Mini-myoglobin: preparation and reaction with oxygen and carbon monoxide

A domain of 108 amino acid residues (32 to 139), obtained by digestion of horse heart apomyoglobin with clostripain, was found to bind protoheme in a 1 to 1 molar ratio. This domain is 33 amino acid residues larger than the protein segment encoded by the central exon in seal myoglobin. Flash photolysis experiments have shown that reconstituted "mini-myoglobin" is very similar to myoglobin in the combination reaction with carbon monoxide and with oxygen, and in the oxygen replacement reaction by carbon monoxide. These experiments provide for the first time direct evidence for the presence of a structural and functional domain, closely corresponding to the segment encoded by the central exon of the myoglobin gene, which contains the information for binding the natural heme and for maintaining the native folding typical of a respiratory protein.     

Cloning, overexpression and characterization of micro-myoglobin, a minimal heme-binding fragment.

We report the cloning and expression of micro-myoglobin, a 78-amino-acid fragment containing residues 29-105 of sperm whale myoglobin, and spanning the region from mid-helix B to mid-helix G of the globin fold. In contrast to full-length myoglobin and to mini-myoglobin (residues 32-129), the micro-myoglobin apoprotein is almost unfolded. However, circular dichroism and absorption spectroscopy data indicate that this fragment is capable of folding into a functional heme-binding unit forming a complex with the prosthetic group with characteristics similar to native myoglobin. Therefore, this case represents a new example of cofactor-assisted folding. The experimental data suggest independence between myoglobin subdomains.     

Mini-myoglobin. Electron paramagnetic resonance and reversible oxygenation of the cobalt derivative.

Mini-myoglobin, obtained by limited proteolysis of horse heart myoglobin (residues 32 to 139), represents a good model for testing the correlation between an exon and a protein domain. We have shown that ligand binding kinetics, spectral and folding features of mini-myoglobin are very similar to those of native myoglobin. In order to develop further the analysis of the structure-function relationship in this mini-protein, mini-globin was reconstituted with the heme moiety in which iron is replaced by cobalt. The Soret absorption spectra of oxy and deoxy cobaltous mini-myoglobin are very similar to those of cobaltous myoglobin derivatives; in addition. Co-mini-myoglobin binds oxygen reversibly with an n value approximately 1 and a p50 value of 45 to 50 mm Hg (the same as Co-myoglobin). Oxy Co-mini-myoglobin shows a well-resolved electron paramagnetic resonance (e.p.r.) spectrum typical of an oxygenated hemoprotein, while the spectrum of the deoxy derivative, although similar to that of deoxy Co-myoglobin, displays a lower resolution of the complex hyperfine structure. Moreover, photodissociation experiments on oxy Co-mini-myoglobin allow e.p.r. detection of an intermediate state, already observed in most hemoproteins and diagnostic for the interaction of bound oxygen with the distal histidine residue. Thus, reconstitution of mini-globin with cobalt protoprophyrin IX has provided, for the first time, a stable oxygenated complex that reflects a correct folding of the protein surrounding the heme pocket and possesses the functional behaviour typical of a hemoprotein.     

Assignment of hyperfine shifted haem methyl carbon resonances in paramagnetic low-spin met-cyano complex of sperm whale myoglobin

The hyperfine shifted resonances arising from all four individual haem carbons of the paramagnetic low-spin met-cyano complex of sperm whale myoglobin have been clearly identified and assigned for the first time with the aid of 1H-13C heteronuclear chemical shift correlated spectroscopy. Alteration of the in-plane symmetry of the electronic structure of haem induced by the ligation of proximal histidyl imidazole spreads the haem carbon resonances to 32 ppm at 22 degrees C, indicating the sensitivity of those resonances to the haem electronic/molecular structure. Those resonances are potentially powerful probes in characterizing the nature of haem electronic structure.     

