The oxygen reactions of reduced cytochrome c oxidase. Position of a form with an unusual EPR signal in the sequence of early intermediates.

The order of appearance of intermediates in the reoxidation of reduced cytochrome c oxidase by oxygen has been examined. Particular emphasis was placed on determining where the intermediate with the EPR signal at g = 5, 1.78, 1.69 (Shaw, R.W., Hansen, R.E. and Beinert, H. (1978) J. Biol. Chem. 253, 6637--6640) appears in the sequence of events during reoxidation. Flash photolysis of reduced, CO-complexed samples of cytochrome c oxidase in the presence of oxygen in a buffer containing 30% (v/v) ethylene glycol at 77 K and 195 K has been used to generate states of partial reoxidation. The intermediate with the EPR signal at g = 5, 1.78, and 1.69 can be detected as a product of the photolysis and subsequent oxidation but does not appear until the photolyzed sample is incubated at temperatures well above 196 K. In the course of the reoxidation, the intermediate characterized by the g = 5, 1.78, 1.69 signal occurs in the reaction sequence after the states referred to as 'Compound A' and 'Compound B' (Chance, B., Saronio, C., and Leigh, J.S. (1975) J. Biol. Chem. 250, 9226--9237). Its appearance is within the time range reported for the formation of 'oxygenated' cytochrome c oxidase (Orii, Y. (1979) in Cytochrome Oxidase (King, T.E., Orii, Y., Chance, B. and Okunuki, K., eds.), pp. 331--340, Elsevier/North-Holland Biomedical Press, Amsterdam).     

Cytochrome c oxidase. Time dependence of optical and EPR spectral changes related to the ‘oxygen-pulsed’ form

Time-dependent changes in the optical spectrum (450–920 nm) of cytochrome c oxidase, following oxidation with oxygen of the stoichiometrically reduced form, have been investigated and where possible, attempts have been made to correlate our observations with variations in the EPR spectrum over a parallel time course at 2°C. In this regard, particular emphasis has been placed on establishing absorption features related to the presence of EPR resonances at g 5, 1.78 and 1.69, which have been tentatively assigned to a spin-coupled state involving cytochrome a₃ and ‘EPR-undetectable Cu’ (Beinert, H., Shaw, R.W., Dunham, R.W. and Sands, R.H. (1982) in Oxidases and Related Redox Systems (King, T.E., Mason, H.S. and Morrison, M., eds.), Pergamon Press, Oxford, in the press). For optical studies we have used a versatile rapid-scanning spectrophotometer to obtain well resolved spectra down to 2 ms reaction time. Concomitant with the appearance (within 10 ms) of EPR signals at g 5, 1.78 and 1.69 is the presence of an enhanced absorption (Δε = 0.25 mM (heme a)^?1·cm^?1) at 660 nm, with a trough (relative to following spectra) at 580 nm. In our hands, this feature disappears in a first-order process with a half-life of 46 s at pH 7.2 and 2°C. The effect of this spectral transformation is to decrease considerably the acuteness of the 655 nm absorption band, previously suggested as representing a state of the enzyme in which ferric cytochrome a₃ is coupled to oxidised EPR-undetectable Cu (Beinert, H., Hansen, R.E. and Hartzell, C.R. (1976) Biochim. Biophys. Acta 423, 339–355). This observation can be correlated satisfactorily with a small field shift of the high-field resonances at g 1.78 and 1.69 and a broadening at g 1.78. Support for this and further correlative assignments arises from parallel experiments using cytochrome c oxidase purified via an alternative procedure, which displays different kinetic behavior. Further transformations of the oxidized enzyme are evident through an approx. 10% decrease in absorbance at 600 nm together with small changes centered at 640 and 665 nm (which serve to restore the sharpness of the 655 nm band). The kinetics, as analyzed by the Guggenheim procedure using the absorbance at 597 nm, indicate approx. 50% first-order linearity (half-life 40 min) with additional species contributing at longer times, while over a parallel time course (0–3 h) the EPR resonances at g 5, 1.78 and 1.69 virtually disappear. These novel signals can also be seen at a lower intensity in samples of cytochrome c oxidase anaerobically reoxidized by porphyrexide and frozen after a 6 min incubation period at 4°C. This observation, along with the establishment of similar optical changes over the time course of 1 min to 3 h, suggests that aerobic and anaerobic reoxidation produce common forms of the enzyme. Comparison of the g 1.78 and 1.69 resonances between samples rapidly aerobically reoxidized in the presence of H₂¹⁶O and H₂¹⁷O yielded no evidence for the presence of any labile oxygen ligand (including OH^?, H₂O) in the coordination sphere of the species involved.     

