Mechanistic Insights into the Activation of Soluble Guanylate Cyclase by Carbon Monoxide: A Multistep Mechanism Proposed for the BAY 41-2272 Induced Formation of 5-Coordinate CO-Heme.

Soluble guanylate cyclase (sGC) is a heme-containing enzyme that catalyzes cGMP production upon sensing NO. While the CO adduct, sGC-CO, is much less active, the allosteric regulator BAY 41-2272 stimulates the cGMP productivity to the same extent as that of sGC-NO. The stimulatory effect has been thought to be likely associated with Fe-His bond cleavage leading to 5-coordinate CO-heme, but the detailed mechanism remains unresolved. In this study, we examined the mechanism under the condition including BAY 41-2272, 2'-deoxy-3'-GMP and foscarnet. The addition of these effectors caused the original 6-coordinate CO-heme to convert to an end product that was an equimolar mixture of a 5- and a new 6-coordinate CO-heme, as assessed by IR spectral measurements. The two types of CO-hemes in the end product were further confirmed by CO dissociation kinetics. Stopped-flow measurements under the condition indicated that the ferrous sGC bound CO as two reversible steps, where the primary step was assigned to the full conversion of the ferrous enzyme to the 6-coordinate CO-heme, and subsequently followed by the slower second step leading a partial conversion of the 6-coordinate CO-heme to the 5-coordinate CO-heme. The observed rates for both steps linearly depended on CO concentrations. The unexpected CO dependence of the rates in the second step supports a multistep mechanism, in which the 5-coordinate CO-heme is led by CO release from a putative bis-carbonyl intermediate that is likely provided by the binding of a second CO to the 6-coordinate CO-heme. This mechanism provides a new aspect on the activation of sGC by CO.

Initial O2 Insertion Step of the Tryptophan Dioxygenase Reaction Proposed by a Heme-Modification Study.

L-Tryptophan 2,3-dioxygenase (TDO) is a protoheme-containing enzyme that catalyzes the production of N-formylkynurenine by inserting O2 into the pyrrole ring of L-tryptophan. Although a ferrous-oxy form (Fe²âº-O2) has been established to be an obligate intermediate in the reaction, details of the ring opening reaction remain elusive. In this study, the O2 insertion reaction catalyzed by Pseudomonas TDO (PaTDO) was examined using a heme-modification approach, which allowed us to draw a quantitative correlation between the inductive electronic effects of the heme substituents and the substituent-induced changes in the functional behaviors of the ferrous-oxy form. We succeeded in preparing reconstituted PaTDO with synthetic hemes, which were different with respect to the inductive electron-withdrawing nature of the heme substituents at positions 2 and 4. An increase in the electron-withdrawing power of the heme substituents elevated the redox potential of reconstituted PaTDO, showing that the stronger the electron-withdrawing ability of the heme substituents, the lower the electron density on the heme iron. The decrease in the electron density of the heme iron resulted in a higher frequency shift of the C-O stretch of the heme-bound CO and enhanced the dissociation of O2 from the ferrous-oxy intermediate. This result was interpreted as being due to weaker π back-donation from the heme iron to the bound CO or O2. More importantly, the reaction rates of the ferrous-oxy intermediate to oxidize L-Trp were increased with the electron-withdrawing ability of the heme substituents, implying that the more electron-deficient ferrous-oxy heme is favored for the PaTDO-catalyzed oxygenation. On the basis of these results, we propose that the initial step of the dioxygen activation by PaTDO is a direct electrophilic addition of the heme-bound O2 to the indole ring of L-Trp.

Oxygen binding and redox properties of the heme in soluble guanylate cyclase: implications for the mechanism of ligand discrimination.

Soluble guanylate cyclase is an NO-sensing hemoprotein that serves as a NO receptor in NO-mediated signaling pathways. It has been believed that this enzyme displays no measurable affinity for O(2), thereby enabling the selective NO sensing in aerobic environments. Despite the physiological significance, the reactivity of the enzyme-heme for O(2) has not been examined in detail. In this paper we demonstrated that the high spin heme of the ferrous enzyme converted to a low spin oxyheme (Fe(2+)-O(2)) when frozen at 77 K in the presence of O(2). The ligation of O(2) was confirmed by EPR analyses using cobalt-substituted enzyme. The oxy form was produced also under solution conditions at -7 °C, with the extremely low affinity for O(2). The low O(2) affinity was not caused by a distal steric protein effect and by rupture of the Fe(2+)-proximal His bond as revealed by extended x-ray absorption fine structure. The midpoint potential of the enzyme-heme was +187 mV, which is the most positive among high spin protoheme-hemoproteins. This observation implies that the electron density of the ferrous heme iron is relatively low by comparison to those of other hemoproteins, presumably due to the weak Fe(2+)-proximal His bond. Based on our results, we propose that the weak Fe(2+)-proximal His bond is a key determinant for the low O(2) affinity of the heme moiety of soluble guanylate cyclase.

