Photoinduced Electron Transfer between CytochromecPeroxidase (D37K) and Zn-Substituted Cytochromec: Probing the Two-Domain Binding and Reactivity of the Peroxidase

Constraints on the Radical Cation Center of Cytochrome c Peroxidase for Electron Transfer from Cytochrome c

The tryptophan 191 cation radical of cytochrome c peroxidase (CcP) compound I (Cpd I) mediates long-range electron transfer (ET) to cytochrome c (Cc). Here we test the effects of chemical substitution at position 191. CcP W191Y forms a stable tyrosyl radical upon reaction with peroxide and produces spectral properties similar to those of Cpd I but has low reactivity toward reduced Cc. CcP W191G and W191F variants also have low activity, as do redox ligands that bind within the W191G cavity. Crystal structures of complexes between Cc and CcP W191X (X = Y, F, or G), as well as W191G with four bound ligands reveal similar 1:1 association modes and heme pocket conformations. The ligands display structural disorder in the pocket and do not hydrogen bond to Asp235, as does Trp191. Well-ordered Tyr191 directs its hydroxyl group toward the porphyrin ring, with no basic residue in the range of interaction. CcP W191X (X = Y, F, or G) variants substituted with zinc-porphyrin (ZnP) undergo photoinduced ET with Cc(III). Their slow charge recombination kinetics that result from loss of the radical center allow resolution of difference spectra for the charge-separated state [ZnP(+), Cc(II)]. The change from a phenyl moiety at position 191 in W191F to a water-filled cavity in W191G produces effects on ET rates much weaker than the effects of the change from Trp to Phe. Low net reactivity of W191Y toward Cc(II) derives either from the inability of ZnP(+) or the Fe-CcP ferryl to oxidize Tyr or from the low potential of the resulting neutral Tyr radical.

Binding of Yeast Cytochrome c to Forty-Four Charge-Reversal Mutants of Yeast Cytochrome c Peroxidase: Isothermal Titration Calorimetry

Previously, we constructed, expressed, and purified 46 charge-reversal mutants of yeast cytochrome c peroxidase (CcP) and determined their electronic absorption spectra, their reaction with H2O2, and their steady-state catalytic properties [ Pearl , N. M. et al. (2008) Biochemistry 47 , 2766 - 2775 ]. Forty-four of the mutants involve the conversion of either an aspartate or glutamate residue to a lysine residue, while two are positive-to-negative mutations, R31E and K149D. In this paper, we report on a calorimetric study of the interaction of each charge-reversal mutant (excluding the internal mutants D76K and D235K) with recombinant yeast iso-1 ferricytochrome c(C102T) (yCc) under conditions where only one-to-one yCc/CcP complex formation is observed. Thirteen of the 44 surface-site charge-reversal mutants decrease the binding affinity for yCc by a factor of 2 or more. Eight of the 13 mutations (E32K, D33K, D34K, E35K, E118K, E201K, E290K, E291K) occur within, or on the immediate periphery, of the crystallographically defined yCc binding site [ Pelletier , H. and Kraut , J. (1992) Science 258 , 1748 - 1755 ], three of the mutations (D37K, E98K, E209K) are slightly removed from the crystallographic site, and two of the mutations (D165K, D241K) occur on the "back-side" of CcP. The current study is consistent with a model for yCc binding to CcP in which yCc binds predominantly near the region defined by crystallographic structure of the 1:1 yCc-CcP complex, whether as a stable electron-transfer active complex or as part of a dynamic encounter complex.

Symmetrized photoinitiated electron flow within the [myoglobin:cytochrome b₅] complex on singlet and triplet time scales: energetics vs dynamics