Heme-heme interaction in cytochrome c oxidase: the cooperativity of the hemes of cytochrome c oxidase as evidenced in the reaction with CO

Isolated and purified cytochrome c oxidase from beef heart muscle mitochondria (Kuboyama et al. (1972) J. Biol. Chem.247, 6375–6383) is shown to be very similar to the hemoprotein in situ with respect to its EPR absorption properties and the half-reduction potentials of the hemes and copper. The half-reduction potentials of cytochromes a and a₃ in the purified cytochrome c oxidase are 205 mV and 360 mV, respectively, and these values are the same in the presence and absence of cytochrome c.Low-temperature EPR spectra show that the binding of CO to reduced cytochrome a₃ changes the oxidized cytochrome a from high spin (g 6) to low spin (g 3). In samples at 5–8 °K the photodissociation of the reduced cytochrome a₃CO compound shifts the spectrum of the oxidized low-spin cytochrome a to a lower g value and converts approximately 5% of the low-spin form to a high-spin form. The heme-heme interaction demonstrated in this reaction is very fast as evidenced by the fact that even at 5 °K the measured change in oxidized cytochrome is complete within 5 msec.     

Kinetic studies on cytochrome c oxidase by combined EPR and reflectance spectroscopy after rapid freezing

1. Techniques and experiments are described concerned with the millisecond kinetics of EPR-detectable changes brought about in cytochrome c oxidase by reduced cytochrome c and, after reduction with various agents, by reoxidation with O₂ or ferricyanide. Some experiments in the presence of ligands are also reported. Light absorption was monitored by low-temperature reflectance spectroscopy.2. In the rapid phase of reduction of cytochrome c oxidase by cytochrome c (< 50 ms) approx. 0.5 electron equivalent per hame a is transferred mainly to the low-spin heme component of cytochrome c oxidase and partly to the EPR-detectable copper. In a slow phase (> 1 s) the copper is reoxidized and high-spin ferric heme signals appear with a predominant rhombic component. Simultaneously the absorption band at 655 nm decreases and the Soret band at 444 nm appears between the split Soret band (442 and 447 nm) of reduced cytochrome a.3. On reoxidation of reduced enzyme by oxygen all EPR and optical features are restored within 6 ms. On reoxidation by O₂ in the presence of an excess of reduced cytochrome c, states can be observed where the low-spin heme and copper signals are largely absent but the absorption at 655 nm is maximal, indicating that the low-spin heme and copper components are at the substrate side and the component(s) represented in the 655 nm absorption at the O₂ side of the system. On reoxidation with ferricyanide the 655 nm absorption is not readily restored but a ferric high-spin heme, represented by a strong rhombic signal, accumulates.4. On reoxidation of partly reduced enzyme by oxygen, the rhombic high-spin signals disappear within 6 ms, whereas the axial signals disappear more slowly, indicating that these species are not in rapid equilibrium. Similar observations are made when partly reduced enzyme is mixed with CO.5. The results of this and the accompanying paper are discussed and on this basis an assignment of the major EPR signals and of the 655 nm absorption is proposed, which in essence is that published previously (Hartzell, C. R., Hansen, R. E. and Beinert, H. (1973) Proc. Natl. Acad. Sci. U.S. 70, 2477–2481). Both the low-spin (g = 3; 2.2; 1.5) and slowly appearing high-spin (g = 6; 2) signals are attributed to ferric cytochrome a, whereas the 655 nm absorption is thought to arise from ferric cytochrome a₃, when it is present in a state of interaction with EPR-undetectable copper. Alternative possibilities and possible inconsistencies with this proposal are discussed.     

