a combination of isomorphous and molecular replacement techniques. Heavy-atom positions were found using vector search and difference Fourier methods. The tetrameric catalase molecule has 222 symmetry with one of its dyads coincident with a crystallographic 2-fold axis. The known polypeptide sequence has been unambiguously fitted to the electron density map. The heme is well buried in a hydrophobic pocket, 20 Å below the surface of the molecule, and accessible through a hydrophobic channel. Residues that line the heme pocket belong to two different subunits. Tyr357 is the proximal heme ligand and the catalytically important residues on the distal side are residues His74 and Asnl47. The tertiary structure consists of four domains: an extended non-globular amino-terminal arm, which stabilizes the quaternary structure; an anti-parallel, eight-stranded β-barrel providing the residues on the distal side of the heme; a rather random “wrapping domain” around the subunit exterior including the proximal heme ligand; and a final λ-helical structure resembling the E, F, G and H helices of the globins.     

Truncated hemoglobins and nitric oxide action

Truncated hemoglobins (trHbs) build a separate subfamily within the hemoglobin superfamily; they are scarcely related by sequence similarity to (non-)vertebrate hemoglobins, displaying amino acid sequences in the 115-130 residue range. The trHb tertiary structure is based on a 2-on-2 alpha-helical sandwich, which hosts a unique hydrophobic cavity/tunnel system, traversing the protein matrix, from the molecular surface to the heme distal site. Such a protein matrix system may provide a path for diffusion of ligands to the heme. In Mycobacterium tuberculosis trHbN the heme-bound oxygen molecule is part of an extended hydrogen bond network including the heme distal residues TyrB10 and GlnE11. In vitro experiments have shown that M. tuberculosis trHbN supports efficiently nitric oxide dioxygenation, yielding nitrate. Such a reaction would provide a defense barrier against the nitrosative stress raised by host macrophages during lung infection. It is proposed that the whole protein architecture, the heme distal site hydrogen bonded network, and the unique protein matrix tunnel, are optimally designed to support the pseudo-catalytic role of trHbN in converting the reactive NO species into the harmless NO3-.