Parallel time courses of electrochromic shifts of carotenoids and cytochrome f photooxidation in intact Bryopsis chloroplasts

Light-induced absorbance changes at 560 nm, and electrochromicshifts in absorption of carotenoids responding to membrane potentialacross the thylakoid membrane, were studied, comparing themwith the kinetics of cytochrome f photooxidation, in the dark-adaptedintact chloroplasts of the green alga Bryopis maxima. The 560nm changes showed transient variations, characterized by a sharpinitial peak followed by a second, lower peak, within a fewseconds of illumination. The time course of the 560 nm changesis parallel to that of light-induced transient changes of cytochromef. Inhibitors and redox substances which selectively influenceddifferent transient phases of the cytochrome f induction alsospecifically affected corresponding transient phases of the560 nm changes. These results indicate that the two inductionphenomena are closely related to each other and that the inductionof the 560 nm change is due to light-dependent changes in electrontransfer on the reducing side of photosystem I. A possible mechanismfor the electric field formation by electron transfer associatedwith photosystem I will be discussed. (Received May 9, 1977; )     

A new light-induced absorbance change at 561 nm in chloroplasts of green alga, Bryopsis maxima

A new light-induced absorbance change having a maximum at 561nm was discovered in the thalli, as well as in isolated chloroplastsof a green alga, Bryopsis maxima Okamura. Another simultaneous change also occurred at 515 nm. The magnitudeof the 561 nm change was several-fold larger than that at 515nm and much larger than could be explained by an oxidation-reductionchange in cytochromes contained in chloroplasts. There was noabsorbance change in the Soret region that may be correlatedto the 561 nm change. Both 561 and 515 nm changes showed a spike-liketime course pattern, both having a half-rise time of about 20msec. Effects of inhibitors and uncouplers such as DCMU, Cl-CCPand gramicidin J on the absorbance change were also similarat 561 and at 515 nm. We inferred that the 561 nm change is related to photophosphorylationand possibly to the membrane potential in a way similar to the515 nm change. (Received March 27, 1974; )     

Electron transport in the membrane of lutoids from the latex ofHevea brasiliensis

1. An antimycin-insensitive NADH-cytochromec oxidoreductase (E.C. 1.6.99.3) activity can be demonstrated in the membrane of lutoids isolated from the latex ofHevea brasiliensis. This electron transport system can also use ferricyanide as an electron acceptor, but is unable to oxidize NADPH.2. Twob-type cytochromes are present in the membranes. Cytochromeb₅₆₃ is partially reduced by NADH and ascorbate, but is not reducible by NADPH. It shows a double peak at 555 and 561 nm at 77 °K. A second cytochrome, cytochromeb₅₆₁, seems to be reducible by hydrosulfite only.3. In the reduced state, these cytochromes do not combine with CO. The occurrence of cytochromeP-450 could not be demonstrated.4. The role of the NADH oxidation system is considered in relation to the biosynthesis of polyisoprene compounds in the latex.     

Two electrogenic mechanisms contributing to the 560 nm absorption changes in intact Bryopsis chloroplasts

Light -induced absorbance changes at 560 nm in dark-adapted intact chloroplasts of the green alga, Bryopsis maxima were studied in the time range of 200 ms. The initial rise of the 560 nm signals constists of two major components which are both electrochromic absorbance changes of the carotenoids, sipnonein and/or siphonaxanthin, but different in mechanisms of the field formation.The first component (component S) is related to electron transport since it was sensitive to 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB) and showed a light-intensity dependence similar to that of electron transport in chloroplasts. In the presence of DCMU, component S could be restored on addition of proton-transporting electron donors such as reduced 2,6-dichlorophenol indophenol and phenazine methosulfate, but not on addition of N,N,N′,N′-tetramethyl-p-phenylenediamine which does not carry protons with electrons (Trebst, A. (1974) Annu. Rev. Plant Physiol. 25, 423–458). We propose that component S is due to the electric field set up by the proton translocation across the thylakoid membrane.The second component (component R) was resistant to DCMU and DBMIB. The light-intensity dependency of component R was similar to that of cytochrome f photooxidation which showed saturation at a relatively low light intensity. The magnitude of component R was markedly reduced by phenylmercuric acetate, suggesting the participation of ferredoxin and ferredoxin-NADP oxidoreductase in the mechanism of the field formation responsible for this component. In the presence of DCMU and phenylmercuric acetate, time courses of the 560 nm changes paralleled those of cytochrome f changes. These results indicate that component R is due to the electric field formed between oxidized cytochrome f and other intersystem electron carriers located in the inner part of the thylakoid membrane and reduced electron acceptors of Photosystem I situated on the membrane surface.The complex natures of the 560 nm changes, as well as the contributions of Photosystems I and II to the absorbance changes, are explained in terms of the two electrogenic mechanisms.     

