Insights into the alkaline transformation of ferricytochrome c from (1)H NMR studies in 30% acetonitrile-water

Recently, we found that ferricytochrome c (ferricyt c) undergoes significant structural changes in mixed aqueous-nonaqueous media, resulting in the formation of a mixture of alkaline-like species. The equilibrium composition of this mixture of species is dependent on the dielectric constant of the mixed solvent medium. One-dimensional (1D) and two-dimensional (2D) (1)H nuclear magnetic resonance (NMR) methods have now been used to study these alkaline-like forms in 30% acetonitrile-water solution. A native-like (M80-ligated) III* form, two lysine-ligated forms (IVa* and IVb*), and a hydroxide-ligated form (V*) were observed. Heme proton resonance assignments for these forms were accomplished using 1D (1)H NMR and 2D nuclear Overhauser effect spectroscopy methods at 20 degrees C and 35 degrees C. The chemical exchange between the alkaline forms in 30% acetonitrile solution facilitated heme proton resonance assignments. Based on examination of the heme proton chemical shifts and several highly conserved amino acid residues, the electronic structure, secondary structure, and hydrogen bond network in the vicinity of the heme in the III* form were found to be intact. Similarly, the heme electronic structure of the IVa* form was found to be comparable to that of the IVa form. Differences in the order of the heme methyl resonances in the IVb* form, however, suggest that the heme active site in this form is somewhat different from that observed in aqueous alkaline solution. In addition, resonance assignments for the 8- and 3-methyl heme protons were made for the hydroxide-ligated V* form for the first time. The observation of chemical exchange peaks between all species except IVb* and IVa* or V* was used to propose an exchange pathway between the different forms of ferricyt c in 30% acetonitrile solution. This pathway may be biologically significant because ferricyt c, which resides in the intermembrane space of mitochondria, is exposed to medium of relatively low dielectric constant when it interacts with the mitochondrial membrane.     

Structure–function relationship of reduced cytochrome c probed by complete solution structure determination in 30% acetonitrile/water solution

The complete solution structure of ferrocytochrome c in 30% acetonitrile/70% water has been determined using high-field 1D and 2D (1)H NMR methods and deposited in the Protein Data Bank with codes 1LC1 and 1LC2. This is the first time a complete solution protein structure has been determined for a protein in nonaqueous media. Ferrocyt c retains a native protein secondary structure (five alpha-helices and two omega loops) in 30% acetonitrile. H18 and M80 residues are the axial heme ligands, as in aqueous solution. Residues believed to be axial heme ligands in the alkaline-like conformers of ferricyt c, specifically H33 and K72, are positioned close to the heme iron. The orientations of both heme propionates are markedly different in 30% acetonitrile/70% water. Comparative structural analysis of reduced cyt c in 30% acetonitrile/70% water solution with cyt c in different environments has given new insight into the cyt c folding mechanism, the electron transfer pathway, and cell apoptosis.     

A proton NMR study of the non-covalent complex of horse cytochrome c and yeast cytochrome-c peroxidase and its comparison with other interacting protein complexes

Cytochrome-c peroxidase (ferrocytochrome-c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) forms a noncovalent 1:1 complex with horse cytochrome c in low ionic strength solution that is detectable by proton NMR spectroscopy. When the entire proton hyperfine-shifted spectrum is considered only five hyperfine resonances exhibit unambiguously detectable shifts: the heme 8-CH3 and 3-CH3 resonances, single proton resonances near 19 ppm and -4 ppm and the methionine-80 methyl group. These shifts are very similar to those observed for the covalently crosslinked complex of cytochrome-c peroxidase and horse cytochrome c, but different from those reported for cytochrome c complexes with flavodoxin and cytochrome b5. By comparison with the shifts reported for lysine-13-modified cytochrome c we conclude that the results reported here support the Poulos-Kraut proposed structure for the molecular redox complex between cytochrome-c peroxidase and cytochrome c. These results indicate that the principal site of interaction with cytochrome-c peroxidase is the exposed heme edge of horse cytochrome c, in proximity to lysine-13 and the heme pyrrole II. The noncovalent cytochrome-c peroxidase-cytochrome c complex exists in the rapid-exchange time limit even at 500 mHz proton frequency. Our data provide an improved estimate of the minimum off-rate for exchanging cytochrome c as 1133 (+/- 120) s-1 at 23 degrees C.     

