Structural properties of 2/2 hemoglobins: the group III protein from Helicobacter hepaticus.

The ε-proteobacterium Helicobacter hepaticus (Hh) contains a gene coding for a hemoglobin (Hb). The protein belongs to the 2/2 Hb lineage and is representative of group III, a set of Hbs about which little is known. An expression and purification procedure was developed for Hh Hb. Electronic absorption and nuclear magnetic resonance (NMR) spectra were used to characterize ligation states of the ferric and ferrous protein. The pK(a) of the acid/alkaline transition of ferric Hh Hb was 7.3, an unusually low value. NMR analysis of the cyanomet complex showed the orientation of the heme group to be reversed when compared with most group I and group II 2/2 Hbs. Ferrous Hh Hb formed a stable cyanide complex that yielded NMR spectra similar to those of the carbonmonoxy complex. All forms of Hh Hb were self-associated at NMR concentrations. Comparison was made to the related Campylobacter jejuni 2/2 Hb (Ctb), and the amino acid conservation pattern of group III was reinspected to help in the generalization of structure-function relationships.

Functional and structural characterization of the 2/2 hemoglobin from Synechococcus sp. PCC 7002.

Cyanobacterium Synechococcus sp. PCC 7002 contains a single gene (glbN) coding for GlbN, a protein of the 2/2 hemoglobin lineage. The precise function of GlbN is not known, but comparison to similar 2/2 hemoglobins suggests that reversible dioxygen binding is not its main activity. In this report, the results of in vitro and in vivo experiments probing the role of GlbN are presented. Transcription profiling indicated that glbN is not strongly regulated under any of a large number of growth conditions and that the gene is probably constitutively expressed. High levels of nitrate, used as the sole source of nitrogen, and exposure to nitric oxide were tolerated better by the wild-type strain than a glbN null mutant, whereas overproduction of GlbN in the null mutant background restored the wild-type growth. The cellular contents of reactive oxygen/nitrogen species were elevated in the null mutant under all conditions and were highest under NO challenge or in the presence of high nitrate concentrations. GlbN overproduction attenuated these contents significantly under the latter conditions. The analysis of cell extracts revealed that the heme of GlbN was covalently bound to overproduced GlbN apoprotein in cells grown under microoxic conditions. A peroxidase assay showed that purified GlbN does not possess significant hydrogen peroxidase activity. It was concluded that GlbN protects cells from reactive nitrogen species that could be encountered naturally during growth on nitrate or under denitrifying conditions. The solution structure of covalently modified GlbN was determined and used to rationalize some of its chemical properties.

Structural divergence and distant relationships in proteins: evolution of the globins.

The globin family has long been known from studies of approximately 150-residue proteins such as vertebrate myoglobins and haemoglobins. Recently, this family has been enriched by the investigation of the sequences and structures of truncated globins, which have the same basic topology but are approximately 30 residues shorter and exhibit functions other than the familiar one of binding diatomic ligands. The divergence of protein sequences, structures and functions reveals Nature's exploration of the potential inherent in a folding pattern, that is, the topology of the native structure. The observation of what remains constant and what varies during the evolution of a protein family reveals essential features of structure and function. Study of proteins with a wide range of divergence can therefore sharpen our understanding of how different amino acid sequences can determine similar three-dimensional structures. Globins have provided, and continue to provide, interesting material for such studies.

Structural and thermodynamic consequences of b heme binding for monomeric apoglobins and other apoproteins.

The binding of a cofactor to a protein matrix often involves a reorganization of the polypeptide structure. b Hemoproteins provide multiple examples of this behavior. In this minireview, selected monomeric and single b heme proteins endowed with distinct topological properties are inspected for the extent of induced refolding upon heme binding. To complement the data reported in the literature, original results are presented on a two-on-two globin of cyanobacterial origin (Synechococcus sp. PCC 7002 GlbN) and on the heme-containing module of FixL, an oxygen-sensing protein with the mixed alpha/beta topology of PAS domains. GlbN had a stable apoprotein that was further stabilized and locally refolded by heme binding; in contrast, apoFixLH presented features of a molten globule. Sequence analyses (helicity, disorder, and polarity) and solvent accessibility calculations were performed to identify trends in the architecture of b hemoproteins. In several cases, the primary structure appeared biased toward a partially disordered binding pocket in the absence of the cofactor.

Structural properties of cyanobacterial hemoglobins: the unusual heme-protein cross-link of Synechocystis sp. PCC 6803 Hb and Synechococcus sp. PCC 7002 Hb.

The truncated hemoglobins from Synechocystis sp. PCC 6803 and Synechococcus sp. PCC 7002 ligate the heme iron with two axial histidines (HisF8 and HisE10). In addition, these two proteins are able to form a heme-protein cross-link between a vinyl substituent and a histidine at position 16 of the H helix. The product is a protein with improved resistance to thermal and acid denaturation.

(1)H, (15)N, and (13)C resonance assignments of the 2/2 hemoglobin from the cyanobacterium Synechococcus sp. PCC 7002 in the ferric bis-histidine state.

