Structural determinants in the group III truncated hemoglobin from Campylobacter jejuni

Truncated hemoglobins (trHbs) constitute a distinct lineage in the globin superfamily, distantly related in size and fold to myoglobin and monomeric hemoglobins. Their phylogenetic analyses revealed that three groups (I, II, and III) compose the trHb family. Group I and II trHbs adopt a simplified globin fold, essentially composed of a 2-on-2 alpha-helical sandwich, wrapped around the heme group. So far no structural data have been reported for group III trHbs. Here we report the three-dimensional structure of the group III trHbP from the eubacterium Campylobacter jejuni. The 2.15-A resolution crystal structure of C. jejuni trHbP (cyano-met form) shows that the 2-on-2 trHb fold is substantially conserved in the trHb group III, despite the absence of the Gly-based sequence motifs that were considered necessary for the attainment of the trHb specific fold. The heme crevice presents important structural modifications in the C-E region and in the FG helical hinge, with novel surface clefts at the proximal heme site. Contrary to what has been observed for group I and II trHbs, no protein matrix tunnel/cavity system is evident in C. jejuni trHbP. A gating movement of His(E7) side chain (found in two alternate conformations in the crystal structure) may be instrumental for ligand entry to the heme distal site. Sequence conservation allows extrapolating part of the structural results here reported to the whole trHb group III.     

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-.     

Ligand migration in the truncated hemoglobin of Mycobacterium tuberculosis

The truncated hemoglobin of Mycobacterium tuberculosis (Mt-trHbO) is a small heme protein belonging to the hemoglobin superfamily. Truncated hemoglobins (trHbs) are believed to have functional roles such as terminal oxidases and oxygen sensors involved in the response to oxidative and nitrosative stress, nitric oxide (NO) detoxification, O?/NO chemistry, O? delivery under hypoxic conditions, and long-term ligand storage. Based on sequence similarities, they are classified into three groups. Experimental studies revealed that all trHbs display a 2-on-2 α-helical sandwich fold rather than the 3-on-3 α-helical sandwich fold of the classical hemoglobin fold. Using locally enhanced sampling (LESMD) molecular dynamics, the ligand-binding escape pathways from the distal heme binding cavity of Mt-trHbO were determined to better understand how this protein functions. The importance of specific residues, such as the group II and III invariant W(G8) residue, can be seen in terms of ligand diffusion pathways and ligand dynamics. LESMD simulations show that the wild-type Mt-trHbO has three diffusion pathways while the W(G8)F Mt-trHbO mutant has only two. The W(G8) residue plays a critical role in ligand binding and stabilization and helps regulate the rate of ligand escape from the distal heme pocket. Thus, this invariant residue is important in creating ligand diffusion pathways and possibly in the enzymatic functions of this protein.     

Heme-ligand tunneling in group I truncated hemoglobins

Truncated hemoglobins (trHbs) are small hemoproteins forming a separate cluster within the hemoglobin superfamily; their functional roles in bacteria, plants, and unicellular eukaryotes are marginally understood. Crystallographic investigations have shown that the trHb fold (a two-on-two alpha-helical sandwich related to the globin fold) hosts a protein matrix tunnel system offering a potential path for ligand diffusion to the heme distal site. The tunnel topology is conserved in group I trHbs, although with modulation of its size/structure. Here, we present a crystallographic investigation on trHbs from Mycobacterium tuberculosis, Chlamydomonas eugametos, and Paramecium caudatum, showing that treatment of trHb crystals under xenon pressure leads to binding of xenon atoms at specific (conserved) sites along the protein matrix tunnel. The crystallographic results are in keeping with data from molecular dynamics simulations, where a dioxygen molecule is left free to diffuse within the protein matrix. Modulation of xenon binding over four main sites is related to the structural properties of the tunnel system in the three trHbs and may be connected to their functional roles. In a parallel crystallographic investigation on M. tuberculosis trHbN, we show that butyl isocyanide also binds within the apolar tunnel, in excellent agreement with concepts derived from the xenon binding experiments. These results, together with recent data on atypical CO rebinding kinetics to group I trHbs, underline the potential role of the tunnel system in supporting diffusion, but also accumulation in multiple copies, of low polarity ligands/molecules within group I trHbs.     