Expression of a synthetic gene for horseradish peroxidase C in Escherichia coli and folding and activation of the recombinant enzyme with Ca2+ and heme

A synthetic gene encoding horseradish peroxidase isoenzyme C (HRP C) has been synthesized and expressed in Escherichia coli. The nonglycosylated recombinant enzyme (HRP C*) was produced in inclusion bodies in an insoluble inactive form containing only traces of heme. HRP C* was solubilized and conditions under which it folded to give active enzyme were determined. Folding was shown to be critically dependent upon the concentrations of urea, Ca2+, and heme and on oxidation by oxidized glutathione. Purification of active HRP C* from the folding mixture gave a peroxidase, with about half the activity of HRP C. Glycosylation is thus not essential for correct folding and activity. The C-terminal and N-terminal extensions to HRP identified previously in cloned cDNA sequences are also not required for correct folding. However, Ca2+ appears to play a key role in folding to give the active enzyme. The overall yield of purified active enzyme was 2-3%, but this could be increased by reprocessing material that precipitated during folding.     

Molten globule-like state of cytochrome c induced by polyanion poly(vinylsulfate) in slightly acidic pH.

The effect of polyanion, poly(vinylsulfate), used as a model of negatively charged surface, on ferric cytochrome c (ferricyt c) structure in acidic pH has been studied by absorbance spectroscopy, circular dichroism (CD), tryptophan (Trp) fluorescence and microcalorimetry. The polyanion induced only small changes in the native structure of the protein at neutral pH, but it profoundly shifted the acid induced high spin state of the heme in the active center of cyt c to a more neutral pH region. Cooperativity of the acidic transition of ferricyt c in the presence of the polyanion was disturbed, in comparison with uncomplexed protein, as followed from different apparent pK(a) values observed in a distinct regions of the ferricyt c electronic absorbance spectrum (4.55+/-0.08 in the 620 nm band region and 5.47+/-0.15 in the Soret region). The ferricyt c structure in the complex with the polyanion at acidic pH (below pH 5.0) has properties of a molten globule-like state. Its tertiary structure is strongly disturbed according to CD and microcalorimetry measurements; however, its secondary structure, from CD, is still native-like and ferricyt c is in a compact state as evidenced by quenched Trp fluorescence. These findings are discussed in the context of the molten globule state of proteins induced on a negatively charged membrane surface under physiological conditions.     

1H NMR structural characterization of the cytochrome c modifications in a micellar environment

The interaction of cytochrome c with micelles of sodium dodecyl sulfate was studied by proton NMR spectroscopy. The protein/micelles ratio was found to be crucial in controlling the extent of the conformational changes in the heme crevice. Over a range of ratios between 1:30 and 1:60, the NMR spectra of the ferric form display no paramagnetic signals due to a moderately fast exchange between intermediate species on the NMR time scale. This is consistent with an interconversion of bis-histidine derivatives (His18-Fe-His26 and His18-Fe-His33). Further addition of micelles induces a high-spin species that is proposed to involve pentacoordinated iron. The resulting free binding site, also encountered in the ferrous form, is used to complex exogenous ligands such as cyanide or carbon monoxide. Attribution of the heme methyls was performed by means of exchange spectroscopy through ligand exchange or electron transfer. The heme methyl shift pattern of the micellar cyanocytochrome in the ferric low spin form is different from the pattern of both the native and the cyanide cytochrome c adduct, in the absence of micelles, reflecting a complete change of the heme electronic structure. Analysis of the electron self-exchange reaction between the two redox states of the micellar cyanocytochrome c yields a rate constant of 2.4 x 10(4) M(-1) s(-1) at 298 K, which is surprisingly close to the value observed in the native protein.     

Sequential assignment of the proton NMR spectrum of isolated alpha(CO) chains from human adult hemoglobin.