Effects of mutation of the conserved glutamic acid-286 in subunit I of cytochrome c oxidase from Rhodobacter sphaeroides

We have studied the effects of mutations, E286Q and E286D, of the conserved glutamate in subunit I of cytochrome c oxidase from Rhodobacter sphaeroides with a view to evaluating the role of this residue in redox-linked proton translocation. The mutation E286D did not have any dramatic effects on enzyme properties and retained 50% of wild-type catalytic activity. For E286Q a fraction of the binuclear center was trapped in an unreactive, spectrally distinct form which is most likely due to misfolded protein, but the majority of E286Q reacted normally with formate and cyanide in the oxidized state, and with carbon monoxide and cyanide in the dithionite-reduced form. The mutation also had little effect on the pH-dependent redox properties of haem a in the reactive fraction. However, formation of the P state from oxidized enzyme with hydrogen peroxide or by aerobic incubation with carbon monoxide was inhibited. In particular, only an F-type product was obtained, at less than 25% yield, in the reaction with hydrogen peroxide. The aerobic steady state in the presence of ferrous cytochrome c was characterized by essentially fully reduced haem a and ferric haem a3, suggesting that the mutation hinders electron transfer from haem a to the binuclear center. Under these conditions or after reoxidation, on a seconds time scale, of haem a3 following anaerobiosis, there was no indication of accumulation of significant amounts of P state. We propose that the glutamate is implicated in several steps in the catalytic cycle, O --> R, P --> F, and, possibly, F --> O. The results are discussed in relation to the "glutamate trap" model for proton translocation.     

Interaction between external medium and haem pocket in myoglobin probed by low-temperature optical spectroscopy

The visible absorption spectra of carbonmonoxymyoglobin in the temperature range 300 to 20 K are reported and compared with the analogous spectra of carbonomonoxyhaemoglobin. The temperature dependence of the zeroth, first and second moment of the observed bands is analysed to obtain information on the local dynamics in the proximity of the haem. Contrary to haemoglobin, the first moment of the observed bands in myoglobin is markedly affected by the solvent composition and its value saturates at temperatures at which the solvent undergoes the glass transition. These data indicate that solvent properties influence the haem pocket stereodynamics in myoglobin; moreover, the different behaviour between myoglobin and haemoglobin suggests that the process should involve the surfaces that are buried in the haemoglobin tetramer and exposed to the solvent in myoglobin, and/or the different protein compressibility.     

Geminate recombination of n-butyl isocyanide to myoglobin

Transient optical absorption spectra of myoglobin were measured following photolysis of the n-butyl isocyanide complex with 10-ns laser pulses at room temperature. The data were analyzed by using singular value decomposition to give the kinetics of ligand rebinding and spectral changes. Geminate recombination phases were observed at 30 ns and 1 microsecond following photodissociation. These processes were accompanied by simultaneous changes in the shape of the Soret band which indicate changes in protein conformation. These spectral changes are not present in the geminate recombination of photolyzed complexes of myoglobin with the diatomic ligands oxygen and carbon monoxide. This difference in behavior, as well as the slower overall association rate of n-butyl isocyanide to myoglobin, can be rationalized as arising from distortion of the protein structure by the larger isocyanide ligand along the binding pathway.     

Structure of deoxy-quaternary haemoglobin with liganded beta subunits

We have determined the structure of a T-state haemoglobin in which the haem groups of the beta subunits have carbon monoxide bound, and the alpha subunits have nickel replacing the haem iron and are ligand-free. The structural adjustments on binding ligand in the T state are in the same direction as those associated with the quaternary transition, and a translational shift of the haem is severely restricted. We explain how these observations may account for the low ligand affinity of the beta haem of T-state haemoglobin.     

