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.

(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.

Chemical rescue of a site-modified ligand to a [4Fe-4S] cluster in PsaC, a bacterial-like dicluster ferredoxin bound to Photosystem I.

Chemical rescue of site-modified amino acids using externally supplied organic molecules represents a powerful method to investigate structure-function relationships in proteins. Here we provide definitive evidence that aryl and alkyl thiolates, reagents typically used for in vitro iron-sulfur cluster reconstitutions, serve as rescue ligands to a site-specifically modified [4Fe-4S](1+,2+) cluster in PsaC, a bacterial dicluster ferredoxin-like subunit of Photosystem I. PsaC binds two low-potential [4Fe-4S](1+,2+) clusters termed F(A) and F(B). In the C13G/C33S variant of PsaC, glycine has replaced cysteine at position 13 creating a protein that is missing one of the ligating amino acids to iron-sulfur cluster F(B). Using a variety of analytical techniques, including non-heme iron and acid-labile sulfur assays, and EPR, resonance Raman, and Mössbauer spectroscopies, we showed that the C13G/C33S variant of PsaC binds two [4Fe-4S](1+,2+) clusters, despite the absence of one of the biological ligands. (19)F NMR spectroscopy indicated that the external thiolate replaces cysteine 13 as a substitute ligand to the F(B) cluster. The finding that site-modified [4Fe-4S](1+,2+) clusters can be chemically rescued with external thiolates opens new opportunities for modulating their properties in proteins. In particular, it provides a mechanism to attach an additional electron transfer cofactor to the protein via a bound, external ligand.

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.

Structural and dynamic properties of Synechocystis sp. PCC 6803 Hb revealed by reconstitution with Zn-protoporphyrin IX.

In its resting state, the truncated globin of the cyanobacterium Synechocystis sp. PCC 6803 exhibits hexacoordination of the heme iron, with His46 (E10) and His70 (F8, proximal) serving as axial ligands. Diatomic ligands displace the distal His46 (E10) from the ferric and ferrous iron and promote considerable structural changes in the B helix, E helix, and EF regions. Here, Zn(II)-substituted hemoglobin was used to explore the role of distal ligands in stabilizing the heme pocket structure. NMR data showed that the Zn ion was coordinated by the four pyrrole nitrogens and by His70 (F8) only. The proximal side of the Zn-porphyrin adopted a geometry recognizable as that of the wild-type protein. Decoordination of His46 (E10) to form the pentacoordinate Zn resulted in an incomplete transition to the conformation observed in the ferric, cyanide-bound protein. The NMR data also demonstrated that the H helix underwent complex dynamic processes near His117, a residue readily reacting with the wild-type heme 2-vinyl group in a post-translational modification.

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.

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.

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.

Partial NMR assignments and secondary structure mapping of the isolated alpha subunit of Escherichia coli tryptophan synthase, a 29-kD TIM barrel protein.

The alpha subunit of tryptophan synthase (alphaTS) from S. typhimurium belongs to the triosephosphate isomerase (TIM) or the (beta/alpha)(8) barrel fold, one of the most common structures in biology. To test the conservation of the global fold in the isolated Escherichia coli homolog, we have obtained a majority of the backbone assignments for the 29-kD alphaTS by using standard heteronuclear multidimensional NMR methods on uniformly (15)N- and (15)N/(13)C-labeled protein and on protein selectively (15)N-labeled at key hydrophobic residues. The secondary structure mapped by chemical shift index, nuclear Overhauser enhancements (NOEs), and hydrogen-deuterium (H-D) exchange, and several abnormal chemical shifts are consistent with the conservation of the global TIM barrel fold of the isolated E. coli alphaTS. Because most of the amide protons that are slow to exchange with solvent correspond to the beta-sheet residues, the beta-barrel is likely to play an important role in stabilizing the previously detected folding intermediates for E. coli alphaTS. A similar combination of uniform and selective labeling can be extended to other TIM barrel proteins to obtain insight into the role of the motif in stabilizing what appear to be common partially folded forms.

The solution structure of the recombinant hemoglobin from the cyanobacterium Synechocystis sp. PCC 6803 in its hemichrome state.

The product of the cyanobacterium Synechocystis sp. PCC 6803 gene slr2097 is a 123 amino acid polypeptide chain belonging to the truncated hemoglobin family. Recombinant, ferric heme-reconstituted Synechocystis sp. PCC 6803 hemoglobin displays bis-histidine coordination of the iron ion. In addition, this protein is capable of covalently attaching a reactive histidine to the heme 2-vinyl group. The structure of the protein in the low-spin ferric state with intact vinyl substituents was solved by NMR methods. It was found that the structure differs from that of known truncated hemoglobins primarily in the orientation of the E helix, which carries His46 (E10) as the distal ligand to the iron; the length and orientation of the F helix, which carries His70 (F8) as the proximal ligand to the iron; and the H-helix, which carries His117 (H16), the reactive histidine. Regions of enhanced flexibility include the short A helix, the loop connecting the E and F helices, and the last seven residues at the carboxy end. The structural data allowed for the rationalization of physical properties of the cyanobacterial protein, such as fast on-rate for small ligand binding, unstable apoprotein fold, and cross-linking ability. Comparison to the truncated hemoglobin from the green alga Chlamydomonas eugametos also suggested how the endogenous hexacoordination affected the structure.

Isolation and characterization of a family of stable RNA tetraloops with the motif YNMG that participate in tertiary interactions.

RNA is known to fold into a variety of structural elements, many of which have sufficient sequence complexity to make the thermodynamic study of each possible variant impractical. We previously reported a method for isolating stable and unstable RNA sequences from combinatorial libraries using temperature gradient gel electrophoresis (TGGE). This method was used herein to analyze a six-nucleotide RNA hairpin loop library. Three rounds of in vitro selection were performed using TGGE, and unusually stable RNAs were identified by cloning and sequencing. Known stable tetraloops were found, including sequences belonging to the UNCG motif closed by a CG base pair, and the CUUG motif closed by a GC base pair. In addition, unknown tetraloops were found that were nearly as stable as cUNCGg, including sequences related through substitution of the U with a C (Y), the C with an A (M), or both. These substitutions allow hydrogen bonding and stacking interactions in the UNCG loop to be maintained. Thermodynamic analysis of YNMG and variant loops confirmed optimal stability with Y at position 1 and M at position 3. Similarity in structure and stability among YNMG loops was further supported by deoxyribose substitution, CD, and NMR experiments. A conserved tertiary interaction in 16S rRNA exists between a YAMG loop at position 343 and two adenines in the loop at position 159 (Escherichia coli numbering). NMR and functional group substitution experiments suggest that YNAG loops in particular have enhanced flexibility, which allows the tertiary interaction to be maintained with diverse loop sequences at position 159. Taken together, these results support the existence of an extended family of UNCG-like tetraloops with the motif cYNMGg that are thermodynamically stable and structurally similar and can engage in tertiary interactions in large RNA molecules.

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.