In this paper we report proton two-dimensional NMR experiments on isolated alpha chains from human hemoglobin A (HbA) in the monocarboxylated state. Several J-correlated and NOE spectra in water or deuterium water and phosphate buffer (100 mM) at 310 K and pH 5.6 were acquired and analysed for the sequential assignment of the proton resonances. In addition, we used the topological data obtained from the crystal structure of alpha subunits in the monocarboxylated HbA tetramer. The assigned resonances correspond to 70% of the amino acid residues. The present results provide information on the tertiary structure of isolated alpha chains in solution, particularly in the heme region. This structure may be compared with that of the a subunits in the tetrameric HbA(CO) in crystal by comparison of observed chemical shifts and those calculated from the X-ray atomic coordinates. Overall, the global folding of the two forms are highly similar. However, this analysis points out several local conformational differences in the heme pocket and the neighboring of the unique Trp residue. Possible explanations of these differences are discussed.     

Assignment of proton resonances in the NMR spectrum of carbonmonoxy hemoglobin beta subunit tetramers

Isolated beta chains from human adult hemoglobin at millimolar concentration are mainly associated to form beta 4 tetramers. We were able to obtain relevant two-dimensional proton nuclear magnetic resonance (NMR) spectra of such supermolecular complexes (Mr approximately 66,000) in the carboxylated state. Analysis of the spectra enabled us to assign the major part of the proton resonances corresponding to the heme substituents. We also report assignments of proton resonances originating from 12 amino acid side chains mainly situated in the heme pocket. These results provide a basis for a comparative analysis of the tertiary heme structure in isolated beta(CO) chains in solution and in beta(CO) subunits of hemoglobin crystals. The two structures are generally similar. A significantly different position, closer to the heme center, is predicted by the NMR for Leu-141 (H19) in isolated beta chains. Comparison of the assigned resonances of conserved amino acids in alpha chains, beta chains and sperm whale myoglobin indicates a close similarity of the tertiary heme pocket structure in the three homologous proteins. Significant differences were noted on the distal heme side, at the position of Val-E11, and on Leu-H19 and Phe-G5 position on the proximal side.     

Synthesis and characterization of N-methyliminodiacetato trans-R,R-, trans-S,S-, and cis-1,2-diaminocyclohexane platinum (IV) complexes: crystal structure of chloro(trans-R,R-1,2-diaminocyclohexane) (N-methyliminodiacetato) platinum(IV) chloride.

The compounds, chloro(trans-R,R-1,2-diaminocyclohexane) (N-methyliminodiacetato)platinum(IV) chloride, chloro(trans-S,S-1,2-diaminocyclohexane)(N-methyliminodiacetato) platinum(IV) chloride, and chloro(cis-1,2-diaminocyclohexane)(N-methyliminodiacetato)platinum (IV) chloride, were prepared and characterized by elemental analysis, IR, and 195Pt NMR. The crystal structure of one of these three compounds, chloro(trans-R,R-1,2-diaminocyclohexane) (N-methyliminodiacetato) platinum(IV) chloride, was determined by x-ray single crystal diffraction. This compound is particularly interesting because the 1,2-diaminocyclohexane (DACH) ring is in a twist-boat configuration rather than the chair configuration previously reported for other DACH platinum compounds. The crystal structure consists of two independent cations and anions, with all atoms between these two independent molecules (except those in the chiral DACH) related by a pseudo-inversion center. Both platinum atoms have slightly distorted octahedral coordination, with angles ranging from 81.8 to 100.8 degrees. Crystallographic details: space group P2(1) (monoclinic); a = 19.864(5) A, b = 7.026(2) A, c = 12.446(3) A, beta = 106.64(2) degrees; Z = 4; R = 0.036 for 2333 reflections.     

Proton NMR assignments of heme contacts and catalytically implicated amino acids in cyanide-ligated cytochrome c peroxidase determined from one- and two-dimensional nuclear Overhauser effects.

Proton NMR assignments of the heme pocket and catalytically relevant amino acid protons have been accomplished for cyanide-ligated yeast cytochrome c peroxidase. This form of the protein, while not enzymatically active itself, is the best model available (that displays a resolvable proton NMR spectrum) for the six-coordinate low-spin active intermediates, compounds I and II. The assignments were made with a combination of one- and two-dimensional nuclear Overhauser effect methods and demonstrate the utility of NOESY experiments for paramagnetic proteins of relatively large size (Mr 34,000). Assignments of both isotope exchangeable and nonexchangeable proton resonances were obtained by using enzyme preparations in both 90% H2O/10% D2O and, separately, in 99.9% D2O solvent systems. Complete resonance assignments have been achieved for the proximal histidine, His-175, and His-52, which is a member of the catalytic triad on the distal side of the heme. In addition, partial assignments are reported for Trp-51 and Arg-48, catalytically important residues, both on the distal side. Aside from His-175, partial assignments for amino acids on the proximal side of the heme are proposed for the alanines at primary sequence positions 174 and 176 and for Thr-180 and Leu-232.     