Reactivity of photoreduced cytochrome aa3 complexes with molecular oxygen.

Cytochrome c oxidase (ox heart cytochrome aa3) is reduced on illumination in the presence of a photocatalyst system containing deazaflavin and EDTA. The photo-reduced enzyme reacts with oxygen at neutral pH to give a form of ferric enzyme, whereas a corresponding sample partially reduced by light in the absence of any photocatalyst reacts with oxygen to give an oxyferri species ('oxygenated' enzyme). Reduction by the photocatalyst system at an alkaline pH value (9.0) also gives rise to fully reduced oxidase (both haem groups ferrous). At these pH values the immediate product after oxygen addition is a species with a 605-606 nm absorption band, not identical with ferrous cytochrome a, but capable of oxidizing added cytochrome c. This intermediate, which is unstable at neutral pH, may be analogous to the 'compound B' obtained by Chance and co-workers [Chance, Saronio & Leigh (1975) J. Biol. Chem. 250, 9226-9237; Chance, Saronio & Leigh (1979) Biochem. J. 177, 931-941] at low temperatures.     

Cross-linking studies on a cytochrome c-cytochrome c oxidase complex.

A cytochrome $\text{c}$ - cytochrome $\text{c}$ oxidase complex containing 0.8–1.0 moles of cytochrome $\text{c}$ per mole of cytochrome $\text{c}$ oxidase (heme a + a₃) was isolated as described by Ferguson-Miller, S., Brautigan, D.L., and Margoliash E., J. Biol. Chem. $\text{251}$, 1104 (1976). This complex was reacted with dithiobissuccinimidyl propionate, an 11 Å bridging bifunctional reagent, and the cross-linked products obtained were analyzed by two dimensional gel electrophoresis. Cytochrome $\text{c}$ was cross-linked to subunit II of cytochrome $\text{c}$ oxidase. Other cross-linked products were formed involving different subunits of cytochrome $\text{c}$ oxidase. These included I+V, II+V, III+V, V+VII, IV+VI and IV+VII. Experiments are also described using N,N′-bis(3-succinimidyloxycarbonylpropyl) tartarate. The major product formed with this 18 Å bridging bifunctional reagent was a pair containing II+VI.     

Peroxide interaction with pulsed cytochrome oxidase. Optical and EPR studies

EPR and optical analysis of the 420 nm form of cytochrome oxidase (Kumar, C., Naqui, A., and Chance, B. (1984) J. Biol. Chem. 259, 2073-2076) shows that 1) the 420 nm form possesses a 605 nm band, g = 5 EPR signals, and a slightly blue shifted 655 nm band; 2) the reaction of H2O2 with the 420 nm form generates the peroxide complex (Soret band at 427 nm) with the formation of a 580 nm band and abolition of both the 655 nm band and the g = 5 EPR signal. Comparison of our results with past data shows that various forms of oxidase formed from the resting oxidase through different protocols may be identified to be either the 420 nm or the 427 nm form and leads to identification of a peroxy intermediate during oxidase turnover.     