Electron addition to the (FeO2) unit of oxyhaemoglobin Glycera

Exposure of glassy solutions containing the monomeric fraction of the oxyhaemoglobin of the polychaete annelid Glycera dibranchiata to 60Co gamma-rays at 77 K resulted in electron addition to the (FeO2) moiety. The form of the g tensor components obtained from the ESR spectrum indicates that the spin-density on oxygen is much greater than that observed for similar paramagnetic centres formed in haemoglobin A or myoglobin. A major difference between these monomer haem units and normal haem units is that the distal histidine (E7 58) is replaced by leucine. We therefore postulate that the oxygen in the (FeO2)- units formed in haemoglobin A and myoglobin is hydrogen-bonded to the NH group of the distal histidine, whilst that of the (FeO2)- units in haemoglobin Glycera are not hydrogen-bonded. However, on annealing to approx. 160 K the spectrum changed irreversibly into one resembling those for (FeO2)- units in haemoglobin A and myoglobin. We postulate that this is caused by hydrogen-bonding to a water molecule in the haem pocket. Exposure of the polymeric fractions of haemoglobin Glycera to gamma-rays gave an (FeO2)- unit with an ESR spectrum remarkably similar to that obtained from oxymyoglobin. The X-ray structure of this protein is unknown but we suggest that our results could indicate the presence of a distal histidine in this material.     

The IsdG‐family of haem oxygenases degrades haem to a novel chromophore

Enzymatic haem catabolism by haem oxygenases is conserved from bacteria to humans and proceeds through a common mechanism leading to the formation of iron, carbon monoxide and biliverdin. The first members of a novel class of haem oxygenases were recently identified in Staphylococcus aureus (IsdG and IsdI) and were termed the IsdG‐family of haem oxygenases. Enzymes of the IsdG‐family form tertiary structures distinct from those of the canonical haem oxygenase family, suggesting that IsdG‐family members degrade haem via a unique reaction mechanism. Herein we report that the IsdG‐family of haem oxygenases degrade haem to the oxo‐bilirubin chromophore staphylobilin. We also present the crystal structure of haem‐bound IsdI in which haem ruffling and constrained binding of oxygen is consistent with cleavage of the porphyrin ring at the β‐ or δ‐meso carbons. Combined, these data establish that the IsdG‐family of haem oxygenases degrades haem to a novel chromophore distinct from biliverdin.     

1H and 15N resonance assignments and secondary structure of the carbon monoxide complex of sperm whale myoglobin

Summary Sequence-specific backbone ¹H and ¹⁵N resonance assignments have been made for 95% of the amino acids in sperm whale myoglobin, complexed with carbon monoxide (MbCO). Many assignments for side-chain resonances have also been obtained. Assignments were made by analysis of an extensive series of homonuclear 2D spectra, measured with unlabeled protein, and both 2D and 3D ¹H-¹⁵N-correlated spectra obtained from uniformly ¹⁵N-labeled myoglobin. Patterns of medium-range NOE connectivities indicate the presence of eight helices in positions that are very similar to those found in the crystal structures of sperm whale myoglobin. The resonance assignments of MbCO form the basis for determination of the solution structure and for hydrogen-exchange measurements to probe the stability and folding pathways of myoglobin. They will also form a basis for assignment of the spectra of single-site mutants with altered ligand-binding properties.     

Role of haem oxygenase-1 in microbial host defence

Haem oxygenase (HO)-1 is a cytoprotective enzyme that plays a critical role in defending the body against oxidant-induced injury during inflammatory processes. HO catalydes the degradation of haem to carbon monoxide (CO), biliverdin and ferrous iron. Biliverdin is converted to bilirubin, a potent endogenous antioxidant. CO has a number of biological functions, including anti-inflammatory properties. In various models of disease, HO-1 is known to play a critical role by ameliorating the pathological consequences of injury. In many of these models, the beneficial effects of HO-1 and its products of haem catabolism are by suppressing an inflammatory response. However, when investigating diseases due to microbial infections, inhibition of the inflammatory response could disrupt the ability of the immune system to eradicate an invading pathogen. Thus, questions remain regarding the role of HO-1 in microbial host defence. This microreview will address our present understanding of HO-1 and its functional significance in a variety of microbial infections.     

A proton magnetic relaxation study of ferric myoglobin and haemoglobin in water/ethanediol solutions.