Initial purification study of the cytochromeb 561 of bean hypocotyl plasma membrane

Summary The plasma membrane (PM) of higher plants contains a major ascorbate-reducible, high-potentialb-type cytochrome, named cytochromeb ₅₆₁ (cytb ₅₆₁). In this paper a rapid purification protocol for the cytb ₅₆₁ of bean hypocotyls PM is described. An almost 200-fold increase of cytb ₅₆₁ specific concentration was achieved with respect to the PM fraction, which contained about 0.2 nmol of ascorbate-reducible heme per mg protein. The procedure can be performed in one day starting from purified PMs obtained by the phase-partitioning procedure. However, cytb ₅₆₁ proved to be unstable during chromatographic purification and the amount of protein finally recovered was low. Purified cytb ₅₆₁ eluted as a 130,000 Da protein-detergent complex from gel-filtration columns. It was completely reduced by ascorbate and reduced-minus-oxidized spectra showed -, - and -bands at 561, 530, and 429 nm respectively, not unlike the spectra of whole PMs. This work represents an initial approach to the biochemical characterization of the cytb ₅₆₁ of higher plants, formerly suggested to be related to cytb ₅₆₁ of animal chromaffin granules.Abbreviations cytb ₅₆₁ cytochromeb ₅₆₁ - PM plasma membrane - UPV upper-phase vesicles - GSII glucan synthase II - CCR NADH-dependent cytochromec reductase - CCO cytochromec oxidase - TX-100R reduced Triton X-100     

Characterization of the photosynthetic electron transport chain in normal and photobleachedAnabaena cylindrica by flash spectroscopy

Electron transport of normal and photobleachedAnabaena cylindrica was studied using spectral and kinetic analyses of absorbance transients induced by single turnover flashes. Between 500 and 600 nm two positive bands (540 and 566 nm) and two negative bands (515 and 554 nm) were found. Absorbance changes at 515 and 540 nm were partly characterized. None of these absorbance changes represent an electrochromic shift. Absorbance changes at 554 and 566 nm correspond to the oxidation of cytochromef and the reduction of cytochromeb ₅₆₃, respectively. We found a very slight 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU) sensitivity of cytochromef in normal cells, while DCMU was completely ineffective for cytochromef reduction in photobleached cells. The absorbance change of cytochromeb ₅₆₃ increased, while the absorbance change of cytochromef was smaller than in normal cells. The increased O₂ evolution in photobleached cells and the negligible electron transport via cytochromef suggest the participation of other electron acceptor(s) in the electron-transport chain of photobleachedAnabaena cylindrica.     

Cytochromebc purified from the methanogenMethanosarcina barkeri

Cytochromebc was partially purified from the methanogen,Methanosarcina barkeri. The cytochrome was composed of three subunits with molecular masses of 23.4, 20.9, and 9.1 kDa, respectively, and the 23.4 kDa subunit contained haemc. The absorption spectrum of cytochromebc showed a peak at 411 nm in the oxidized form, and peaks at 554, 524, and 422 nm in the reduced form. The cytochrome reacted with CO, and its low temperature absorption spectrum showed the peak at 552 nm with a shoulder at 557 nm.     