A re-evaluation of the low-temperature kinetics of the reaction of fully reduced mitochondrial cytochrome oxidase with carbon monoxide and the spectral characterization of species Ic in the Soret and visible regions

The kinetics of the reaction of fully reduced membrane bound cytochrome oxidase with CO following photolysis of the fully reduced cytochrome oxidase-CO complex habe been re-examined by re-analysing the data of Clore and Chance (1978) Biochem. J. 175, 709-725) at six temperatures in the 178-203 K range simultaneously at only a single wavelength pair, 444-463 nm. The choice of the 444-463 nm wavelength pair was based on the fact that the absorbance change produced at 444-463 nm on photolysis of the CO complex is sufficiently large and the separation between monitoring and reference wavelengths sufficiently small to render the effects of any possible time dependent scattering changes insignificant. On the basis of our analysis only a two step mechanism (Model 1 of Clore and Chance (1978) Biochem. J. 175, 709-725) satisfies the triple requirement of a S.D. within the standard error of the data, a random distribution of residuals and good determination of the optimized parameters. The single step mechanism of De Fonseka and Chance (1978) Biochem. J. 175, 1137-1138) fails to satisfy all three requirements. The pure difference spectra of species Ic minus E, E minus IIc and Ic minus IIc are calculated from the computed kinetics of the individual species and repetitive slow wavelength scanning difference spectra (reaction sample minus the CO complex) taken during the course of the reaction of fully reduced cytochrome oxidase with CO at 176 K.     

Studies on the origin of the near-infrared (800–900 nm) absorption of cytochrome c oxidase

Data are presented which were collected in the course of the past ten years and bear on the correlation of absorbance at 800 nm and the EPR signal at g = 2 (‘copper signal’) of cytochrome c oxidase in various states of oxidation and ligation. Both EPR and optical reflectance spectra were obtained at low temperature (?170 to ?190°C). For some sets of samples spectra were recorded in the range 500–1100 nm. A particular effort was made to study this correlation with what are called ‘mixed valence’ states (Greenwood, C., Wilson, M.T. and Brunori, M. (1974) Biochem. J. 137, 205–215), when cytochrome a and the EPR-detectable copper are thought to be oxidized and the other components reduced and vice versa. These data show no evidence that the copper component of cytochrome oxidase which has so far not been detected by EPR makes a contribution to the absorption between 800 and 900 nm exceeding 10–15% of the total, which is close to or within the error of the respective measurements. For the various states of the oxidase examined in this work the 700–800 nm region did not appear to be more useful than the 800–900 nm region for determining the state of the EPR-undetectable copper in a reliable way. These conclusions are in agreement with results presented previously from other laboratories concerning the relationship of optical (approx. 800 nm) and EPR spectroscopic (g = 2) data obtained with the enzyme.     

Biochemical and biophysical studies on cytochrome c oxidase. XVII. An epr study of the photodissociation of cytochrome a32+ · CO

1. The photodissociation reaction of the cytochrome c oxidase-CO compound was studied by EPR at 15 °K. Illumination with white light at both room and liquid N₂ temperatures of the partially reduced cytochrome c oxidase (2 electrons per 4 metals) in the presence of CO, causes the appearance of a rhombic (g_x = 6.60, g_y = 5.37) high-spin heme signal.This signal disappears completely upon darkening of the sample and reappears upon illumination at room temperature; accordingly the photolytic process is reversible. Under these conditions, no great changes in the intensities are observed, neither of the copper signal at g = 2, nor of the low-spin heme signal at g = 3, 2.2 and 1.5.2. In the presence of ferricyanide (2 mM) and CO, both the low-spin heme signal (g = 3.0, 2.2 and 1.5) and the copper signal of the partially reduced enzyme have intensities about equal to those of the completely oxidized enzyme in the absence of CO. Upon illumination of the carboxy-cytochrome c oxidase in the presence of ferricyanide, it was found that the rhombic high-spin heme signal appears without affecting appreciably the copper of low-spin heme signals. Thus, in the presence of ferricyanide the EPR-detectable paramagnetism of the illuminated carboxy-cytochrome c oxidase is higher than in the untreated oxidized enzyme.3. The membrane-bound cytochrome c oxidase reduced with NADH in the presence of CO and subsequently oxidized with ferricyanide shows a similar rhombic high-spin heme signal (g_x = 6.62, g_y = 5.29) upon illumination at room temperature. This signal disappears completely upon darkening and reappears upon illumination at room temperature.     