Focal distribution of baculovirus IE1 triggered by its binding to the hr DNA elements.

In BmN cells infected with the baculovirus Bombyx mori nucleopolyhedrovirus (BmNPV), IE1, a principal transcriptional activator, localizes to sites of viral DNA replication. IE1 initially displays focal distribution in BmNPV-infected cells prior to DNA synthesis, whereas the protein expressed by transfection with the ie1 gene is distributed throughout the nucleoplasm instead of localized to discrete subnuclear structures. To identify the inducer of focus formation for IE1, we conducted transfection experiments with an IE1-GFP construct and found that cotransfection with genomic DNA fragments bearing the homologous region (hr) sequences caused the formation of IE1-green fluorescent protein (GFP) foci. The transfection of insect cells with a single plasmid containing exclusively the hr3 sequence and the IE1-GFP gene was sufficient to form IE1-GFP foci. These results suggest that hr elements are a primary determinant of the focal distribution of IE1. An analysis of a series of hr3 deletion mutants showed that a single copy of the direct repeat could induce the formation of IE1 foci. Targeted mutagenesis within the hr-binding domain of IE1-GFP caused impairment of the hr-dependent IE1 localization, suggesting that binding of IE1 to the hr elements is essential for the onset of IE1 focus formation. The observation of BmNPV IE1 foci in non-BmNPV-susceptible cells suggests that no species-specific factors are required for hr-dependent IE1 focus formation.

Design and synthesis of de novo cytochromes c.

Natural c-type cytochromes are characterized by the consensus Cys-X-X-Cys-His heme-binding motif (where X is any amino acid) by which the heme is covalently attached to protein by the addition of the sulfhydryl groups of two cysteine residues to the vinyl groups of the heme. In this work, the consensus sequence was used for the heme-binding site of a designed four-helix bundle, and the apoproteins with either a histidine residue or a methionine residue positioned at the sixth coordination site were synthesized and reacted with iron protoporphyrin IX (protoheme) under mild reducing conditions in vitro. These polypeptides bound one heme per helix-loop-helix monomer via a single thioether bond and formed four-helix bundle dimers in the holo forms as designed. They exhibited visible absorption spectra characteristic of c-type cytochromes, in which the absorption bands shifted to lower wavelengths in comparison with the b-type heme binding intermediates of the same proteins. Unexpectedly, the designed cytochromes c with bis-His-coordinated heme iron exhibited oxidation-reduction potentials similar to those of their b-type intermediates, which have no thioether bond. Furthermore, the cytochrome c with His and Met residues as the axial ligands exhibited redox potentials increased by only 15-30 mV in comparison with the cytochrome with the bis-His coordination. These results indicate that highly positive redox potentials of natural cytochromes c are not only due to the heme covalent structure, including the Met ligation, but also due to noncovalent and hydrophobic environments surrounding the heme. The covalent attachment of heme to the polypeptide in natural cytochromes c may contribute to their higher redox potentials by reducing the thermodynamic stability of the oxidized forms relatively against that of the reduced forms without the loss of heme.

ADP reduces the oxygen-binding affinity of a sensory histidine kinase, FixL: the possibility of an enhanced reciprocating kinase reaction.

The rhizobial FixL/FixJ system, a paradigm of heme-based oxygen sensors, belongs to the ubiquitous two-component signal transduction system. Oxygen-free (deoxy) FixL is autophosphorylated at an invariant histidine residue by using ATP and catalyzes the concomitant phosphoryl transfer to FixJ, but oxygen binding to the FixL heme moiety inactivates the kinase activity. Here we demonstrate that ADP acts as an allosteric effector, reducing the oxygen-binding affinity of the sensor domain in FixL when it is produced from ATP in the kinase reaction. The addition of ADP to a solution of purified wild-type FixL resulted in an approximately 4- to 5-fold decrease in oxygen-binding affinity in the presence of FixJ. In contrast, phosphorylation-deficient mutants, in which the well conserved ATP-binding catalytic site of the kinase domain is impaired, showed no such allosteric effect. This discovery casts light on the significance of homodimerization of two-component histidine kinases; ADP, generated in the phosphorylation reaction in one subunit of the homodimer, enhances the histidine kinase activity of the other, analogous to a two-cylinder reciprocating engine by reducing the ligand-binding affinity.

