1H-NMR studies of the coordination geometry at the heme iron and the electronic structure of the heme group in cytochrome c-552 from Euglena gracilis

Heme crevice disorder after sixth ligand displacement in the cytochrome c-551 family

1H NMR and visible absorption spectroscopy were used to monitor sixth ligand methionine displacement reactions in four members of the ferricytochrome c-551 family from Pseudomonas aeruginosa, Pseudomonas stutzeri, Pseudomonas stutzeri substrain ZoBell, and Nitrosomonas europae. Potassium cyanide displaces the methionine ligand with very modest changes in the visible spectra, but profound changes in the NMR spectra. The initial product formed kinetically, designated complex I, changes with time and/or heating to a more thermodynamically favored product termed complex II. Spectra indicate that both I and II are actually a family of closely related conformational isomers. Low temperature NMR spectra of complex II indicate that some of the isomers are in chemical exchange on the NMR time scale. High pH also displaces the methionine ligand in a manner similar to the well-known alkaline transition of mitochondrial cytochrome c. However, the reaction occurs at higher pH values and over a narrower pH range for the c-551 family, and the transition pH range is different for the different proteins studied. The final alkaline forms also show peak widths and a number of peaks indicative of multiple conformational isomers.

Characteristics of the paramagnetic 1H-NMR spectra of the ferricytochrome c-551 family

Heme proton resonances have been assigned for ferricytochromes c-551 isolated from four distinct species of bacteria. While the available structure information indicates that the four cytochromes have very similar conformations in solution, including the chirality of the methionine ligand sulfur bond, the chemical shifts of the paramagnetically shifted resonances are surprisingly different, more so than has been previously reported for a homologous series of ferricytochromes. The resonances are contrasted in terms of chemical shift and the temperature dependence of the shift, which gives rise to a very strong anti-Curie effect for some specific protons. Non-methyl heme resonances do display an approximately conserved set of chemical shifts, but the heme methyl groups demonstrate a wide range of values. The 12(1) heme methyl group is always the highest frequency heme methyl, but the relative positions of the other methyl groups may change. The 7(1) heme methyl group always displayed strong anti-Curie behavior, while the 12(1) methyl group displayed normal Curie behavior. The behavior of the other methyl groups was variable. Possible reasons for the range of observations will be discussed. In spite of their NMR differences, all the ferricytochromes c-551 demonstrated comparable electron-transfer rates to a membrane-bound cytochrome reductase system.

Cytochrome c6 from Monoraphidium braunii. A cytochrome with an unusual heme axial coordination

A soluble monoheme c-type cytochrome (cytochrome c6) has been isolated from the green alga Monoraphidium braunii. It has a molecular mass of 9.3 kDa, an isoelectric point of 3.6 and a reduction potential of 358 mV at pH 7. The determined amino acid sequence allows its classification as a class-I c-type cytochrome. The ferric and ferrous cytochrome forms and their pH equilibria have been studied using 1H-NMR, ultraviolet/visible, EPR and Mössbauer spectroscopies. The pH equilibria are complex, several pKa values and pH-dependent forms being observed. The amino acid sequence, the reduction-potential value and the visible and NMR spectroscopies data in the pH range 4-9 indicate that the heme iron has a methionine-histidine axial coordination. However, the EPR and Mössbauer data obtained for the ferricytochrome show that in this pH range two distinct forms are present: form I, gz = 3.27, gy = 2.05 and gx = 1.05; form II, gz = 2.95, gy = 2.29 and gx = 1.43. While form I has crystal-field parameters typical of a methionine-histidine coordination, those associated with form II would suggest a histidine-histidine axial ligation. This possibility was extensively analyzed by spectroscopic methods and by chemical modification of a histidine residue. It was concluded that form II actually corresponds to an unusual type of methionine-histidine axial coordination. Straightforward examples of this type of coordination have recently been found in other c-type hemeproteins [Teixeira, M., Campos, A. P., Aguiar, A. P., Costa, H. S., Santos, H., Turner, D. L. & Xavier, A. V. (1993) FEBS Lett. 317, 233-236], corroborating our proposal. Since both forms, with very distinct crystal-field parameters, are shown to have the same reduction potential, it may be concluded that the axial and rhombic distortions of the heme-iron ligand field cannot be directly correlated with the heme-reduction potential. The pH-dependence studies have also shown that the form I and form II are interconvertible, with pKa approximately 5. To establish a possible physiological significance for this process, in particular for the interaction of the cytochrome with the membrane-bound electron-transfer complexes b6f and photosystem I, the effect of surfactants on the spectroscopic characteristics of cytochrome c6 has been studied.