Oxido-reductive titrations of cytochrome c oxidase followed by EPR spectroscopy

Experiments are described on oxido-reductive titrations of cytochrome c oxidase as followed by low-temperature EPR and reflectance spectroscopy. The reductants were cytochrome c or NADH and the oxidant ferricyanide. Experiments were conducted in the presence and absence of either cytochrome c or carbon monoxide, or both. An attempt is made to provide a complete quantitative balance of the changes observed in the major EPR signals. During reduction, the maximal quantity of heme represented in the high-spin ferric heme signals (g ～ 6; 2) is 25% of the total heme present, and during reoxidation 30%. With NADH reduction there is little difference between the pattern of disappearance of the low-spin ferric heme signals in the absence or presence of cytochrome c. The copper and high-spin heme signals, however, disappear at higher titrant concentrations in the presence of cytochrome c than in its absence. In these titrations, as well as in those with ferrocytochrome c, the quantitative balance indicates that, in addition to EPR-detectable components, EPR-undetectable components are also reduced, increasingly so at higher titrant concentrations. The quantity of EPR-undetectable components reduced appears to be inversely related to pH. A similar inverse relationship exists between pH and appearance of high-spin signals during the titration. At pH 9.3 the quantity of heme represented in the high-spin signals is < 5%, whereas it approximately doubles from pH 7.4 to pH 6.1. In the presence of CO less of the low-spin heme and copper signals disappears for the same quantity of titrant consumed, again implying reduction of EPR undetectable components. At least one of these components is represented in a broad absorption band centered at 655 nm. The stoichiometry observed on reoxidation, particularly in the presence of CO, is not compatible with the notion that the copper signal represents 100% of the active copper of the enzyme as a pair of interacting copper atoms.     

An infrared study of the binding and photodissociation of carbon monoxide in cytochrome ba3 from Thermus thermophilus

The C-O stretching frequencies of fully reduced carbonmonoxy cytochrome ba3, a newly discovered terminal oxidase of the bacterium Thermus thermophilus (Zimmermann, B.H., Nitsche, C.I., Fee, J.A., Rusnak, F., and Münck, E. (1988) Proc. Natl. Acad. Sci. U.S. A. 85, 5779-5783), are studied by Fourier transform infrared spectroscopy. Multiple C-O frequencies are observed in the Fourier transform infrared spectra, indicating the presence of discrete interconverting conformers of the enzyme. Upon photolysis, the CO is shown to migrate exclusively to CuB+. Above 200 K, the CO returns to the heme a3 by a thermal process which follows simple first-order kinetics. The rate of the reaction was studied from 205 to 230 K and at 300 K, yielding the activation parameters delta H = 14.9 kcal/mol and delta S = -5 cal/mol/K. These are compared with previously determined activation parameters for CO recombination in mitochondrial cytochrome aa3 preparations (Fiamingo, F.G., Altschuld, R.A., Moh, P.P., and Alben, J.O. (1982) J. Biol. Chem. 257, 1639-1650). We report the novel finding that CO remains bound to CuB+ at room temperature during continuous photolysis of cytochrome ba3, and we conjecture on the possible interference of copper-bound CO in "flow-flash" and "triple-trap" studies of cytochrome c oxidases.     