We report here that photoinitiated electron flow involving a metal-substituted (M = Mg, Zn) myoglobin (Mb) and its physiological partner protein, cytochrome b5 (cyt b5) can be "symmetrized": the [Mb:cyt b5] complex stabilized by three D/E → K mutations on Mb (D44K/D60K/E85K, denoted MMb) exhibits both oxidative and reductive ET quenching of both the singlet and triplet photoexcited MMb states, the direction of flow being determined by the oxidation state of the cyt b5 partner. The first-excited singlet state of MMb ((1)MMb) undergoes ns-time scale reductive ET quenching by Fe(2+)cyt b5 as well as ns-time scale oxidative ET quenching by Fe(3+)cyt b5, both processes involving an ensemble of structures that do not interconvert on this time scale. Despite a large disparity in driving force favoring photooxidation of (1)MMb relative to photoreduction (δ(-ΔG(0)) ≈ 0.4 eV, M = Mg; ≈ 0.2 eV, M = Zn), for each M the average rate constants for the two reactions are the same within error, (1)k(f) > 10(8) s(-1). This surprising observation is explained by considering the driving-force dependence of the Franck-Condon factor in the Marcus equation. The triplet state of the myoglobin ((3)MMb) created by intersystem crossing from (1)MMb likewise undergoes reductive ET quenching by Fe(2+)cyt b5 as well as oxidative ET quenching by Fe(3+)cyt b5. As with singlet ET, the rate constants for oxidative ET quenching and reductive ET quenching on the triplet time scale are the same within error, (3)k(f) ≈ 10(5) s(-1), but here the equivalence is attributable to gating by intracomplex conversion among a conformational ensemble.

Distance-independent charge recombination kinetics in cytochrome c-cytochrome c peroxidase complexes: compensating changes in the electronic coupling and reorganization energies

Charge recombination rate constants vary no more than 3-fold for interprotein ET in the Zn-substituted wild type (WT) cytochrome c peroxidase (CcP):cytochrome c (Cc) complex and in complexes with four mutants of the Cc protein (i.e., F82S, F82W, F82Y, and F82I), despite large differences in the ET distance. Theoretical analysis indicates that charge recombination for all complexes involves a combination of tunneling and hopping via Trp191. For three of the five structures (WT and F82S(W)), the protein favors hopping more than that in the other two structures that have longer heme → ZnP distances (F82Y(I)). Experimentally observed biexponential ET kinetics is explained by the complex locking in alternative coupling pathways, where the acceptor hole state is either primarily localized on ZnP (slow phase) or on Trp191 (fast phase). The large conformational differences between the CcP:Cc interface for the F82Y(I) mutants compared to that the WT and F82S(W) complexes are predicted to change the reorganization energies for the CcP:Cc ET reactions because of changes in solvent exposure and interprotein ET distances. Since the recombination reaction is likely to occur in the inverted Marcus regime, an increased reorganization energy compensates the decreased role for hopping recombination (and the longer transfer distance) in the F82Y(I) mutants. Taken together, coupling pathway and reorganization energy effects for the five protein complexes explain the observed insensitivity of recombination kinetics to donor-acceptor distance and docking pose and also reveals how hopping through aromatic residues can accelerate long-range ET.

Application of high pressure laser flash photolysis in studies on selected hemoprotein reactions

This article focuses on the application of high pressure laser flash photolysis for studies on selected hemoprotein reactions with the objective to establish details of the underlying reaction mechanisms. In this context, particular attention is given to the reactions of small molecules such as dioxygen, carbon monoxide, and nitric oxide with selected hemoproteins (hemoglobin, myoglobin, neuroglobin and cytochrome P450(cam)), as well as to photo-induced electron transfer reactions occurring in hemoproteins (particularly in various types of cytochromes). Mechanistic conclusions based on the interpretation of the obtained activation volumes are discussed in this account.

Effect of single-site charge-reversal mutations on the catalytic properties of yeast cytochrome c peroxidase: evidence for a single, catalytically active, cytochrome c binding domain

