Cytochrome f and plastocyanin kinetics in Chlorella pyrenoidosa. I. Oxidation kinetics after a flash

P-700, plastocyanin and cytochrome f redox kinetics were measured after one flash, using dark-adapted Chlorella in the presence of hydroxylamine and 3(3,4-dichlorophenyl)-1,1-dimethylurea. Plastocyanin becomes increasingly oxidized with a half-time of 70 μs, then undergoes reduction with a half-time of 7 ms. Cytochrome f oxidation has a sigmoidal time-course and a half-time of 100 μs. Its reduction exhibits a half-time of 4 ms. These results are interpreted in a linear scheme:

An equilibrium constant of 2 between cytochrome f and plastocyanin (PC), which contrasts with the large equilibrium constant between PC and P-700 is computed.The presence of cytochrome b₆ in a cyclic path around Photosystem I is confirmed under these conditions.     

Effects of alcohol/water mixtures on the structure and reactivity of cytochrome c

The oxidation reaction of ferrocytochrome c (produced in situ by pulse radiolysis) by Fe(CN)^3?₆, was used to probe the effect of alcohol/water mixtures on the reactivity of the protein. Reduced cytochrome c is oxidized in a biphasic process. The relative contribution of each phase depended on: pH, alcohol concentration and temperature. pK_a values were derived from the kinetic data. These pK_a values were identical with the spectroscopic pK_a values determined under similar conditions by monitoring the 695 nm absorption band of the oxidized protein. The two phases of oxidation were therefore related to the oxidation of a relaxed and a nonrelaxed conformer of reduced cytochrome c produced in situ. A shift in the pK_a of ferricytochrome c and a retardation of the redox reactions of both the reduced and the oxidized protein were observed at low alcohol concentrations (up to 5 mol %). These low alcohol concentrations are known to affect the structure of water (Yaacobi, M. and Ben-Naim, A. (1973) J. Sol. Chem. 5, 425?443; Ben-Naim, A. (1967) J. Phys. Chem. 71, 4002?4007 and Ben-Naim, A. and Baer, S. (1964) Trans. Faraday Soc. 60, 1736?1741) but have only minor effects on the protein. Accordingly, the kinetic results are interpreted on the basis of involvement of water molecules in the reaction complex of cytochrome c with its redox substrates.     

The presence of EC collagen and type IV collagen in bovine Descemet's membranes

The inhibitory effect of antimycin A on the slow rise of the flash-induced electrochromic absorbance change was reinvestigated in intact chloroplasts isolated from pea leaves. It is show that in the absence of nigericin and ⁺K at low repetition rates (<0.5 s^?1) of the excitation flashes not only the slow (～ 10 ms) rise but also the initial (?1 ms) rise generated by photosystem 1 is inhibited by antimycin A.     

Fluorescence yield kinetics in the microsecond-range in Chlorella pyrenoidosa and spinach chloroplasts in the presence of hydroxylamine

The kinetics of fluorescence yield inChlorella pyrenoidosa and spinach chloroplasts were studied in the time range of 0.5 μs to several hundreds of microseconds in the presence of hydroxylamine. Fluorescence was excited with a just-saturating xenon flash with a halfwidth of 13 μs (λ = 420 nm). The fast rise of the fluorescence yield which was limited by the rate of light influx, was, in the presence of 10⁻³–10⁻² M hydroxylamine, replaced by a slow component which had a half risetime of 25 μs in essence independent of light intensity. This slow fluorescence yield increase reflects a dark reaction on the watersplitting side of Photosystem II. Simultaneous oxygen evolution measurements suggested that a fast fluorescence component is only present in organisms with intact O₂-evolving system, whereas a slow rise predominantly occurs in organisms with the watersplitting system irreversibly inhibited by hydroxylamine.

The results can be explained by the following hypotheses: (a) The primary donor of Photosystem II in its oxidized state, P⁺, is a fluorescence quencher. (b) Hydroxylamine prevents the secondary electron donor Z from reducing the oxidized reaction center pigment P⁺ rapidly. This inhibition is dependent on hydroxylamine concentration and is complete at a concentration of 10⁻² M. (c) A second donor (not transporting electrons from water) transfers electrons to P⁺ with a half time of roughly 25 μs.     