Redox state of respiratory chain enzymes and potassium transport in silkworm mid-gut

The midgut of Hyalophora cecropia actively transports potassium from hemolymph to lumen and the energy for this process appears to be intimately linked to oxidative metabolism. In the present investigation, we monitored concurrently the rate of active transport and the redox levels of the components of the respiratory chain in the intact tissue under a variety of experimental conditions. Approximately equal concentrations of cytochromes a₃, a, c and b-557 were found. Other investigators (Pappenheimer, Jr, A. M. and Williams, C. M. (1954) J. Biol. Chem. 209, 915, Shappirio, D. G. and Williams, C. M. (1957) Proc. R. Soc. Lond. Ser. B 147, 233 and Chance, B. and Pappenheimer, Jr, A. M. (1954) J. Biol. Chem. 209, 931) have identified cytochrome b-557 with b₅ and found that it exists primarily in an extramitochondrial location.Steady-state experiments demonstrated that all these cytochromes were approximately 50% reduced while active transport proceeded at a high rate in regular cecropia Ringer containing 32 mM KCl. When the potassium concentration was reduced, the active transport decreased and all the cytochromes became more oxidized. Addition of 1 mM cyanide inhibited active transport by 90% and caused a 100% reduction of all cytochromes. Redox state and short circuit current (I_sc) kinetics measured as the tissue was made anoxic showed that all the respiratory enzymes, except cytochrome b-557, became fully reduced at a faster rate than the rate of inhibition of the I_sc. The rate of cytochrome b-557 reduction followed kinetically the I_sc.These observations are interpreted in a scheme where cytochrome b-557 (possibly b₅) branches off cytochrome c from the conventional respiratory chain, utilizing cytochrome a₃ as the terminal oxidase for both branches. Cytochrome b-557 may be involved in providing a direct link between oxidative metabolism and active transport in the midgut of the silkworm.     

Structure and reactivity of multiple forms of cytochrome oxidase as evaluated by X-ray absorption spectroscopy and kinetics of cyanide binding

The extended X-ray absorption fine structure (EXAFS) data show differences between the active site structures of different cytochrome oxidase preparations. In the resting (as isolated) state of the Yonetani preparation, the bridging atom between Fe3+a3 and Cu2+a3 is present [Powers, L., Chance, B., Ching, Y., & Angiolillo, P. (1981) Biophys. J. 34, 465], whereas in another preparation (e.g., Hartzell-Beinert), this atom seems to be bound only to Fe3+a3 in a significant fraction of the molecules. Both preparations bind cyanide in a multiphasic fashion, suggesting that the resting cytochrome oxidase is not homogeneous but rather is a mixture of several forms. The proportion of these forms as detected by cyanide binding kinetics differs for different preparations. However, upon reduction and reoxidation (conversion to the "oxygenated" form) the cyanide binding kinetics become monophasic and all preparations of the oxygenated form bind cyanide at the same rate. Thus, a combination of structural and kinetic approaches seems necessary for evaluation of the nature of the active site of cytochrome oxidase in its various forms.     

The influence of pH on the EPR and redox properties of cytochrome c oxidase in detergent solution and in phospholipid vesicles

The EPR signals of oxidized and partially reduced cytochrome oxidase have been studied at pH 6.4, 7.4, and 8.4. Isolated cytochrome oxidase in both non-ionic detergent solution and in phospholipid vesicles has been used in reductive titrations with ferrocytochrome c.The g values of the low- and high-field parts of the low-spin heme signal in oxidized cytochrome oxidase are shown to be pH dependent. In reductive titrations, low-spin heme signals at g 2.6 as well as rhombic and nearly axial high-spin heme signals are found at pH 8.4, while the only heme signals appearing at pH 6.4 are two nearly axial g 6 signals. This pH dependence is shifted in the vesicles.The g 2.6 signals formed in titrations with ferrocytochrome c at pH 8.4 correspond maximally to 0.25–0.35 heme per functional unit (aa₃) of cytochrome oxidase in detergent solution and to 0.22 heme in vesicle oxidase. The total amount of high-spin heme signals at g 6 found in partially reduced enzyme is 0.45–0.6 at pH 6.4 and 0.1–0.2 at pH 8.4. In titrations of cytochrome oxidase in detergent solution the g 1.45 and g 2 signals disappear with fewer equivalents of ferrocytochrome c added at pH 8.4 compared to pH 6.4.The results indicate that the environment of the hemes varies with the pH. One change is interpreted as cytochrome a₃ being converted from a high-spin to a low-spin form when the pH is increased. Possibly this transition is related to a change of a liganded H₂O to OH^? with a concomitant decrease of the redox potential. Oxidase in phosphatidylcholine vesicles is found to behave as if it experiences a pH, one unit lower than that of the medium.     