Forty-six charge-reversal mutants of yeast cytochrome c peroxidase (CcP) have been constructed in order to determine the effect of localized charge on the catalytic properties of the enzyme. The mutants include the conversion of all 20 glutamate residues and 24 of the 25 aspartate residues in CcP, one at a time, to lysine residues. In addition, two positive-to-negative charge-reversal mutants, R31E and K149D, are included in the study. The mutants have been characterized by absorption spectroscopy and hydrogen peroxide reactivity at pH 6.0 and 7.5 and by steady-state kinetic studies using recombinant yeast iso-1 ferrocytochrome c (C102T) as substrate at pH 7.5. Many of the charge-reversal mutations cause detectable changes in the absorption spectrum of the enzyme reflecting increased amounts of hexacoordinate heme compared to wild-type CcP. The increase in hexacoordinate heme in the mutant enzymes correlates with an increase in H 2O 2-inactive enzyme. The maximum velocity of the mutants decreases with increasing hexacoordination of the heme group. Steady-state velocity studies indicate that 5 of the 46 mutations (R31E, D34K, D37K, E118K, and E290K) cause large increases in the Michaelis constant indicating a reduced affinity for cytochrome c. Four of the mutations occur within the cytochrome c binding site identified in the crystal structure of the 1:1 complex of yeast cytochrome c and CcP [Pelletier, H., and Kraut, J. (1992) Science 258, 1748-1755] while the fifth mutation site lies outside, but near, the crystallographic site. These data support the hypothesis that the CcP has a single, catalytically active cytochrome c binding domain, that observed in the crystal structures of the cytochrome c/CcP complex.

Crystal structure of the ascorbate peroxidase-ascorbate complex

Heme peroxidases catalyze the H2O2-dependent oxidation of a variety of substrates, most of which are organic. Mechanistically, these enzymes are well characterized: they share a common catalytic cycle that involves formation of a two-electron, oxidized Compound I intermediate followed by two single-electron reduction steps by substrate. The substrate specificity is more diverse--most peroxidases oxidize small organic substrates, but there are prominent exceptions--and there is a notable absence of structural information for a representative peroxidase-substrate complex. Thus, the features that control substrate specificity remain undefined. We present the structure of the complex of ascorbate peroxidase-ascorbate. The structure defines the ascorbate-binding interaction for the first time and provides new rationalization of the unusual functional features of the related cytochrome c peroxidase enzyme, which has been a benchmark for peroxidase catalysis for more than 20 years. A new mechanism for electron transfer is proposed that challenges existing views of substrate oxidation in other peroxidases.

Yeast cytochrome c peroxidase: mechanistic studies via protein engineering

Cytochrome c peroxidase (CcP) is a yeast mitochondrial enzyme that catalyzes the reduction of hydrogen peroxide to water by ferrocytochrome c. It was the first heme enzyme to have its crystallographic structure determined and, as a consequence, has played a pivotal role in developing ideas about structural control of heme protein reactivity. Genetic engineering of the active site of CcP, along with structural, spectroscopic, and kinetic characterization of the mutant proteins has provided considerable insight into the mechanism of hydrogen peroxide activation, oxygen-oxygen bond cleavage, and formation of the higher-oxidation state intermediates in heme enzymes. The catalytic mechanism involves complex formation between cytochrome c and CcP. The cytochrome c/CcP system has been very useful in elucidating the complexities of long-range electron transfer in biological systems, including protein-protein recognition, complex formation, and intracomplex electron transfer processes.

Structure-function relationships in Anabaena ferredoxin/ferredoxin:NADP(+) reductase electron transfer: insights from site-directed mutagenesis, transient absorption spectroscopy and X-ray crystallography

The interaction between reduced Anabaena ferredoxin and oxidized ferredoxin:NADP(+) reductase (FNR), which occurs during photosynthetic electron transfer (ET), has been investigated extensively in the authors' laboratories using transient and steady-state kinetic measurements and X-ray crystallography. The effect of a large number of site-specific mutations in both proteins has been assessed. Many of the mutations had little or no effect on ET kinetics. However, non-conservative mutations at three highly conserved surface sites in ferredoxin (F65, E94 and S47) caused ET rate constants to decrease by four orders of magnitude, and non-conservative mutations at three highly conserved surface sites in FNR (L76, K75 and E301) caused ET rate constants to decrease by factors of 25-150. These residues were deemed to be critical for ET. Similar mutations at several other conserved sites in the two proteins (D67 in Fd; E139, L78, K72, and R16 in FNR) caused smaller but still appreciable effects on ET rate constants. A strong correlation exists between these results and the X-ray crystal structure of an Anabaena ferredoxin/FNR complex. Thus, mutations at sites that are within the protein-protein interface or are directly involved in interprotein contacts generally show the largest kinetic effects. The implications of these results for the ET mechanism are discussed.