Protein structure in the truncated (2/2) hemoglobin family

The discovery of protein sequences belonging to the widespread 'truncated hemoglobin' family has been followed in the last few years by extensive analyses of their three-dimensional structures. Truncated hemoglobins can be classified in three main groups, in light of their overall structural properties. The three groups adopt a 2-on-2 alpha-helical sandwich fold, based on four main alpha-helices of the classical 3-on-3 alpha-helical sandwich found in vertebrate and invertebrate globins. Each of the three groups displays sequence and structure specific features. Among these, a protein matrix tunnel system is typical of group I, a Trp residue at the G8 topological site is conserved in groups II and III, and residue TyrB10 is almost invariant in the three groups. Despite sequence variability in the heme distal site region, a strongly intertwined, but varied, network of hydrogen bonds stabilizes the heme ligand in the three protein groups. Fine mechanisms of ligand recognition and stabilization may vary based on group-specific distal site residues and on differing ligand diffusion pathways to the heme. Taken together, the structural considerations here presented underline that 'truncated hemoglobins' result from careful editing of the 3-on-3 alpha-helical globin sandwich fold, rather than from simple 'truncation' events. Thus, '2/2Hb' appears the most proper term to concisely address this protein family.     

Protein fold and structure in the truncated (2/2) globin family

Analysis of amino acids sequences and protein folds has recently unraveled the structural bases and details of several proteins from the recently discovered "truncated hemoglobin" family. The analysis here presented, in agreement with previous surveys, shows that truncated hemoglobins can be classified in three main groups, based on their structural properties. Crystallographic analyses have shown that all three groups adopt a 2-on-2 alpha-helical sandwich fold, resulting from apparent editing of the classical 3-on-3 alpha-helical sandwich of vertebrate and invertebrate conventional globins. Specific structural features distinguish each of the three groups. Among these, a protein matrix tunnel system is typical of group I, a Trp residue at the G8 topological site is conserved in groups II and III, and TyrB10 is almost invariant through the three groups. A strongly intertwined network of hydrogen bonds stabilizes the heme bound ligand, despite variability of the heme distal residues observed in the different proteins considered. Details of ligand recognition in the three groups are discussed at the light of residue conservation and of differing ligand diffusion pathways to the heme. Based on structural analyses of the family-specific fold, we endorse a recent proposal of leaving the "truncated hemoglobins" term, that does not represent properly the observed 2-on-2 alpha-helical sandwich fold, and adopting the simple "2/2Hb" term to concisely address this protein family.     

Truncated hemoglobins: trimming the classical ‘three-over-three’ globin fold to a minimal size

Truncated hemoglobins (trHbs) host the heme in a “two-over-two’ α-helical sandwich which results from extensive editing of the classical ‘three-over-three’ globin fold. The three-dimensional structure of trHbs is based on four main α-helices, arranged in a sort of α-helical bundle composed of two antiparallel helix pairs (B/E and G/H). Most notably, trHbs deviate from the conventional globin fold in that they display an extended loop substituting for the heme proximal F-helix observed in globins. Moreover, since efficient adaptation of a 110–130 amino acid trHb chain to host the porphyrin ring firstly requires specific chain flexibility, trHbs contain three invariant Gly-based motifs. Inspection of the trHb three-dimensional trHb structures shows that an apparent protein cavity or tunnel would connect the protein surface to an inner region very close to the heme distal site. Such a structural feature, never observed before in (non) vertebrate globins, may have substantial implications for ligand diffusion and binding properties in trHbs.     

Modulation of oxygen binding to insect hemoglobins: the structure of hemoglobin from the botfly Gasterophilus intestinalis

Hemoglobins (Hbs) reversibly bind gaseous diatomic ligands (e.g., O2) as the sixth heme axial ligand of the penta-coordinate deoxygenated form. Selected members of the Hb superfamily, however, display a functionally relevant hexa-coordinate heme Fe atom in their deoxygenated state. Endogenous heme hexa-coordination is generally provided in these Hbs by the E7 residue (often His), which thus modulates accessibility to the heme distal pocket and reactivity of the heme toward exogenous ligands. Such a pivotal role of the E7 residue is prominently shown by analysis of the functional and structural properties of insect Hbs. Here, we report the 2.6 A crystal structure of oxygenated Gasterophilus intestinalis Hb1, a Hb known to display a penta-coordinate heme in the deoxygenated form. The structure is analyzed in comparison with those of Drosophila melanogaster Hb, exhibiting a hexa-coordinate heme in its deoxygenated derivative, and of Chironomus thummi thummi HbIII, which displays a penta-coordinate heme in the deoxygenated form. Despite evident structural differences in the heme distal pockets, the distinct molecular mechanisms regulating O2 binding to the three insect Hbs result in similar O(2 affinities (P50 values ranging between 0.12 torr and 0.46 torr).     