Structural alterations of the haem vicinity of the high-spin derivatives of bovine ferric myoglobin (metmyoglobin) and human haemoglobin and the changes of the interaction with inositol hexaphosphate induced by ethanediol were monitored by solvent-proton magnetic relaxation. On addition of ethanediol up to 60% the fluoromet derivatives exhibit a gradual increase in the accessibility of the haem for the molecules from the solvent. In aquomethaemoglobin solutions with more than 25% ethanediol there is no unique explanation of proton magnetic relaxation. Ethanediol enhances the binding of inositol hexaphosphate to methaemoglobin, but the structural consequences of this binding on the haem-pockets seem to be diminished. The mechanisms of the observed structural and functional alterations of myoglobin as well as haemoglobin tetramer are discussed here.     

Oxidation of glycine by Phaseolus leghaemoglobin with associated catabolic reactions at the haem.

Leghaemoglobin from the root nodules of kidney bean (Phaseolus vulgaris) reacts in alkaline glycine solutions as a glycine oxidase in a reaction that may also be regarded as a coupled oxidation. Leghaemoglobin is reduced to the ferrous form by glycinate, the oxygen complex is formed, and finally the haem is attacked to yield a green reaction product. Glycine is simultaneously oxidized to glyoxylate, and hydrogen peroxide is generated. The initial velocity of the formation of the green product is proportional to the concentrations of leghaemoglobin and glycine, and the optimum pH for the reaction is 10.2. The green product is not formed if carbon monoxide, azide of imidazole is bound to the haem, whereas oxidation of glycine to glyoxylate is not inhibited by azide and not essentially by carbon monoxide. Haem breakdown is activated by digestion of leghaemoglobin by carboxypeptidase, and partly inhibited by catalase and superoxide dismutase.     

Histidine and not tyrosine is required for the peroxide-induced formation of haem to protein cross-linked myoglobin

Peroxide-induced oxidative modifications of haem proteins such as myoglobin and haemoglobin can lead to the formation of a covalent bond between the haem and globin. These haem to protein cross-linked forms of myoglobin and haemoglobin are cytotoxic and have been identified in pathological conditions in vivo. An understanding of the mechanism of haem to protein cross-link formation could provide important information on the mechanisms of the oxidative processes that lead to pathological complications associated with the formation of these altered myoglobins and haemoglobins. We have re-examined the mechanism of the formation of haem to protein cross-link to test the previously reported hypothesis that the haem forms a covalent bond to the protein via the tyrosine 103 residue (Catalano, C. E., Choe, Y. S., Ortiz de Montellano, P. R., J. Biol. Chem. 1989, 10534 - 10541). Comparison of native horse myoglobin, recombinant sperm whale myoglobin and Tyr(103) --> Phe sperm whale mutant shows that, contrary to the previously proposed mechanism of haem to protein cross-link formation, the absence of tyrosine 103 has no impact on the formation of haem to protein cross-links. In contrast, we have found that engineered myoglobins that lack the distal histidine residue either cannot generate haem to protein cross-links or show greatly suppressed levels of modified protein. Moreover, addition of a distal histidine to myoglobin from Aplysia limacina, that naturally lacks this histidine, restores the haem protein's capacity to generate haem to protein cross-links. The distal histidine is, therefore, vital for the formation of haem to protein cross-link and we explore this outcome.     

Kinetic and equilibrium studies of the reactions of heme-substituted horse heart myoglobins with oxygen and carbon monoxide.

