Detergent solubilization of membrane-bound methane monooxygenase requires plastoquinol analogs as electron donors.

Quinols can provide reducing equivalents for the membrane-bound form of methane monooxygenase (pMMO), substituting for NADH in whole cells and membranes. Furthermore, quinols are effective reductants for the detergent-solubilized enzyme, whereas NADH is ineffective. The decyl analog of plastoquinol and duroquinol (2,3,5,6-tetramethylbenzoquinol) provide the greatest methane monooxygenase activity in whole cells and membrane suspensions, as well as detergent-solubilized samples. Lauryl maltoside is by far the best detergent for solubilization of catalytically active methane monooxygenase. Optimal pMMO activity in the detergent-solubilized fraction is obtained with a ratio of approximately 1.7 mg of detergent per milligram of membrane protein, independent of protein concentration. The detergent-solubilized pMMO retains its sensitivity to inhibition by cyanide, acetylene, and EDTA. It is also stimulated by exogenous copper, as in isolated membrane fractions. Reaction of the detergent-solubilized enzyme with [14C]acetylene results in labeling of a 26-kDa peptide, analogous to the behavior observed for isolated membrane suspensions. The selectivity of pMMO for duroquinol and decyl-plastoquinol, relative to other structurally similar quinols, suggests that the enzyme obtains reducing equivalents directly from a quinol (probably plastoquinol) in vivo.

The nature of the copper ions in the membranes containing the particulate methane monooxygenase from Methylococcus capsulatus (Bath).

It is shown that the particulate methane monooxygenase (pMMO) has an obligate requirement for copper. The MMO activity in the particulate fractions obtained from Methylococcus capsulatus (Bath) cells is found to increase with increasing copper content of the membranes. The enzyme activity from membranes obtained from cells grown at low copper levels can be stimulated further by the addition of Cu(II) ions to the assay medium. The membrane-bound copper ions can exist in both Cu(II) and Cu(I) forms. EPR and magnetic susceptibility characterizations of the membranes indicate the presence of an exchange-coupled trinuclear Cu(II) cluster when the bulk of the copper ions is oxidized. However, the functional form of the enzyme is the reduced or partially reduced form. The copper ions in the membrane fractions as isolated often exhibit a high level of reduction. An EPR spectrum with one unpaired electron spin delocalized over three copper nuclei has been observed for the two-electron reduced trinuclear copper cluster. The high correlation between the copper level in the membranes and enzymatic activity as well as the high reactivity of the reduced copper clusters toward dioxygen strongly indicate that the membrane-bound copper ions constitute the active sites of the pMMO.

Spectroscopic characterization of heme A reconstituted myoglobin.

The focus of this study was to examine the functional role of the unusual peripheral substitution of heme A. The effects of heme A stereochemistry on the reconstitution of the porphyrin have been examined in the heme A-apo-myoglobin complex using optical absorption and resonance Raman and electron paramagnetic resonance spectroscopies. The addition of one equivalent of heme A to apo-Mb produces a complex which displays spectroscopic signals consistent with a distribution of high- and low-spin heme chromophores. These results indicate that the incorporation of heme A into apo-Mb significantly perturbs the protein refolding.

Coordination chemistry of F430. Axial ligation equilibrium between square-planar and bis-aquo species in aqueous solution.

X-ray absorption spectroscopic characterization of axial ligand coordination to factor F430, the nickel-tetrapyrrole cofactor of the S-methyl-coenzyme M (CH3SCoM) methyl reductase enzyme from methanogenic bacteria, is presented. The nickel of isolated F430 is hexacoordinate at 10 K in aqueous solution (as is the enzyme-bound cofactor), whereas the epimerized and ring-oxidized derivatives of F430 have four-coordinate nickel. Reduction of the ring-oxidized derivative, F560, with dithionite yields F430 in its native configuration, with axial ligands indistinguishable from those present when the cofactor is obtained directly from the holoenzyme. Thus, we conclude that the axial ligands to F430 in aqueous solution are water molecules. Analysis of the nickel extended x-ray absorption fine structure is consistent with this conclusion. Resonance Raman spectra obtained at room temperature contain features characteristic of both 4- and 6-coordinate forms of the cofactor. We have found that the resonance Raman, optical, and x-ray absorption spectra of aqueous solutions of F430 are temperature-dependent due to a ligand-binding equilibrium involving the square-planar and 6-coordinate bis-aquo forms of the cofactor. At low temperatures (less than 250 K) the 6-coordinate form predominates, whereas higher temperature solutions contain both 4- and 6-coordinate species in a dynamic equilibrium. Similar behavior is observed in other weakly coordinating solvents such as methanol and ethanol. The 4-coordinate form is predominant in solvents with strong electron-withdrawing substituents such as 2,2,2-trifluoroethanol and 2-mercaptoethanol. The relevance of this facile ligand exchange to the active site structure and enzymatic mechanism of the parent enzyme is discussed.

Structural and spectroscopic characterization of exogenous ligand binding to isolated factor F430 and its configurational isomers.