Kinetics of luminescence in the 10−6–10−4-s range in Chlorella

The decay of luminescence in the 6–600-μs range following a microsecond flash has been studied in Chlorella. The decay is highly polyphasic; three kinetic components are outlined, in confirmation of the results of K. L. Zankel (1971, Biochim. Biophys. Acta 245, 373–385).Extrapolation of the decay to zero dark time suggests that a unique metastable species C^?₊, resulting from photochemical charge separation in the System II reaction center, is the substrate of the recombination reaction which gives rise to luminescence.The fast (5–10 μs) and medium (50–70 μs) phases of the decay denote different stabilization steps, preceding relaxation of the centers by electron and proton transduction to the photosynthetic chain.NH₂OH specifically inhibits the fast phase and enhances the medium phase. This effect is explained by assuming that the fast phase results from electron transfer from the water splitting system Z to the oxidized primary donor Y.3-(3,4-Dichlorophenyl)-1,1-dimethylurea (DCMU), in the presence of NH₂OH elicits another fast phase. It is believed that DCMU affords a parasitic stabilization of C^?₊ by forming a complex with Q^?.     

Changes in photosynthetic activity in the cyanobacterium Chlorogloea fritschii following transition from dark to light growth

The cyanobacterium Chlorogloea fritschii loses Photosystem II activity, measured by delayed fluorescence and oxygen evolution, during dark heterotrophic growth, but retains Photosystem I, measured as light induced EPR signals. Following transition to the light, Photosystem II recovers in two stages, the first of which does not require protein synthesis. New Photosystem I reaction centres are not synthesised until after net chlorophyll synthesis has commenced. Carbon dioxide fixation recovery commences immediately, the initial rate being unaffected by chloramphenicol. The recovery of carbon dioxide fixation is not directly related to oxygen evolution rate and is only inhibited slightly by 3-(3,4-dichlorophyenyl)-1,1-dimethylurea and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone.     

The role of chloride ion in Photosystem II I. Effects of chloride ion on Photosystem II electron transport and on hydroxylamine inhibition

1. Chloroplasts washed with Cl^?-free, low-salt media (pH 8) containing EDTA, show virtually no DCMU-insensitive silicomolybdate reduction. The activity is readily restored when 10 mM Cl^? is added to the reaction mixture. Very similar results were obtained with the other Photosystem II electron acceptor 2,5-dimethylquinone (with dibromothymoquinone), with the Photosystem I electron acceptor FMN, and also with ferricyanide which accepts electrons from both photosystems.2. Strong Cl^?-dependence of Hill activity was observed invariably at all pH values tested (5.5–8.3) and in chloroplasts from three different plants: spinach, tobacco and corn (mesophyll).3. In the absence of added Cl^? the functionally Cl^?-depleted chloroplasts are able to oxidize, through Photosystem II, artificial reductants such as catechol, diphenylcarbazide, ascorbate and H₂O₂ at rates which are 4–12 times faster than the rate of the residual Hill reaction.4. The Cl^?-concentration dependence of Hill activity with dimethylquinone as an electron acceptor is kinetically consistent with the typical enzyme activation mechanism: E(inactive) + Cl^?ag E · Cl^? (active), and the apparent activation constant (0.9 mM at pH 7.2) is unchanged by chloroplast fragmentation.5. The initial phase of the development of inhibition of water oxidation in Cl^?-depleted chloroplasts during the dark incubation with NH₂OH ($\text{1}\text{2}$ H₂SO₄) is 5 times slower when the incubation medium contains Cl^? than when the medium contains NH₂OH alone or NH₂OH plus acetate ion. (Acetate is shown to be ineffective in stimulating O₂ evolution.)6. We conclude that the Cl^?-requiring step is one which is specifically associated with the water-splitting reaction, and suggests that Cl^? probably acts as a cofactor (ligand) of the NH₂OH-sensitive, Mn-containing O₂-evolving enzyme.     

Inhbition of photosystem II-dependent phosphorylation in chloroplasts by mercurials.

Photophosphorylation supported by the coupling site associated with Phostosystem II electron transport (coupling site II) is 50 to 60 times less sensitive to the energy transfer inhibitor HgCl₂ than phosphorylation supported by the coupling site associated with Photosystem I electron transport (coupling site I). Coupling site II phosphorylation is only about 2 times less sensitive to the lipophilic mercurial p-hydroxymercuribenzoate (PHMB), however. Both coupling sites are equally sensitive to CF₁ antiserum. These results suggest that a portion of the energy conserving apparatus associated with coupling site II is in a more hydrophobic environment than the corresponding apparatus associated with coupling site I.     