Cytochrome c binding to Apaf-1: the effects of dATP and ionic strength

In the apoptosis pathway in mammals, cytochrome c and dATP are critical cofactors in the activation of caspase 9 by Apaf-1. Until now, the detailed sequence of events in which these cofactors interact has been unclear. Here, we show through fluorescence polarization experiments that cytochrome c can bind to Apaf-1 in the absence of dATP; when dATP is added to the cytochrome c.Apaf-1 complex, further assembly occurs to produce the apoptosome. These findings, along with the discovery that the exposed heme edge of cytochrome c is involved in the cytochrome c.Apaf-1 interaction, are confirmed through enhanced chemiluminescence visualization of native PAGE gels and through acrylamide fluorescence quenching experiments. We also report here that the cytochrome c.Apaf-1 interaction depends highly on ionic strength, indicating that there is a strong electrostatic interaction between the two proteins.

Self-assembled complexes of oligopeptides and metalloporphyrins: measurements of the reorganization and electronic interaction energies for photoinduced electron-transfer reactions

Cationic porphyrins form ground state electrostatically associated complexes with anionic oligo-electrolytes such as those formed by a series of glutamic acid (E) residues. Temperature dependencies were measured of the rate constants for intra-complex electron transfer to the triplet state of Pd(II)TMPyP4+ from a tyrosine (tyr, Y) or tryptophan (trp, W) moiety connected to a glutamic acid tetramer. In complexes such as YE4, E2YE2, YE4G10E (G, glycine), and WE4 these data were used to estimate the reorganization energy (lambda) and electronic interaction energy (HDA) relevant to the process. For all tyr-peptide complexes, lambda values were found to be large (lambda approximately 1.60 +/- 0.06 eV), reflecting a relatively high medium polarity in the vicinity of tyr residues. It further indicates that the tyr residues in all oligo-peptides are exposed to the aqueous medium in a similar way irrespective of the position of the aromatic moiety in the peptide chain. A significantly lower lambda value (lambda = 1.08 eV) was derived for the tryptophan-containing peptide complex, indicating a relatively higher hydrophobic character of trp compared to tyr. The electronic coupling matrix elements (HDA) derived for tyr-peptide complexes (5.1 meV for YE4, 5.4 meV for YE4G10E and 7.5 meV for E2YE2) were larger than that found for WE4 (1.1 meV). Molecular dynamics calculations were employed to obtain structural features of the porphyrin-peptide complexes. These showed average distances between the center of mass (COM) of the porphyrin ring and the center of mass of the amino acid aromatic ring of 816 +/- 140 pm (YE4), 800 +/- 80 pm (E2YE2), 900 +/- 130 pm (YE4G10E) and 970 +/- 160 pm (WE4). The molecular dynamics calculations were shown to be in good agreement with the experimentally determined electronic interaction energies, strongly suggesting that HDA is primarily responsible for the dependence of the electron-transfer rate constant (KET) on the donor-acceptor separation distance and relative orientation. The higher HDA (7.55 meV) derived for tyr incorporated into the middle of the peptide backbone (E2YE2) was presumed to be associated with a higher degree of orbital overlap due to a more favorable ring-ring orientation. Overlap parameters (beta derived for all peptide-porphyrin complexes were similar (approximately 0.95 +/- 0.06 A-1), being in good agreement with most literature values for similar systems. Finally, the intra-complex electron-transfer ratio (ktrp/ktyr) derived from flash photolysis experiments and the corresponding ratio derived from Marcus' theory combined with experimental data from the temperature-dependence investigations and electrochemical measurements were found to be in excellent agreement. This same consistency was found for the couple E4Y and E2YE2. The empirical expression (Moser and Dutton) governing the intraprotein electron-transfer rate constant in native systems combined with our experimental data (kET, lambda, delta G0) yielded tunneling pathway distances in excellent agreement with those arising from the molecular modeling studies. The exception was for the long peptide YE4G10E, for which the Quenched Molecular Dynamic (QMD) sampling technique was complicated and is probably inadequate.