Nitrosylation Mechanisms of Mycobacterium tuberculosis and Campylobacter jejuni Truncated Hemoglobins N,O, and P

Truncated hemoglobins (trHbs) are widely distributed in bacteria and plants and have been found in some unicellular eukaryotes. Phylogenetic analysis based on protein sequences shows that trHbs branch into three groups, designated N (or I), O (or II), and P (or III). Most trHbs are involved in the O₂/NO chemistry and/or oxidation/reduction function, permitting the survival of the microorganism in the host. Here, a detailed comparative analysis of kinetics and/or thermodynamics of (i) ferrous Mycobacterium tubertulosis trHbs N and O (Mt-trHbN and Mt-trHbO, respectively), and Campylobacter jejuni trHb (Cj-trHbP) nitrosylation, (ii) nitrite-mediated nitrosylation of ferrous Mt-trHbN, Mt-trHbO, and Cj-trHbP, and (iii) NO-based reductive nitrosylation of ferric Mt-trHbN, Mt-trHbO, and Cj-trHbP is reported. Ferrous and ferric Mt-trHbN and Cj-trHbP display a very high reactivity towards NO; however, the conversion of nitrite to NO is facilitated primarily by ferrous Mt-trHbN. Values of kinetic and/or thermodynamic parameters reflect specific trHb structural features, such as the ligand diffusion pathways to/from the heme, the heme distal pocket structure and polarity, and the ligand stabilization mechanisms. In particular, the high reactivity of Mt-trHbN and Cj-trHbP reflects the great ligand accessibility to the heme center by two protein matrix tunnels and the E7-path, respectively, and the penta-coordination of the heme-Fe atom. In contrast, the heme-Fe atom of Mt-trHbO the ligand accessibility to the heme center of Mt-trHbO needs large conformational readjustments, thus limiting the heme-based reactivity. These results agree with different roles of Mt-trHbN, Mt-trHbO, and Cj-trHbP in vivo.     

Structure-function relationships in the growing hexa-coordinate hemoglobin sub-family

Hemoglobin and related heme proteins, generally referred to as 'globins', reversibly bind gaseous diatomic ligands (O2, NO, and CO) to a penta-coordinate heme iron atom, the ligand filling the sixth coordination site. Over the last decade, several new globins have been reported to display a functionally-relevant hexa-coordinate heme iron atom, whose sixth coordination site is taken by an endogenous protein ligand. The reversible intramolecular hexa- to penta-coordination process at the heme-Fe atom modulates exogenous ligand binding properties of hexa-coordinate globins. Here, we review current knowledge on hexa-coordinate globins in terms of their structural and functional properties.     

Unraveling the molecular basis for ligand binding in truncated hemoglobins: The trHbO Bacillus subtilis case

Truncated hemoglobins (trHbs) are heme proteins present in bacteria, unicellular eukaryotes, and higher plants. Their tertiary structure consists in a 2‐over‐2 helical sandwich, which display typically an inner tunnel/cavity system for ligand migration and/or storage. The microorganism Bacillus subtilis contains a peculiar trHb, which does not show an evident tunnel/cavity system connecting the protein active site with the solvent, and exhibits anyway a very high oxygen association rate. Moreover, resonant Raman results of CO bound protein, showed that a complex hydrogen bond network exists in the distal cavity, making it difficult to assign unambiguously the residues involved in the stabilization of the bound ligand. To understand these experimental results with atomistic detail, we performed classical molecular dynamics simulations of the oxy, carboxy, and deoxy proteins. The free energy profiles for ligand migration suggest that there is a key residue, GlnE11, that presents an alternate conformation, in which a wide ligand migration tunnel is formed, consistently with the kinetic data. This tunnel is topologically related to the one found in group I trHbs. On the other hand, the results for the CO and O₂ bound protein show that GlnE11 is directly involved in the stabilization of the cordinated ligand, playing a similar role as TyrB10 and TrpG8 in other trHbs. Our results not only reconcile the structural data with the kinetic information, but also provide additional insight into the general behaviour of trHbs. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