Kinetics of reduction of the oxidized primary electron donor of Photosystem II in spinach chloroplasts and in Chlorella cells in the microsecond and nanosecond time ranges following flash excitation

Absorption changes (ΔA) at 820 nm, following laser flash excitation of spinach chloroplasts and Chlorella cells, were studied in order to obtain information on the reduction time of the photooxidized primary donor of Photosystem II at physiological temperatures.In the microsecond time range the difference spectrum of ΔA between 750 and 900 nm represents a peak at 820 nm, attributable to a radical-cation of chlorophyll a. In untreated dark-adapted material the signal can be attributed solely to P⁺?700; it decays in a polyphasic manner with half-times of 17 μs, 210 μs and over 1 ms. The oxidized primary donor of Photosystem II (P⁺_II) is not detected with a time resolution of 3 μs. After treatment with 3–10 mM hydroxylamine, which inhibits the donor side of Photosystem II, P⁺_II is observed and decays biphasically (a major phase with $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 20–40 μ}\text{s}$, and a minor phase with $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{? 200 μ}\text{s}$), probably by reduction by an accessory electron donor.In the nanosecond range, which was made accessible by a new fast-response flash photometer operating at 820 nm, it was found the P⁺_II is reduced with a half-time of 25–45 ns in untreated dark-adapted chloroplasts. It is assumed that the normal secondary electron donor is responsible for this fast reduction.     

Functional and structural organization of chlorophyll in the developing photosynthetic membranes of Euglena gracilis Z. I. Formation of System II photosynthetic units during greening under optimal light intensity

The relationships between light-harvesting chlorophyll and reaction centers in Photosystem II were analyzed during the chloroplast development of dark-grown, non-dividing Euglena gracilis Z. Comparative measurements included light saturation of photosynthesis, oxygen evolution under flashing-light and fluorescence induction. The results obtained can be summarized as follows: (1) Photosystem II photocenters are formed in parallel with chlorophyll synthesis, but after a longer lag phase. (2) As a consequence, the chlorophyll: reaction center ratio (Emerson's type photosynthetic unit) decreases during greening. (3) This decrease is accompanied by considerable changes in the energy transfer and trapping properties of Photosystem II. Most of the initially synthesized chlorophylls are inactive in the transfer of excitations to active photochemical centers and are shared among newly formed Photosystem II photocenters; as a consequence, the number of chlorophylls functionally connected to each Photosystem II photocenter decreases and cooperativity between these centers appears. Results are discussed in terms of chlorophyll organization in developing photosynthetic membranes with reference to the lake or puddle models of photosynthetic unit organization.     

Chlorophyll a forms in Phaeodactylum tricornutum: Comparison with other diatoms and brown algae

The long-wave chlorophyll a forms in Phaeodactylum tricornutum (688 and 703 nm) change into a short-wave form, 670 nm, as a result of incubation with 55% glycerol, freeze-thawing, short ultraviolet irradiation and, probably, chloroplast preparation. This short-wave form is non-fluorescent. Fluorescence polarisation measurements indicate that the long-wave chlorophyll a molecules are oriented parallel to each other. Although “labile” long-wave chlorophyll a receives energy from Photosystem II pigments at room temperatures and follows the induction phenomena of fluorescence, it is indicated by afterglow experiments that it probably does not participate in Photosystem II.Long-wave chlorophyll forms in Fucus are stable and probably are related to Photosystem I.     

Photo-inactivation of System II centers by carbonyl cyanide m-chlorophenylhydrazone in Chlorella pyrenoidosa

In the presence of a high concentration of carbonyl cyanide m-chlorophenylhydrazone (CCCP) (4 · 10^?6 M), the S₂ and S₃ dark decays are accelerated and become biphasic with a first half-time of 0.6 s. The first fast phase of the decays does not correspond to a simple reduction of S₂, S₃ back to S₀, S₁ (i.e. to an acceleration of the deactivation reaction), but to a decrease in the number of oxygen-evolving System II centers. This photo-inactivation produced by CCCP is rapidly reversible in the dark.     

Photooxidation of cytochrome b559 and the electron donors in chloroplast Photosystem II

The effect of light on the reaction center of Photosystem II was studied by differential absorption spectroscopy in spinach chloroplasts.

At − 196 °C, continuous illumination results in a parallel reduction of C-550 and oxidation of cytochrome b₅₅₉ high potential. With flash excitation, C-550 is reduced, but only a small fraction of cytochrome b₅₅₉ is oxidized. The specific effect of flash illumination is suppressed if the chloroplasts are preilluminated by one flash at 0 °C.