Solution structure and dynamics of the functional domain of Paracoccus denitrificans cytochrome c(552) in both redox states

A soluble and fully functional 10.5 kDa fragment of the 18.2 kDa membrane-bound cytochrome c(552) from Paracoccus denitrificans has been heterologously expressed and (13)C/(15)N-labeled to study the structural features of this protein in both redox states. Well-resolved solution structures of both the reduced and oxidized states have been determined using high-resolution heteronuclear NMR. The overall protein topology consists of two long terminal helices and three shorter helices surrounding the heme moiety. No significant redox-induced structural differences have been observed. (15)N relaxation rates and heteronuclear NOE values were determined at 500 and 600 MHz. Several residues located around the heme moiety display increased backbone mobility in both oxidation states, while helices I, III, and V as well as the two concatenated beta-turns between Leu30 and Arg36 apparently form a less flexible domain within the protein structure. Major redox-state-dependent differences of the internal backbone mobility on the picosecond-nanosecond time scale were not evident. Hydrogen exchange experiments demonstrated that the slow-exchanging amide proton resonances mainly belong to the helices and beta-turns, corresponding to the regions with high order parameters in the dynamics data. Despite this correlation, the backbone amide protons of the oxidized cytochrome c(552) exchange considerably faster with the solvent compared to the reduced protein. Using both differential scanning calorimetry as well as temperature-dependent NMR spectroscopy, a significant difference in the thermostabilities of the two redox states has been observed, with transition temperatures of 349.9 K (76.8 degrees C) for reduced and 307.5 K (34.4 degrees C) for oxidized cytochrome c(552). These results suggest a clearly distinct backbone stability between the two oxidation states.     

Proton-NMR studies of the effects of ionic strength and pH on the hyperfine-shifted resonances and phenylalanine-82 environment of three species of mitochondrial ferricytochrome c.

Ferricytochromes c from three species (horse, tuna, yeast) display sensitivity to variations in solution ionic strength or pH that is manifested in significant changes in the proton NMR spectra of these proteins. Irradiation of the heme 3-CH3 resonances in the proton NMR spectra of tuna, horse and yeast iso-1 ferricytochromes c is shown to give NOE connectivities to the phenyl ring protons of Phe82 as well as to the beta-CH2 protons of this residue. This method was used to probe selectively the Phe82 spin systems of the three cytochromes c under a variety of solution conditions. This phenylalanine residue has previously been shown to be invariant in all mitochondrial cytochromes c, located near the exposed heme edge in proximity to the heme 3-CH3, and may function as a mediator in electron transfer reactions [Louie, G. V., Pielak, G. J., Smith, M. & Brayer, G. D. (1988) Biochemistry 27, 7870-7876]. Ferricytochromes c from all three species undergo a small but specific structural rearrangement in the environment around the heme 3-CH3 group upon changing the solution conditions from low to high ionic strength. This structural change involves a decrease in the distance between the Phe82 beta-CH2 group and the heme 3-CH3 substituent. In addition, studies of the effect of pH on the 1H-NMR spectrum of yeast iso-1 ferricytochrome c show that the heme 3-CH3 proton resonance exhibits a pH-dependent shift with an apparent pK in the range of 6.0-7.0. The chemical shift change of the yeast iso-1 ferricytochrome c heme 3-CH3 resonance is not accompanied by an increase in the linewidth as previously described for horse ferricytochrome c [Burns, P. D. & La Mar, G. N. (1981) J. Biol. Chem. 256, 4934-4939]. These spectral changes are interpreted as arising from an ionization of His33 near the C-terminus. In general, the larger spectral changes observed for the resonances in the vicinity of the heme 3-CH3 group in yeast iso-1 ferricytochrome c with changes in solution conditions, relative to the tuna and horse proteins, suggest that the region around Phe82 is more open and that movement of the Phe82 residue is less constrained in yeast ferricytochrome c. Finally, it is demonstrated here that both the heme 8-CH3 and the 7 alpha-CH resonances of yeast ferricytochrome c titrate with p2H and exhibit apparent pK values of approximately 7.0. The titrating group responsible for these spectral changes is proposed to be His39.     