Cyanide binding to truncated hemoglobins: a crystallographic and kinetic study

Cyanide is one of the few diatomic ligands able to interact with the ferric and ferrous heme-Fe atom. Here, the X-ray crystal structure of the cyanide derivative of ferric Mycobacterium tuberculosis truncated hemoglobin-N (M. tuberculosis trHbN) has been determined at 2.0 A (R-general = 17.8% and R-free = 23.5%), and analyzed in parallel with those of M. tuberculosis truncated hemoglobin-O (M. tuberculosis trHbO), Chlamydomonas eugametos truncated hemoglobin (C. eugametos trHb), and sperm whale myoglobin, generally taken as a molecular model. Cyanide binding to M. tuberculosis trHbN is stabilized directly by residue TyrB10(33), which may assist the deprotonation of the incoming ligand and the protonation of the outcoming cyanide. In M. tuberculosis trHbO and in C. eugametos trHb the ligand is stabilized by the distal pocket residues TyrCD1(36) and TrpG8(88), and by the TyrB10(20) - GlnE7(41) - GlnE11(45) triad, respectively. Moreover, kinetics for cyanide binding to ferric M. tuberculosis trHbN and trHbO and C. eugametos trHb, for ligand dissociation from the ferrous trHbs, and for the reduction of the heme-Fe(III)-cyanide complex have been determined, at pH 7.0 and 20.0 degrees C. Despite the different heme distal site structures and ligand interactions, values of the rate constant for cyanide binding to ferric (non)vertebrate heme proteins are similar, being influenced mainly by the presence in the heme pocket of proton acceptor group(s), whose function is to assist the deprotonation of the incoming ligand (i.e., HCN). On the other hand, values of the rate constant for the reduction of the heme-Fe(III)-cyanide (non)vertebrate globins span over several orders of magnitude, reflecting the different ability of the heme proteins considered to give productive complex(es) with dithionite or its reducing species SO(2)(-). Furthermore, values of the rate constant for ligand dissociation from heme-Fe(II)-cyanide (non)vertebrate heme proteins are very different, reflecting the different nature and geometry of the heme distal residue(s) hydrogen-bonded to the heme-bound cyanide.     

Kinetic modulation in carbonmonoxy derivatives of truncated hemoglobins: the role of distal heme pocket residues and extended apolar tunnel

Truncated hemoglobins (trHbs), are a distinct and newly characterized class of small myoglobin-like proteins that are widely distributed in bacteria, unicellular eukaryotes, and higher plants. Notable and distinctive features associated with trHbs include a hydrogen-bonding network within the distal heme pocket and a long apolar tunnel linking the external solvent to the distal heme pocket. The present work compares the geminate and solvent phase rebinding kinetics from two trHbs, one from the ciliated protozoan Paramecium caudatum (P-trHb) and the other from the green alga Chlamydomonas eugametos (C-trHb). Unusual kinetic patterns are observed including indications of ultrafast (picosecond) geminate rebinding of CO to C-trHb, very fast solvent phase rebinding of CO for both trHbs, time-dependent biphasic CO rebinding kinetics for P-trHb at low CO partial pressures, and for P-trHb, an increase in the geminate yield from a few percent to nearly 100% under high viscosity conditions. Species-specific differences in both the 8-ns photodissociation quantum yield and the rebinding kinetics, point to a pivotal functional role for the E11 residue. The response of the rebinding kinetics to temperature, ligand concentration, and viscosity (glycerol, trehalose) and the viscosity-dependent changes in the resonance Raman spectrum of the liganded photoproduct, together implicate both the apolar tunnel and the static and dynamic properties of the hydrogen-bonding network within the distal heme pocket in generating the unusual kinetic patterns observed for these trHbs.     