Functional characterization of bacterial signal peptide OmpA in a baculovirus-mediated expression system.

Signal sequences are evolutionarily conserved and are often functionally interchangeable between prokaryotes and eukaryotes. However, we have found that the bacterial signal peptide, OmpA, functions incompletely in insect cells. Upon baculovirus-mediated expression of chloramphenicol acetyltransferase (CAT) in insect cells, OmpA signal peptide led to the cytosolic accumulation of the CAT molecules in an aglycosylated, signal-peptide cleaved form, in addition to the secretion of the glycosylated CAT. When green fluorescent protein (GFP) was used as another reporter, the GFP molecules expressed from the OmpA-GFP construct was distributed primarily in the cytosol as aggresome-like structures. These results together suggest that, subsequent to the cleavage of OmpA signal peptide in the ER, some of the processed proteins are returned to the cytoplasm. Since the prototypical insect signal peptide, melittin, did not result in this ER-to-cytosol dislocation of the reporter proteins, we proposed a model explaining the dislocation process in insect cells, apparently selective to the OmpA-directed secretory pathway bypassing the co-translational transport.

The uncoupling of oxygen sensing, phosphorylation signalling and transcriptional activation in oxygen sensor FixL and FixJ mutants.

The rhizobial FixL/FixJ system, a member of the superfamily of bacterial two-component signal transducing systems, regulates the expression of nitrogen fixation-related genes by sensing environmental oxygen tension. Oxygen-free (deoxy) FixL is autophosphorylated at an invariant histidine residue with ATP, and the phosphoryl group is transferred to FixJ, leading to an enhancement in transcriptional activity at low oxygen tensions, but the histidine kinase activity of the oxygen-bound (oxy) form is inhibited. To investigate the mechanism of oxygen sensing, we established a FixL/FixJ-mediated PfixK-lacZ reporter system in Escherichia coli, and isolated FixL and FixJ mutations conferring an upregulation of lacZ gene expression on the reporter cells even under aerobic conditions. FixL mutant proteins, which contain single amino acid changes near the autophosphorylation site, showed elevated levels of autophosphorylation and a concomitant phosphoryl transfer to FixJ in the presence of oxygen, although their oxygen-binding affinities were unimpaired. These mutational analyses suggest that the autophosphorylation domain plays a crucial role in regulatory coupling between oxygen binding and kinase activity. FixJ mutants in helix alpha1 and strand beta5 of the N-terminal half exhibited the formation of a stable acyl phosphate bond. In contrast, those in helices alpha4 and alpha5 constitutively bound to the fixK promoter in a monomeric form, suggesting that the alpha4 and alpha5 helices may be involved in the post-phosphorylation/dimerization signal transfer to liberate the DNA-binding activity of the C-terminal domain, not only serving as a dimerization interface.

Contribution of heme-propionate side chains to structure and function of myoglobin: chemical approach by artificially created prosthetic groups.

Horse heart myoglobin was reconstituted with mesohemin derivatives methylated at the 6- or 7-position to evaluate the role of the heme-6-propionate or heme-7-propionate side chain in the protein. The association and dissociation of the O(2) binding for the deoxymyoglobin with 6-methyl-7-propionate mesoheme are clearly accelerated. Furthermore, the myoglobin with 6-methyl-7-propionate mesoheme shows fast autoxidation from oxymyoglobin to metmyoglobin compared to the myoglobin with 6-propionate-7-methyl heme and the reference protein. These results indicate the 6-propionate plays an important physiological role in the stabilization of oxymyoglobin because of the formation of a salt-bridge with the Lys45. The acceleration of CO binding rate is observed for the myoglobin with 6-propionate-7-methyl mesoheme, suggesting that the replacement of the 7-propionate with a methyl group has an influence on the His93-heme iron coordination. The structural perturbation of His93 imidazole was also supported by 1H NMR spectra of cyanide and deoxy forms of the myoglobin with 6-propionate-7-methyl mesoheme. Thus, it is found that the 7-propionate regulates the hydrogen-bonding network and His93-heme iron coordination in the proximal site.