Proton NMR comparison of the Saccharomyces cerevisiae ferricytochrome c isozyme-1 monomer and covalent disulfide dimer

Proton NMR studies of Saccharomyces cerevisiae (bakers yeast) isozyme-1 monomer and dimer ferricytochrome c have been carried out. The dimer is formed via a disulfide bridge between the Cys-102 residues of monomer proteins. Nuclear Overhauser effect (NOE) experiments have led to resonance assignments for many of the heme and axial ligand (Met-80; His-18) protons in both protein forms. Resonances of the following amino acids have also been assigned in both forms: Phe-10; Pro-30; Phe-82; Trp-59; Leu-68. The proton NOE connectivity patterns of the monomer of yeast isozyme-1 ferricytochrome c are similar to those of horse, tuna, and yeast isozyme-2 ferricytochromes c, even though the observed hyperfine resonance spectra are significantly different for the various cytochromes. The pattern of dimer proton hyperfine resonances is distinct from the isozyme-1 monomer pattern, which indicates that the formation of a disulfide bridge via Cys-102 is detected at the heme site, approximately 10 A distant. It appears that a specific structural change is induced upon dimerization, which, in turn, causes specific perturbations in the vicinity of the heme. However, the general features of the NOE connectivity pattern in the dimer are the same as for the monomer indicating that dimerization does not result in drastic structural disruption. Furthermore, the 1H NMR spectrum of the dimer can be mimicked by the monomer form that results when the -SH group of Cys-102 is chemically modified with certain types of bulky, or hydrophilic reagents (i.e. 5,5'-dithiobis[2-nitrobenzoate], indicating that perturbations of the yeast isozyme-1 ferricytochrome c proton resonance spectrum observed upon dimerization are essentially due to changes in intramolecular, rather than intermolecular, interactions. These results suggest that a possible regulatory site for yeast isozyme-1 cytochrome c exists at position 102, which could conceivably have a physiological role in altering the conformation of the molecule.     

Assignment of 1H and 13C hyperfine-shifted resonances for tuna ferricytochrome c.

Tuna ferricytochrome c has been used to demonstrate the potential for completely assigning 1H and 13C strongly hyperfine-shifted resonances in metalloprotein paramagnetic centers. This was done by implementation of standard two-dimensional NMR experiments adapted to take advantage of the enhanced relaxation rates of strongly hyperfine-shifted nuclei. The results show that complete proton assignments of the heme and axial ligands can be achieved, and that assignments of several strongly shifted protons from amino acids located close to the heme can also be made. Virtually all proton-bearing heme 13C resonances have been located, and additional 13C resonances from heme vicinity amino acids are also identified. These results represent an improvement over previous proton resonance assignment efforts that were predicated on the knowledge of specific assignments in the diamagnetic protein and relied on magnetization transfer experiments in heterogeneous solutions composed of mixtures of diamagnetic ferrocytochrome c and paramagnetic ferricytochrome c. Even with that more complicated procedure, complete heme proton assignments for ferricytochrome c have never been demonstrated by a single laboratory. The results presented here were achieved using a more generally applicable strategy with a solution of the uniformly oxidized protein, thereby eliminating the requirement of fast electron self-exchange, which is a condition that is frequently not met.     