At − 50 °C, continuous illumination results in the reduction of C-550 but little oxidation of cytochrome b₅₅₉. However, complete oxidation is obtained if the chloroplasts have been preilluminated by one flash at 0 °C. The effect of preillumination is not observed in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea.

A model is discussed for the reaction center, with two electron donors, cytochrome b₅₅₉ and Z, acting in competition. Their respective efficiency is dependent on temperature and on their states of oxidation. The specific effect of flash excitation is attributed to a two-photon reaction, possibly based on energy-trapping properties of the oxidized trap chlorophyll.     

Isolation of a fast decay in submillisecond Chlorella luminescence

Using a simple He-Ne (632.8-nm) laser phosphoroscope steady-state luminescence from Chlorella pyrenoidosa was studied from 50 μs to 1.1 ms between 1 ms long exciting flashes. The following results were obtained: (1) prior freezing or ultraviolet irradiation changed the time course of the luminescence to a rapid decay with a half-time of about 110 μs; (2) 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) suppressed the 110-μs luminescence; (3) spectrally, all observed luminescence was, within possible error, identical to fluorescence; (4) no effect on the luminescence intensity from pulsed magnetic fields up to 30 kgauss was observed; (5) the relative fluorescence yield, measured simultaneously with luminescence, was found to be constant.Our principal conclusions, supported mainly by experiments with DCMU, are: (1) the 110-μs decay is a distinct component of the total steady-state luminescence; (2) prior freezing or ultraviolet irradiation isolates this component of the luminescence by suppressing all other components; (3) the half-time and intensity of this component are temperature independent in the interval 0–22 °C.     

Nondestructive evaluation of photosynthesis by delayed luminescence in Arabidopsis in Petri dishes

Nondestructive evaluation of photosynthesis is a valuable tool in the field and laboratory. Delayed luminescence (DL) can reflect charge recombination through the backflow of electrons. However, DL detection has not yet been adapted for whole plants in Petri dishes. To compensate for differences in DL decay between sibling Arabidopsis plants grown under the same conditions, we developed a time-sequential double measurement method. Using this method, we examined the influence of photosynthetic electron flow inhibitors, and differences in the DL decay curves were categorized by considering the initial and late phases of the decay curves, as well as their intermediate slopes. The appearance of concavity and convexity in DL curves in Arabidopsis was different from unicellular algae, suggesting complexity in the photosynthetic machinery of higher plants. This detection method should be invaluable for evaluating photosynthetic defects in higher plants under sterile conditions without interrupting plant culture.     

The accessibility of the chloroplast cytochromes ƒ and b-559 to ferricyanide

(1) (a) A concentration range of ferricyanide ( 0.125–0.5 mM) can be found which in the dark causes oxidation of cytochrome ƒ with two distinct kinetic components of comparable amplitude. The slow oxidation has a half time of 1–2 min. (b) The oxidation of cytochrome ƒ by ferricyanide is rapid and monophasic after the chloroplasts are frozen and thawed. (c) The oxidation of cytochrome b-559 by ferricyanide in the dark is mostly monophasic with a time course similar to that of the fast component in the cytochrome ƒ oxidation. (d) Ascorbate reduction of cytochromes ƒ and b-559 appears monophasic. Reduction of cytochrome b-559 by ascorbate is somewhat faster, and that by hydroquinone somewhat slower, than the corresponding reduction of cytochrome ƒ.

(2) (a) The kinetics of dark ferricyanide oxidation of cytochrome ƒ after actinic preillumination in the presence of an electron acceptor are approximately monophasic with a half time of about 30 s and do not show the presence of the slowly oxidized component observed after prolonged dark incubation. (b) The effect of actinic preillumination in altering the time course of ferricyanide oxidation appears to persist for several minutes in the dark. (c) Preillumination causes an increase in the extent of cytochrome b-559 oxidation by low concentrations of ferricyanide. The increase is inhibited if 3-(3′,4′-dichlorophenyl)-1,1-dimethylurea is present during the preillumination. (d) The presence of 3-(3′,4′-dichlorophenyl)-1,1-dimethylurea during preillumination does not inhibit the amplitude or rate of ferricyanide oxidation of cytochrome ƒ, although the presence of the inhibitor KCN does cause such inhibition.

(3) It is proposed that a significant fraction of the cytochrome ƒ population resides at a position in the membrane relatively inaccessible to the aqueous interface compared to high potential cytochrome b-559. Actinic illumination would cause a structural or conformational change in the cytochrome ƒ and/or the membrane resulting in an increase in accessibility to this fraction of the cytochrome ƒ population.