In order to study the effects of chemical modifications of the vinyl groups of heme on oxygen and carbon monoxide binding to myoglobin, apomyoglobins from horse heart were reconstituted with six different hemins with various side chains. Laser flash photolysis experiments of these reconstituted myoglobins showed that the combination rate constants for oxygen (k') and carbon monoxide (l') were closely related to the electron-attractive properties of the side chains. The k' values obtained in 0.1 M potassium phosphate buffer, pH 7.0, at 20 degrees were 0.83 (meso-), 2.4 (deutero-), 1.1 (reconstituted proto-), 1.2 (native proto-), 1.5 (2-formyl-4-vinyl-), 1.9 (2-vinyl-4-formyl-), and 2.7 X 10(7) M-1 S-1 (2,4-diformylmyoglobins), and the corresponding l' values were 2.8, 18, 4.8, 5.1, 7.1, 15, and 35 X 10(5) M-1 S-1, respectively. These rate constants tend to increase as the electron-withdrawing power of the side chains increases, indicating that reduced electron density of the iron atom of heme in myoglobin favors the combination reaction for both oxygen and carbon monoxide. Equilibrium constants (L) between carbon monoxide and various myoglobins were also determined by measuring the partition coefficients (M) between oxygen and carbon monoxide for the myoglobins, and were also found to be closely related to the electronic properties (pK3 of porphyrin) of the heme side chains. The equilibrium association constants for carbon monoxide thus obtained increased with a decrease in pK3 value of the porphyrin. This order was completely opposite to the case of the oxygen binding reaction. The dissociation rate constants for oxygen (k) and carbon monoxide (l) were calculated from the equilibrium and the combination rate constants. The dissociation rate constants showed a similar characteristic to the combination rate constants and increased with the increase in electron attractivity of heme side chains. The concomitant increase in both the combination and dissociation rate constants with increase in electronegativity of the iron atom suggests that these reactions have different rate determining steps, although such a reaction process is contradictory to the generally accepted concept that in a reversible reaction, both on and off reactions proceed through the same transition state. In the on reaction sigma bond formation appears to be dominant, while in the off reaction eta bond break-up is more important.     

Geminate rebinding in trehalose-glass embedded myoglobins reveals residue-specific control of intramolecular trajectories.

It is becoming increasingly apparent that hydrophobic cavities (also referred to as xenon cavities) within proteins have significant functional implications. The potential functional role of these cavities in modulating the internal dynamics of carbon monoxide in myoglobin (Mb) is explored in the present study by using glassy matrices derived from trehalose to limit protein dynamics and to eliminate ligand exchange between the solvent and the protein. By varying the temperature (-15 to 65 degrees C) and humidity for samples of carbonmonoxy myoglobin embedded in trehalose-glass, it is possible to observe a hierarchy of distinct geminate recombination phases that extend from nanosecond to almost seconds that can be directly associated with rebinding from specific hydrophobic cavities. The use of mutant forms of Mb reveals the role of key residues in modulating ligand access between these cavities and the distal hemepocket.     

Reactivity of ferrous myoglobin at low pH.

The rates of reaction of myoglobin with carbon monoxide at low pH are reported. The pH versus rate profile of these kinetics resembles that found for heme model compounds, revealing an increase in combination rate at low pH. These facts suggest that CO binding by myoglobin changes from a mechanism of "direct ligant association" at pH 5 to a mechanism, similar to that proposed for heme model compounds, which assumes a tetracoordinated intermediate as a result of the protonation of the proximal imidazole.     

New techniques in fast time-resolved structure determination.

New techniques in fast time-resolved X-ray crystallography provide a different approach to understanding the structural basis of protein function. Two biological systems have been studied as part of the refinement of these techniques, and have actually spurred new ideas in time-resolved structural studies. The dissociation of carbon monoxide from carbon-monoxy myoglobin has earlier been investigated over a time range spanning 18 orders of magnitude (femtoseconds to hours) using spectroscopic methods. Rapid time-resolved determination of the entire myoglobin structure made it possible to determine both the position of the CO after photodissociation and the entire globin structure, over a time range from nanoseconds to milliseconds, during which the heme and globin relax and the carbon monoxide rebinds. Photoactive yellow protein, a relative newcomer to biophysical research, has a fully-reversible photocycle containing several spectrally distinct intermediates. Identifying and solving the structures of each intermediate is the initial goal in time-resolved studies on this protein and will contribute to a greater understanding of the biological process of light driven signal transduction.