Heme ligation and conformational plasticity in the isolated c domain of cytochrome cd1 nitrite reductase

The heme ligation in the isolated c domain of Paracoccus pantotrophus cytochrome cd(1) nitrite reductase has been characterized in both oxidation states in solution by NMR spectroscopy. In the reduced form, the heme ligands are His69-Met106, and the tertiary structure around the c heme is similar to that found in reduced crystals of intact cytochrome cd1 nitrite reductase. In the oxidized state, however, the structure of the isolated c domain is different from the structure seen in oxidized crystals of intact cytochrome cd1, where the c heme ligands are His69-His17. An equilibrium mixture of heme ligands is present in isolated oxidized c domain. Two-dimensional exchange NMR spectroscopy shows that the dominant species has His69-Met106 ligation, similar to reduced c domains. This form is in equilibrium with a high-spin form in which Met106 has left the heme iron. Melting studies show that the midpoint of unfolding of the isolated c domain is 320.9 +/- 1.2 K in the oxidized and 357.7 +/- 0.6 K in the reduced form. The thermally denatured forms are high-spin in both oxidation states. The results reveal how redox changes modulate conformational plasticity around the c heme and show the first key steps in the mechanism that lead to ligand switching in the holoenzyme. This process is not solely a function of the properties of the c domain. The role of the d1 heme in guiding His17 to the c heme in the oxidized holoenzyme is discussed.     

Platinum(II) complexes with l-methionylglycine and l-methionyl-l-leucine ligands: synthesis, characterization and in vitro antitumoral activity

Four dipeptide complexes of the type [PtX(2)(dipeptide)] x H(2)O (X=Cl, I, dipeptide=l-methionylglycine, l-methionyl-l-leucine) were prepared. The complexes were characterized by (1)H, (13)C, (195)Pt NMR and infrared spectroscopy, DTG and elemental analysis. From the infrared, (1)H and (13)C NMR spectroscopy it was concluded that dipeptides coordinate bidentately via sulfur and amine nitrogen donor atoms. Confirmed with (13)C and (195)Pt NMR spectroscopy, each of the complexes exists in two diastereoisomeric forms, which are related by inversion of configuration at the sulfur atom. The (1)H NMR spectrum for the platinum(II) complex with l-methionylglycine and chloro ligands exhibited reversible, intramolecular inversion of configuration at the S atom; DeltaG( not equal)=72 kJ mol(-1) at coalescence temperature 349 K was calculated. In vitro cytotoxicity studies using the human tumor cell lines liposarcoma, lung carcinoma A549 and melanoma 518A2 revealed considerable activity of the platinum(II) complex with l-methionylglycine and chloro ligands. Further in vitro cytotoxic evaluation using human testicular germ cell tumor cell lines 1411HP and H12.1 and colon carcinoma cell line DLD-1 showed moderate cytotoxic activity for all platinum(II) complexes only in the cisplatin-sensitive cell line H12.1. Platinum uptake studies using atomic absorption spectroscopy indicated no relationship between uptake and activity. Potential antitumoral activity of this class of platinum(II) complexes is dependent on the kind of ligands as well as on tumor cell type.     

Proton and nitrogen-15 NMR studies of ferricytochrome c cyanide complexes: remarkable conservation of the heme environment among organisms of diverse origin

The native ferric and cyanide-bound ferric forms of nine vertebrate and two yeast cytochromes c have been investigated by high-resolution proton nuclear magnetic resonance spectroscopy. Spectral comparisons have been made among the cytochromes with emphasis on the signal positions for heme and amino acid ligand protons. Consistent with earlier more limited studies of native ferric cytochromes c, the paramagnetically shifted proton NMR signals show little variation among species with up to 50% substitution of amino acids. Proton NMR spectra for the cyanide complexes also show little variation among species. The nitrogen-15 signal for the coordinated cyanide ion is known to be highly variable among other hemoproteins, but the signal covers a range of only 855 to 865 ppm (nitrate ion reference) for vertebrate cytochromes c and 884 to 886 ppm for yeast cytochromes c. The cyanide ligand probe thus reports an amazing conservation of the heme and proximal ligand environment among the cytochromes. Comparative proton and nitrogen-15 chemical shift values are consistent with a slightly stronger proximal histidine imidazole hydrogen bond to an amino acid carbonyl function than is the case for hemoglobin and myoglobin.     

Proton NMR comparison of noncovalent and covalently cross-linked complexes of cytochrome c peroxidase with horse, tuna, and yeast ferricytochromes c.