The hemoglobin from the cyanobacterium Synechococcus sp. PCC 7002 is a monomeric 123-residue Group I 2/2 hemoglobin. Here, we report (1)H, (15)N, and (13)C assignments for the ferric (low-spin, S = (1/2)) protein with a b heme cofactor and after post-translational modification leading to a c-like heme.

A phylogenetic and structural analysis of truncated hemoglobins.

Truncated hemoglobins (trHbs) are heme proteins found in bacteria, plants, and unicellular eukaryotes. They are distantly related to vertebrate hemoglobins and are typically shorter than these by 20-40 residues. The multiple amino acid deletions, insertions, and replacements result in distinctive alterations of the canonical globin fold and a wide range of chemical properties. An early phylogenetic analysis categorized trHbs into three groups, I (trHbN), II (trHbO), and III (trHbP). Here, we revisit this analysis with 111 trHbs. We find that trHbs are orthologous within each group and paralogous across the groups. Group I globins form the most disparate set and separate into two divergent subgroups. Group II is comparatively homogeneous, whereas Group III displays the highest level of overall conservation. In Group I and Group II globins, for which some ligand binding and structural data are available, an improved description of probable protein-ligand interactions is achieved. Other conservation trends are either confirmed (essential glycines in loops), refined (lining of ligand access tunnel), or newly identified (helix start signal). The Group III globins, so far uncharacterized, exhibit recognizable heme cavity residues while lacking some of the residues thought to be important to the trHb fold. An analysis of the phylogenetic trees of each group provides a plausible scenario for the emergence of trHbs, by which the Group II trHb gene was the original gene, and the Group I trHb and Group III trHb genes were obtained via duplication and transfer events.

Structural and dynamic repercussions of heme binding and heme-protein cross-linking in Synechococcus sp. PCC 7002 hemoglobin.

The recombinant two-on-two hemoglobin from the cyanobacterium Synechoccocus sp. PCC 7002 (S7002 rHb) is a bishistidine hexacoordinate globin capable of forming a covalent cross-link between a heme vinyl and a histidine in the C-terminal helix (H helix). Of the two heme axial histidines, His46 (in the E helix, distal side) and His70 (in the F helix, proximal histidine), His46 is displaced by exogenous ligands. S7002 rHb can be readily prepared as an apoglobin (apo-rHb), a non-cross-linked hemichrome (ferric iron and histidine axial ligands, rHb-R), and a cross-linked hemichrome (rHb-A). To determine the effects of heme binding and subsequent cross-linking, apo-rHb, rHb-R, and rHb-A were subjected to thermal denaturation and 1H/2H exchange. Interpretation of the latter data was based on nuclear magnetic resonance assignments obtained with uniformly 15N- and 13C,15N-labeled proteins. Apo-rHb was found to contain a cooperative structural core, which was extended and stabilized by heme binding. Cross-linking resulted in further stabilization attributed mainly to an unfolded-state effect. Protection factors were higher at the cross-link site and near His70 in rHb-A than in rHb-R. In contrast, other regions became less resistant to exchange in rHb-A. These included portions of the B and E helices, which undergo large conformational changes upon exogenous ligand binding. Thus, the cross-link readjusted the dynamic properties of the heme pocket. 1H/2H exchange data also revealed that the B, G, and H helices formed a robust core regardless of the presence of the heme or cross-link. This motif likely encompasses the early folding nucleus of two-on-two globins.

Proximal influences in two-on-two globins: effect of the Ala69Ser replacement on Synechocystis sp. PCC 6803 hemoglobin.

The cyanobacterium Synechocystis sp. PCC 6803 (S6803) expresses a two-on-two globin in which His46 (distal side) and His70 (proximal) function as heme iron axial ligands. His46 can be displaced by O2, CO, and CN-, among others, whereas His70 is not labile under native conditions. The residue preceding the proximal histidine has been implicated in controlling globin axial ligand reactivity; the details of the mechanism, however, are not well understood, and little information exists for bis-histidyl hexacoordinate proteins. In many vertebrate hemoglobins and in the Synechocystis protein, the position is occupied by an alanine, whereas, in myoglobins, it is a serine involved in an intricate hydrogen-bond network. We examined the role of Ala69 in S6803 hemoglobin through the effects of an Ala --> Ser replacement. The substitution resulted in minor structural perturbations, but the response of the holoprotein to temperature-, urea-, and acid-induced denaturation was measurably affected. Enhanced three-state behavior was manifested in the decoupling of heme binding and secondary-structure formation. Urea-gradient gel experiments revealed that the stability of the apoprotein was unchanged by the replacement and that a slight alteration of the folding kinetics occurred in the holoproteins. Cyanide-binding experiments were performed to assess trans effects. The apparent rate constant for association decreased 2-fold upon Ala69Ser replacement. This deceleration was attributed to a change in the lifetime of a state containing a decoordinated His46. The results demonstrated that, as in vertebrate globins and leghemoglobin, proximal influences operate to determine fundamental dynamic and thermodynamic properties of the protein.