A novel two-over-two alpha-helical sandwich fold is characteristic of the truncated hemoglobin family

Small hemoproteins displaying amino acid sequences 20-40 residues shorter than (non-)vertebrate hemoglobins (Hbs) have recently been identified in several pathogenic and non-pathogenic unicellular organisms, and named 'truncated hemoglobins' (trHbs). They have been proposed to be involved not only in oxygen transport but also in other biological functions, such as protection against reactive nitrogen species, photosynthesis or to act as terminal oxidases. Crystal structures of trHbs from the ciliated protozoan Paramecium caudatum and the green unicellular alga Chlamydomonas eugametos show that the tertiary structure of both proteins is based on a 'two-over-two' alpha-helical sandwich, reflecting an unprecedented editing of the classical 'three-over-three' alpha-helical globin fold. Based on specific Gly-Gly motifs the tertiary structure accommodates the deletion of the N-terminal A-helix and replacement of the crucial heme-binding F-helix with an extended polypeptide loop. Additionally, concerted structural modifications allow burying of the heme group and define the distal site, which hosts a TyrB10, GlnE7 residue pair. A set of structural and amino acid sequence consensus rules for stabilizing the fold and the bound heme in the trHbs homology subfamily is deduced.     

Interactions of cytochrome P450s with their ligands

Cytochrome P450s (CYPs) are heme-containing monooxygenases that contribute to an enormous range of enzymatic function including biosynthetic and detoxification roles. This review summarizes recent studies concerning interactions of CYPs with ligands including substrates, inhibitors, and diatomic heme-ligating molecules. These studies highlight the complexity in the relationship between the heme spin state and active site occupancy, the roles of water in directing protein–ligand and ligand–heme interactions, and the details of interactions between heme and gaseous diatomic CYP ligands. Both kinetic and thermodynamic aspects of ligand binding are considered.     

Structural studies of constitutive nitric oxide synthases with diatomic ligands bound

Crystal structures are reported for the endothelial nitric oxide synthase (eNOS)–arginine–CO ternary complex as well as the neuronal nitric oxide synthase (nNOS) heme domain complexed with l-arginine and diatomic ligands, CO or NO, in the presence of the native cofactor, tetrahydrobiopterin, or its oxidized analogs, dihydrobiopterin and 4-aminobiopterin. The nature of the biopterin has no influence on the diatomic ligand binding. The binding geometries of diatomic ligands to nitric oxide synthase (NOS) follow the {MXY} ⁿ formalism developed from the inorganic diatomic–metal complexes. The structures reveal some subtle structural differences between eNOS and nNOS when CO is bound to the heme which correlate well with the differences in CO stretching frequencies observed by resonance Raman techniques. The detailed hydrogen-bonding geometries depicted in the active site of nNOS structures indicate that it is the ordered active-site water molecule rather than the substrate itself that would most likely serve as a direct proton donor to the diatomic ligands (CO, NO, as well as O₂) bound to the heme. This has important implications for the oxygen activation mechanism critical to NOS catalysis.     

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.     

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.     

Reversible hexa- to penta-coordination of the heme Fe atom modulates ligand binding properties of neuroglobin and cytoglobin

Neuroglobin (Ngb) and cytoglobin (Cygb) are two recently discovered intracellular members of the vertebrate hemoglobin (Hb) family. Ngb, predominantly expressed in nerve cells, is of ancient evolutionary origin and is homologous to nerve-globins of invertebrates. Cygb, present in many different tissues, shares common ancestry with myoglobin (Mb) and can be traced to early vertebrate evolution. Ngb is held to facilitate O2 diffusion to the mitochondria and to protect neuronal cells from hypoxic-ischemic insults, may be an oxidative stress-responsive sensor protein for signal transduction, and may carry out enzymatic activities, such as NO/O2 scavenging. Cygb is linked to collagen synthesis, may provide O2 for enzymatic reactions, and may be involved in a ROS(NO)-signaling pathway(s). Ngb and Cgb display the classical three-over-three alpha-helical fold of Hb and Mb, and are endowed with a hexa-coordinate heme-Fe atom, in their ferrous and ferric forms, having the heme distal HisE7 residue as the endogenous ligand. Reversible hexa- to penta-coordination of the heme Fe atom modulates ligand binding properties of Ngb and Cygb. Moreover, Ngb and Cygb display a tunnel/cavity system within the protein matrix held to facilitate ligand channeling to/from the heme, multiple ligand copies storage, multi-ligand reactions, and conformational transitions supporting ligand binding.