Proton NMR spectroscopy at 500 and 361 MHz has been used to characterize the noncovalent or electrostatic complexes of yeast cytochrome c peroxidase (CcP) with horse, tuna, yeast isozyme-1, and yeast isozyme-2 ferricytochromes c and the covalently cross-linked complexes of cytochrome c peroxidase with horse and yeast isozyme-1 ferricytochromes c. Under the conditions employed in this work, the stoichiometry of the predominant complex formed in solution (which totaled greater than 90% of complex formed) was found to be 1:1 in all cases. These studies have elucidated significant differences in the proton NMR absorption spectra and the one-dimensional nuclear Overhauser effect difference spectra of the complexes, depending on the specific species of ferricytochrome c incorporated. In particular, the results indicate that the noncovalent complexes formed between CcP and physiological redox partners (yeast isozyme-1 or yeast isozyme-2 ferricytochromes c) are distinctly different from the noncovalent complexes formed between CcP and ferricytochromes c from horse and tuna. Parallel chemical cross-linking studies carried out using mixtures of cytochrome c peroxidase with horse ferricytochrome c, and cytochrome c peroxidase with yeast isozyme-1 ferricytochrome c further emphasize such cytochrome c-dependent differences, with only the covalently cross-linked complex of physiological redox partners (cytochrome c peroxidase/yeast isozyme-1) displaying NMR spectra characteristic of a heterogeneous mixture of different 1:1 complexes. Finally, one-dimensional nuclear Overhauser effect experiments have proven valuable in selectively and efficiently probing the protein-protein interface in these complexes, including the environment around the cytochrome c heme 3-methyl group and Phe-82.     

Effect of chemical modifications of tryptophan residues on the folding of reduced hen egg-white lysozyme

The effects of chemical modifications of Trp62 and Trp108 on the folding of hen egg-white lysozyme from the reduced form were investigated by means of the sulfhydryl-disulfide interchange reaction at pH 8 and 40 degrees C. The folding of reduced lysozyme was monitored by following the recovery of the original activity. Under the conditions employed, the apparent first-order rate constant for the folding of reduced lysozyme was not changed by the modifications of both Trp62 and Trp108 and the folding was completed within 30 min. However, the extent of the correct folding was changed by the modification of Trp62 but not by that of Trp108. Native and oxindolealanine108 lysozymes recovered 80 and 81% of their original activities after 30-min refolding, respectively, but Trp62-modified lysozymes recovered their activities to a lesser extent than native and oxindolealanine108 lysozymes. The recovered activities of Trp62-modified lysozymes after 30-min refolding were 63% for oxindolealanine62 lysozyme, 65% for delta 1-carboxamidomethylthiotryptophan62 lysozyme, and 52% for delta 1-carboxymethylthiotryptophan62 lysozyme. These results suggest that Trp62 is important for preventing the misfolding of reduced lysozyme, but that neither Trp62 nor Trp108 is involved in the rate-determining step (the slowest step) in the folding pathway. A decrease in the hydrophobic nature of Trp62 seems to increase the misfolding and thus to decrease the extent of the correct folding of reduced lysozyme. A mechanism for the involvement of Trp62 in the folding pathway of reduced lysozyme is proposed.     

Redox-related conformational changes in Rhodobacter capsulatus cytochrome c2

WEFT-NOESY and transfer WEFT-NOESY NMR spectra were used to determine the heme proton assignments for Rhodobacter capsulatus ferricytochrome c2. The Fermi contact and pseudo-contact contributions to the paramagnetic effect of the unpaired electron in the oxidized state were evaluated for the heme and ligand protons. The chemical shift assignments for the 1H and 15N NMR spectra were obtained by a combination of 1H-1H and 1H-15N two-dimensional NMR spectroscopy. The short-range nuclear Overhauser effect (NOE) data are consistent with the view that the secondary structure for the oxidized state of this protein closely approximates that of the reduced form, but with redox-related conformational changes between the two redox states. To understand the decrease in stability of the oxidized state of this cytochrome c2 compared to the reduced form, the structural difference between the two redox states were analyzed by the differences in the NOE intensities, pseudo-contact shifts and the hydrogen-deuterium exchange rates of the amide protons. We find that the major difference between redox states, although subtle, involve heme protein interactions, orientation of the heme ligands, differences in hydrogen bond networks and, possible alterations in the position of some internal water molecules. Thus, it appears that the general destabilization of cytochrome c2, which occurs on oxidation, is consistent with the alteration of hydrogen bonds that result in changes in the internal dynamics of the protein.