Cyanide binding to hexacoordinate cyanobacterial hemoglobins: hydrogen-bonding network and heme pocket rearrangement in ferric H117A Synechocystis hemoglobin.

The truncated hemoglobin (Hb) from the cyanobacterium Synechocystis sp. PCC 6803 is a bis-histidyl hexacoordinate complex in the absence of exogenous ligands. This protein can form a covalent cross-link between His117 in the H-helix and the heme 2-vinyl group. Cross-linking, the physiological importance of which has not been established, is avoided with the His117Ala substitution. In the present work, H117A Hb was used to explore exogenous ligand binding to the heme group. NMR and thermal denaturation data showed that the replacement was of little consequence to the structural and thermodynamic properties of ferric Synechocystis Hb. It did, however, decelerate the association of cyanide ions with the heme iron. Full complexation required hours, instead of minutes, of incubation at optical and NMR concentrations. At neutral pH and in the presence of excess cyanide, binding occurred with a first-order dependence on cyanide concentration, eliminating distal histidine decoordination as the rate-limiting step. The cyanide complex of the H117A variant was characterized for the conformational changes occurring as the histidine on the distal side, His46 (E10), was displaced. Extensive rearrangement allowed Tyr22 (B10) to insert in the heme pocket and Gln43 (E7) and Gln47 (E11) to come in contact with it. H-bond formation to the bound cyanide was identified in solution with the use of (1)H(2)O/(2)H(2)O mixtures. Cyanide binding also resulted in a change in the ratio of heme orientational isomers, in a likely manifestation of heme environment reshaping. Similar observations were made with the related Synechococcus sp. PCC 7002 H117A Hb, except that cyanide binding was rapid in this protein. In both cases, the (15)N chemical shift of bound cyanide was reminiscent of that in peroxidases and the orientation of the proximal histidine was as in other truncated Hbs. The ensemble of the data provided insight into the structural cooperativity of the heme pocket scaffold and pointed to the reactive 117 site of Synechocystis Hb as a potential determinant of biophysical and, perhaps, functional properties.

Truncated hemoglobin from the cyanobacterium Synechococcus sp. PCC 7002: evidence for hexacoordination and covalent adduct formation in the ferric recombinant protein.

The glbN gene for the hemoglobin of Synechoccocus sp. PCC 7002, a cyanobacterium incapable of nitrogen fixation, was cloned and overexpressed in Escherichia coli. The 123-residue protein was purified from inclusion bodies and reconstituted with iron protoporphyrin IX to obtain the ferric form of the holoprotein. Mass spectrometric analysis confirmed the identity of the polypeptide. NMR and optical data demonstrated that the protein so prepared contained a hexacoordinate heme group, as observed in the related globin from Synechocystis sp. PCC 6803 [Scott, N. L., and Lecomte, J. T. J. (2000) Protein Sci. 9, 587-597]. The data were consistent with a similar bis-histidine coordination scheme involving His46 (E10) on the distal side and His70 (F8) on the proximal side. Several aromatic residues were identified in the vicinity of the heme and were used to establish the orientation of the prosthetic group in the polypeptide matrix. In this protein, as in that from Synechocystis sp. PCC 6803, there was a marked preference for the heme orientation in which pyrroles C and D contact the C-E corner of the protein. Both hemoglobins were found capable of forming a product in which the heme is cross-linked to the polypeptide through modification of a vinyl group.

Characterization of the heme-histidine cross-link in cyanobacterial hemoglobins from Synechocystis sp. PCC 6803 and Synechococcus sp. PCC 7002.

The recombinant product of the hemoglobin gene of the cyanobacterium Synechocystis sp. PCC 6803 forms spontaneously a covalent bond linking one of the heme vinyl groups to a histidine located in the C-terminal helix (His117, or H16). The present report describes the (1)H, (15)N, and (13)C NMR spectroscopy experiments demonstrating that the recombinant hemoglobin from the cyanobacterium Synechococcus sp. PCC 7002, a protein sharing 59% identity with Synechocystis hemoglobin, undergoes the same facile heme adduct formation. The observation that the extraordinary linkage is not unique to Synechocystis hemoglobin suggests that it constitutes a noteworthy feature of hemoglobin in non-N(2)-fixing cyanobacteria, along with the previously documented bis-histidine coordination of the heme iron. A qualitative analysis of the hyperfine chemical shifts of the ferric proteins indicated that the cross-link had modest repercussions on axial histidine ligation and heme electronic structure. In Synechocystis hemoglobin, the unreacted His117 imidazole had a normal p K(a) whereas the protonation of the modified residue took place at lower pH. Optical experiments revealed that the cross-link stabilized the protein with respect to thermal and acid denaturation. Replacement of His117 with an alanine yielded a species inert to adduct formation, but inspection of the heme chemical shifts and ligand binding properties of the variant identified position 117 as important in seating the cofactor in its site and modifying the dynamic properties of the protein. A role for bis-histidine coordination and covalent adduct formation in heme retention is proposed.