Binding of axial ligands to the nickel(II) of isolated factor F430 from the methyl reductase enzyme of Methanobacterium thermoautotrophicum is demonstrated. Evidence of bis-ligand coordination is obtained from the x-ray absorption, optical, and resonance Raman spectral characterization of F430 and its 12,13-diepimeric isomer in the presence of a large excess of cyanide, pyridine, or 1-methylimidazole. Significant broadening and 5-10-nm red shifts of the main 430-nm optical absorption band and shifts of up to 30 cm-1 for the high-frequency Raman lines are observed upon coordination of these axial ligands. The Raman spectra of native F430 and the diepimer with a particular axial ligand are nearly identical. Nickel x-ray absorption edge spectra of the diepimer in the absence and presence of these exogenous ligands are indicative of conversion from a square-planar to a tetragonally distorted octahedral geometry. Analyses of the nickel extended x-ray absorption fine structure data for the ligated diepimer complexes yield detailed structural information for these complexes. Implications of these data with respect to the enzymatic mechanism and the structure of the enzyme-bound factor are discussed.

The active site of hemerythrin as determined by X-ray absorption fine structure.

Extensive X-ray absorption fine structure measurements and analysis have been made on azidomet- and methemerythrin and on the native forms of oxy- and deoxyhemerythrin. Due to the availability of models that have been synthesized to mimic the active site of hemerythrin, it was possible to make a thorough assessment of the various errors in the structural parameters determined by the analysis. It is found that the largest source of error is the lack of complete transferability of amplitude and phase between the standards and hemerythrin. This is of particular importance in distinguishing the contributions of the second-shell low-Z atoms and, thus, has a substantial influence on the determination of the iron-iron distance. The internal consistencies of the various checks and a new formulation of error analysis for the structural parameters give us confidence in the structure determined for the active site. The main result is that as O2 is released from oxyhemerythrin, the mu-oxo bridge between the two iron atoms in the active site with an Fe-O distance of 1.8 A converts to a mu-hydroxo bridge in deoxyhemerythrin, expanding the Fe-O distance to 2.0 A. The Fe-Fe distance expands proportionally from 3.24 A in oxyhemerythrin to 3.57 A in deoxyhemerythrin so as to keep the Fe-O-Fe bridging angle approximately constant. These conclusions provide experimental support for the structures of oxy- and deoxyhemerythrin proposed previously on the basis of spectroscopic and preliminary X-ray crystallographic data.

Structural heterogeneity and purification of protein-free F430 from the cytoplasm of Methanobacterium thermoautotrophicum.

F430 is the nickel containing tetrapyrrole cofactor of S-methyl coenzyme M methylreductase, the enzyme that catalyzes the final step of methane production by methanogenic bacteria: the reduction of S-methyl coenzyme M (H3CSCH2CH2SO3-) to methane and coenzyme M (HSCH2CH2SO3-). The protein-free F430 obtained from the cytosol of Methanobacterium thermoautotrophicum, strain delta H, exists predominantly in two isomeric forms that differ in relative stereochemical disposition of acid side chains at the 12 and 13 positions of the macrocycle periphery (Pfaltz, A., Livingston, D. A., Jaun, B., Diekert, G., Thauer, R. K., and Eschenmoser, A. (1985) Helv. Chim. Acta 68, 1338-1358). A simple one-step chromatographic procedure for the large-scale separation of these isomers is described. X-ray absorption spectroscopic studies show that F430 (i.e. the native isomer) is 6-coordinate with long nickel-ligand bonds (approximately 2.1 A), suggesting an approximately planar macrocycle. In contrast, the 12,13-diepimer exhibits a 4-coordinate, square-planar structure with short nickel-nitrogen bonds (approximately 1.9 A), suggesting a ruffled macrocycle. Previous reports, based on other x-ray absorption spectroscopic data, of static disorder in F430 Ni-N distances are shown to be incorrect due to sample heterogeneity. The optical spectrum of F430 (whether purified from the protein-free cytosol or extracted at high ionic strength from the holoenzyme) differs significantly from that of the 12,13-diepimer. The optical spectral differences are correlated with the alterations in coordination number and geometry of the central nickel ion in the two F430 isomers.

Nitric oxide adducts of the binuclear iron site of hemerythrin: spectroscopy and reactivity.