Redox properties of the diheme cytochrome c4 from Azotobacter vinelandii and characterisation of the two hemes by NMR, MCD and EPR spectroscopy

From biphasic stopped-flow kinetic studies it has been established that the two heme centres of cytochrome c4 from Azotobacter vinelandii undergo redox change with [Co(terpy)2]3+/2+ (260 mV) at different rates. Rate constants for oxidation and reduction at pH 7.5 give reduction potentials for the two heme centres in agreement with previous values from spectrophotometric titrations (263 and 317 mV). From NMR studies on the fully reduced protein two sharp methyl methionine resonances are observed at -3.16 and -3.60 ppm, consistent with axial methionine coordination. On titration with [Fe(CN)6]3- the -3.16 ppm resonance is the first to disappear, and is assigned to the less positive reduction potential. Line-broadening effects are observed on partial oxidation, which are dominated by intermolecular processes in an intermediate time-range exchange process. The hemes of the oxidised protein are distinguishable by EPR g-values of 3.64 and 3.22. The former is of interest because it is at an unusually low field for histidine/methionine coordination, and has an asymmetric or ramp shape. The latter assigned to the low potential heme is similar to that of a cytochrome c551. The MCD spectra of the fully oxidised protein are typical of low-spin Fe(III) heme centres, with a negative peak at 710 nm characteristic of methionine coordination, and an NIR peak at 1900 nm characteristic of histidine/methionine (axial) coordination. Of the four histidines per molecule only two undergo diethyl pyrocarbonate (DEPC) modification.

Proton hyperfine resonance assignments using the nuclear Overhauser effect for ferric forms of horse and tuna cytochrome c

Proton hyperfine resonance assignments for cytochromes c from several species are currently being successfully pursued by several laboratories. These efforts focus mostly on the ferrous forms. In contrast to that work, we have pursued assignments of the proton hyperfine shifted resonances for horse and tuna ferricytochromes c. Our results indicate that assignments are nearly identical in those two proteins. Using the pre-steady state nuclear Overhauser effect, several additional assignments have been made for the tuna protein, whereas for the horse protein, the following protons have been assigned: heme 7, alpha CH2; heme 7, beta CH2; histidine 18, beta CH2 and alpha CH; and the methionine 80, beta CH2.

Amino acid sequence, haem-iron co-ordination geometry and functional properties of mitochondrial and bacterial c-type cytochromes

Cytochromes are found in all biological oxidation Systems which involve transport of reducing equivalents through organized chains of membrane bound intermediates, regardless of the ultimate oxidant (Keilin, 1966; Bartsch, 1978; Meyer & Kamen, 1982). Thus, cytochromes are present not only in the aerobic mitochondrial and bac-terial respiratory chain, but are also found in much more diversified procariotic Systems, including all varieties of facultative anaerobes (nitrate and nitrite reducers), obligate anaerobes (sulphate reducers and phototrophic sulphur bacteria), facultative photoheterotrophes (phototrophic non-sulphur purple bacteria), and the photoautotrophic cyanobacteria (blue-green algae). Among the different types of cytochromes occurring in the cell, the soluble c-type cytochromes (‘class I’, Meyer & Kamen, 1982) are the most abundant and best characterized group of proteins (Bartsch, 1978; Meyer & Kamen, 1982; Dickerson & Timkovitch, 1975; Lemberg & Barrett, 1973; Salemme, 1977; Ferguson-Miller, Brautigan & Margoliash, 1979). The amino acid sequences of more than 80 mitochrondrial and close to 40 bacterial cytochromes c are known (Meyer & Kamen, 1982; Dickerson & Timkovitch, 1975; Schwartz & Dayhoff, 1976; Dayhoff & Barker, 1978).

Proton NMR spectroscopy of Alcaligenes cytochrome c556

A high molecular-weight c-type cytochrome was purified from Alcaligenes faecalis ATCC 8750. Its weight was 40,000 daltons by sodium dodecyl sulfate-gel electrophoresis. Heme content was determined to be one heme per 40,000 daltons. Proton nuclear magnetic resonance-NMR-spectroscopy determined that the ferrous form is low spin. The detection of a methyl resonance at -3 ppm in the ferrous form indicated that methionine is a heme ligand in this state. The NMR spectrum of the ferric form at pH 7.2 revealed hyperfine shifted methyl resonances at 67.79, 63.17, 57.71, and 50.46 ppm. The large downfield shifts observed are indicative of high spin character. The ferric spectrum was pH-sensitive, indicating two pH-linked structural transitions with estimated pKs at 6.0 and 10.5. The first is interpreted as due to the ionization of a heme propionate. The second is interpreted as the acquisition of a strong field ligand and the subsequent conversion to a low spin ferric form. The ferricytochrome did not form complexes with cyanide, azide, or fluoride at pH 5.2 or 7.9.

Coordination of the heme iron in the low-potential cytochromes c-553 from Desulfovibrio vulgaris and Desulfovibrio desulfuricans. Different chirality of the axially bound methionine in the oxidized and reduced states

The coordination geometry at the heme iron of the cytochromes c-553 from Desulfovibrio vulgaris and Desulfovibrio desulfuricans was investigated by 1H-nuclear magnetic resonance and circular dichroism spectroscopy. Individual assignments were obtained for heme c and the axial ligands. From studies of nuclear Overhauser enhancements the axial histidine imidazole ring orientation relative to the heme group was found to coincide with other c-type cytochromes. In contrast, a new structure was observed for the axial methionine in the reduced cytochromes c-553. This includes S chirality at the iron-bound sulfur atom, but compared to cytochromes c-551 from Pseudomonads and Rhodopseudomonas gelatinosa and cytochrome c5 from Pseudomonas mendocina, which also contain S-chiral methionine, a different spatial arrangement of the gamma- and beta-methylene groups and the alpha carbon of methionine prevails. For the ferricytochromes c-553 R chirality was found for the iron-bound sulfur. This is the first observation of different methionine chirality in different oxidation states of the same c-type cytochrome.