Heme c - heme d1 interaction in Pseudomonas cytochrome oxidase (nitrite reductase): a reappraisal of the spectroscopic evidence.

Magnetic circular dichroism (MCD) spectra of Pseudomonas aeruginosa cytochrome oxidase are reported over the spectral range of 350–700 nm for the oxidized, ascorbate-reduced, dithionite-reduced and reduced carbon monoxide forms. The spectra of all forms examined can be interpreted as the simple sum of the individual heme c and heme d₁ contributions without invoking “heme-heme interaction.” In particular and contrary to a recent report [Orii, Shimada, Nozawa, and Hatano, this Journal $\text{76}$, 983 (1977)] no effect of ligand binding to ferrous heme d₁ was observed in the MCD spectrum of the heme c component. It seems likely that the previous findings were the result of incomplete reduction of the enzyme in the absence of stabilizing ligands.     

Reduction of oxygen-pulsed cytochrome c oxidase by cytochrome c and other electron donors

1. Stopped-flow experiments were performed in which solutions containing dithionite were mixed with air-saturated buffer. Cytochrome c oxidase present in the dithionite-containing syringe is fully oxidized within the mixing time and the oxygen-pulsed form of the oxidase is produced.2. The reduction of this form by dithionite, by dithionite plus cytochrome c and by dithionite plus methyl viologen or benzyl viologen was followed and compared with the corresponding reduction reactions of the ‘resting’ oxidized enzyme. Reduction by dithionite is relatively slow, but the rate of reduction is greatly increased by addition of cytochrome c or the viologens, which are even more effective than cytochrome c on a molar basis.3. Profound differences between the transient kinetics of the reduction of the two oxidized oxidase derivatives were observed. The results are consistent with a direct reduction of cytochrome a followed by an intramolecular electron transfer to cytochrome a₃ (k^obs₁ = 7.5 s^?1 for the oxygen-pulsed oxidase).4. The spectrum of the oxygen-pulsed oxidase formed within 5 ms of the mixing closely resembles that of the ‘oxygenated’ compound, but there were small differences between the two spectra.     

Photosystem I charge separation in the absence of centers A and B. II. ESR spectral characterization of center ‘X’ and correlation with optical signal ‘A2’

The Photosystem I electron acceptor complex was characterized by optical flash photolysis and electron spin resonance (ESR) spectroscopy after treatment of a subchloroplast particle with lithium dodecyl sulfate (LDS). The following properties were observed after 60 s of incubation with 1% LDS followed by rapid freezing. (i) ESR centers A and B were not observed during or after illumination of the sample at 19 K, although the P-700⁺ radical at g = 2.0026 showed a large, reversible light-minus-dark difference signal. (ii) Center ‘X’, characterized by g factors of 2.08, 1.88 and 1.78, exhibited reversible photoreduction at 8 K in the absence of reduced centers A and B. (iii) The backreaction kinetics at 8 K between P-700, observed at g = 2.0026, and center X, observed at g = 1.78, was 0.30 s. (iv) The amplitudes of the reversible g = 2.0026 radical observed at 19 K and the 1.2 ms optical 698 nm transient observed at 298 K were diminished to the same extent when treated with 1% LDS at room temperature for periods of 1 and 45 min. We interpret the strict correlation between the properties and lifetimes of the optical P-700⁺ A⁻₂ reaction pair and the ESR P-700⁺ center X⁻ reaction pair to indicate that signal A₂ and center X represent the same iron-sulfur center in Photosystem I.