Nitric oxide forms adducts with the binuclear iron site of hemerythrin (Hr) at [Fe(II),Fe(II)]deoxy and [Fe(II),Fe(III)]semimet oxidation levels. With deoxyHr our results establish that (i) NO binds reversibly, forming a complex which we label deoxyHrNO, (ii) NO forms a similar but distinct complex in the presence of fluoride, which we label deoxyHrFNO, (iii) NO is directly coordinated to one iron atom of the binuclear pair in these adducts, most likely in a bent end-on fashion, and (iv) the iron atoms in the binuclear sites of both deoxyHrNO and deoxyHrFNO are antiferromagnetically coupled, thereby generating unique electron paramagnetic resonance (EPR) detectable species. The novel EPR signal of deoxyHrNO (deoxyHrFNO) with g[[ = 2.77 (2.58) and g = 1.84 (1.80) is explained by the magnetic interaction of the Fe(II) (S' = 2) and [FeNO]7 (S = 3/2) centers observed by Mössbauer spectroscopy. Antiferromagnetic coupling leads to a ground state of Seff = 1/2. Analysis of the EPR parameters using the isotropic spin-exchange Hamiltonian, Hex = 2JS3/2.S2, and including zero-field splitting leads to a coupling constant, -J approximately 23 cm-1, for deoxyHrNO. The resonance Raman spectrum of deoxyHrNO shows features at 433 and 421 cm-1 that shift downward with 15N16O and that are assigned to stretching and bending modes, respectively, of the [FeNO]7 unit. Sensitivity of the bending mode to D2O suggests that bound NO participates in hydrogen bonding. We propose that the terminal oxygen atom of NO is hydrogen bonded to the proton of the mu-hydroxo bridge in the Fe-(OH)-Fe unit. A bent Fe-N-O geometry is supported by spectroscopic and structural comparisons to synthetic complexes and is consistent with a limiting [FeII,FeIIINO-] formulation for deoxyHrNO. Reversibility of NO binding to deoxyHr is demonstrated by bleaching of the optical and EPR spectra of deoxyHrNO upon additions of excess N3- or CNO-. DeoxyHrNO undergoes autoxidation under anaerobic conditions over the course of several hours. The product of this autoxidation appears to be an EPR-silent NO adduct of semimetHr. The formal one-electron oxidations of the binuclear iron site of deoxyHr by NO and by HNO2 can conceivably occur with no net change in charge on the iron site. In contrast, autoxidation of oxy- to metHr requires a change in net charge on the iron site, which may provide a kinetic barrier.

Sulfide-bridged derivatives of the binuclear iron site of hemerythrin at both met and semi-met oxidation levels.

Exposure of methemerythrin (metHr) to S2- under anaerobic conditions results in a one-electron reduction to the semi-met level and replacement of the mu-oxo bridge between the irons with a single sulfide. The sulfide bridge is maintained upon ferricyanide oxidation of semi-metsulfide to metsulfide hemerythrin and upon subsequent dithionite or S2- reduction back to the semi-met level. Chemical analyses show that metsulfideHr contains one S2- per two Fe. The single quadrupole doublet (delta = 0.50 mm/s; delta Eq = 0.99 mm/s) in the Mössbauer spectrum is consistent with a bridging sulfide geometry. The optical and resonance Raman spectra of metsulfideHr are reminiscent of the [2Fe-2S] iron-sulfur proteins. The optical spectrum exhibits multiple S2----Fe(III) charge-transfer transitions between 400 and 600 nm. The resonance Raman spectrum reveals a series of overtones and combinations of the 431-cm-1 Fe-S-Fe symmetric vibration and the 327-cm-1 asymmetric vibration. The relative energies of the symmetric and asymmetric modes are characteristic of a sulfur-bridged system with a bridge angle of approximately 80 degrees. MetsulfideHr decomposes over several hours in air and over several days in the absence of O2 to metHr and semi-metsulfideHr, respectively. Unlike metHr and semi-metHr, neither the metsulfide nor the semi-metsulfide derivatives form stable adducts with anions such as azide or cyanide. Sulfide bridging confers new properties on the binuclear iron center that are of interest to an understanding of the chemistry of hemerythrin and also of the [2Fe-2S] iron-sulfur proteins.

Hydroxide ion binding to methemerythrin. An investigation by resonance Raman and difference spectroscopy.

The pH dependence for the interconversion of the acid and base forms of methemerythrin from Themiste dyscritum was investigated by difference spectroscopy. A new technique was designed to be able to study mixtures without knowledge of extinction coefficients or exact protein concentrations. The resultant pKa value of 8.4 proved that T. dyscritum hemerythrin crystals used for previous X-ray crystallographic studies at pH less than or equal to 6.5 were in the acid form. Since this material contains a 5-coordinate iron atom with no evidence of a ligated water molecule, it is more appropriately referred to as methemerythrin than aquomethemerythrin. The presence of an iron-bound hydroxide in the base form of methemerythrin was verified by resonance Raman spectroscopy for both T. dyscritum and Phascolopsis gouldii. At pH greater than 9, the protein from either species exhibited a new feature at 490 cm-1 that shifted to 518 cm-1 in D2O and was assigned to a coupled Fe-OH stretching and O-H bending vibration. Thus, hydroxomethemerythrin is the correct designation for the base form of the protein. The other resonance-enhanced vibration, the Fe-O-Fe symmetric stretch, was observed at 506 cm-1 in hydroxomethemerythrin and at 511 cm-1 in methemerythrin and was unaffected by deuteration. Addition of perchlorate to methemerythrin had no effect on the Raman spectrum, despite its known role in stabilizing the met form relative to the hydroxomet form.