A new spatial structure for the axial methionine observed in cytochrome c5 from Pseudomonas mendocina. Correlations with the electronic structure of heme c

Cytochrome c5 from Pseudomonas mendocina has been isolated and the coordination geometry at the heme iron was investigated by 1H nuclear magnetic resonance and circular dichroism spectroscopy. Individual assignments were obtained for heme c and the axial ligands. From studies of nuclear Overhauser enhancements the axial histidine imidazole ring orientation relative to the heme group was found to coincide with that of other c-type cytochromes. In contrast, a new structure was observed for the axial methionine. This includes S chirality at the iron-bound sulfur atom, but compared to cytochromes c-551 from Pseudomonads and Rhodopseudomonas gelatinosa, which also contain S-chiral methionine, the spatial arrangement of the gamma- and beta-methylene groups and the alpha carbon of methionine is markedly different. Analysis of the electron spin density distribution in ferricytochrome c5 in the light of this new coordination geometry provides additional support for the hypothesis that the electronic structure of heme c is primarily governed by the orientation of the sp3 lone-pair orbital of the axial sulfur atom with respect to the heme plane.

Individual 1H-NMR assignments for the heme groups and the axially bound amino acids and determination of the coordination geometry at the heme iron in a mixture of two isocytochromes c-551 from Rhodopseudomonas gelatinosa

This paper describes chemical and physicochemical studies of two small isocytochromes c-551 (approx. 9000 dalton) from Rhodopseudomonas gelatinosa. In spite of numerous amino acid substitutions in the N-terminal half of the sequence the two isoproteins could not be separated by the procedures used, presumably because they have identical size, charge and isoelectric points. Individual assignments of the 1H-NMR lines of heme c and the axial ligands to the heme iron were therefore obtained by nuclear Overhauser enhancement measurements and saturation transfer experiments in a mixed solution of the two isocytochromes c-551. The conformation of the coordination sphere was investigated by additional 1H-NMR and circular dichroism studies. For both isoproteins the electronic structure of the heme and the chirality of the methionine attachment to the iron were found to coincide with those in Pseudomonas cytochromes c-551, i.e., S chirality was observed for the axial methionine. The Rps. gelatinosa cytochromes c-551 thus differ from mammalian, yeast, Euglena gracilis and Rhodospirillum rubrum cytochromes c, which all have R chirality at the axial methionine and concomitantly a characteristically different electronic heme structure. This is the first observation of S chirality of the axially bound methionine in a species outside the Pseudomonas family. The redox potentials of the two isocytochromes c-551 of Rps. gelatinosa differ by approx. 120 mV, and there is no cross-exchange of electrons between the two species. The two isoproteins could thus function in two different, parallel electron-transfer chains or at two different locations in a single transfer sequence.

Determination of the coordination geometry at the heme iron in three cytochromes c from Saccharomyces cerevisiae and from Candida krusei based on individual 1H-NMR assignments for heme c and the axially coordinated amino acids

The 1H-NMR lines of heme c and the axial ligands in reduced and oxidized Iso-1 and Iso-2 cytochromes c from Saccharomyces cerevisiae and in cytochrome c from Candida krusei were individually assigned and the conformation of the coordination sphere of the heme iron was investigated with the use of proton-proton Overhauser enhancement measurements and circular dichroism spectroscopy. The coordination geometry of the axial methionine and the axial histidine and the electronic structure of the heme were found to be closely similar in these yeast cytochromes c and in mammalian cytochromes c. In particular, R chirality at the sulfur atom of the iron-bound methionine was observed in both groups of proteins. Additional nuclear Overhauser enhancement studies of the spatial arrangement relative to the heme group of amino acid side-chains in the heme crevice of yeast ferrocytochromes c showed that the conformational homologies extend beyond the immediate coordination sphere of the heme iron. These data provide a conformational basis for observations on the functional properties of cytochromes c from yeast and mammalian species, which were reported previously by other groups.

1H-NMR studies of structural homologies between the heme environments in horse cytochrome c and in cytochrome c-552 from Euglena gracilis

With the use of proton-proton Overhauser enhancement experiment the spatial arrangement relative to the heme group of amino acid side chains in the heme crevice of horse ferrocytochrome c and ferrocytochrome c-552 from euglena gracilis was investigated. From these data and the known crystal structure for mammalian cytochromes c, individual assignments were obtained for several aromatic residues in horse ferrocytochrome c. This then provided a basis for delineating homologies between the polypeptide conformations near the heme group in horse ferrocytochrome c and ferrocytochrome c-552, for which no crystal structure has as yet been described.