Some properties of cytochromec' and other hemoproteins ofThiocapsa roseopersicina

Cytochromec' ofThiocapsa roseopersicina was partially purified by DEAE and Sephadex chromatography (highest purity index A 275 nm ox./A 396 nm ox.=0.54). It is autoxidizable, thermostable, and is located in the soluble fraction. The reduced cytochromec' reacts with carbon monoxide and has a γ-band at 417 nm and a shoulder at 435 nm. Cyanide (10⁻²−10⁻³ M) does not inhibit the reduction of the cytochromec' by sulfide; only at higher concentrations of cyanide did the shoulder at 435 nm disappear. When the cytochromec' is reduced by dithionite, only one broad α-band at about 550 nm appears next to the γ-band. When is is reduced by sulfide, the absorption spectrum shows an additional β-band at 521 nm. Cytochromec' is not reduced by thiosulfate.     

The reversibility of the ethidium bromide-induced alterations of mitochondrial structure and function in the cellular slime mold,Dictyostelium discoideum

Addition of ethidium bromide to ameboid cultures of the slime mold,Dictyostelium discoideum, caused a cessation of cell division after 1 or 2 generations. The replication of mitochondrial DNA was immediately blocked as indicated by the 50% decrease in the DNA content of purified mitochondria from ethidium-bromide-treated cultures. The activity of the respiratory chain was also inhibited, resulting in a 75% decrease in cyanide-sensitive whole cell respiration. Spectral analysis at low temperature indicated that the amount of cytochromec ₁ was decreased 80% and that of cytochromec increased 100% in mitochondria from treated cells. Two cytochromesb absorbing at 556 and 561 nm were observed in mitochondria from both control and ethidium-bromide-treated cultures. The content of cytochromeb ₅₆₁ appeared to decline more than didb ₅₅₆, but it is hard to quantitate the decrease. The effects of ethidium bromide were fully reversible. When the drug was removed, the cells resumed a normal growth rate without any discernible lag. The activity of oligomycin-sensitive ATPase, cytochrome oxidase, and succinate-cytochrome-c reductase as well as the cytochrome content began to increase after 1 day returning to control levels within 5 days. Electron micrographs of whole cells treated with ethidium bromide revealed that mitochondrial profiles were elongated and had greatly reduced cristae. Numerous membrane whorls were apparent, as was a profound loss of rough endoplasmic reticulum. Three days after removal of ethidium bromide, mitochondria were again ovoid in shape and contained well-developed cristae. In all of the cells during recovery, there was a single large vacuole that appeared to enclose a large portion of the cell volume, forming a new cellular compartment that may simplify the breakdown of previously damaged organelles.This work is in partial fulfillment of the requirements for the Doctor of Philosophy degree at the City University of New York.     

Properties of the Cytochrome c Oxidase Activity of Cytochrome b561 from Photoanaerobically Grown Rhodopseudomonas sphaeroides

Cytochrome b₅₆₁ from Rhodopseudomonas sphaeroides had cytochromec (c2) oxidase activity and a pH optimum at 6.0 for this activity.The activity was affected by the ionic strength of the reactionmixture. The apparent K_m and maximal velocity (V_max) valuesin the absence of addea salts were 14 µM and 120 nmoloxidized per min per mg protein for horse heart cytochrome c.Reduced horse heart cytochrome c was reoxidized in first-orderkinetics by this cytochrome b₅₆₁. The specific activity was0.7 s^–1 per mg protein at 20°C at the concentrationof 30 µMM cytochrome c. Activity was inhibited by KCN and NaN₃, but not by antimycin.The addition of a low concentration of KCN to the cytochromeb₅₆₁ produced a change in the absorption spectrum, evidencethat KCN interacts with the heme moiety of cytochrome b₅₆₁.Results of this and preceeding studies show that the cytochromeoxidase (cytochrome "o") described earlier (Sasaki et al. 1970)is cytochrome b₅₆₁. (Received May 16, 1983; Accepted September 8, 1983)     

Identification of an ascorbate-dependent cytochrome<Emphasis Type="Italic"> b</Emphasis> of the tonoplast membrane sharing biochemical features with members of the cytochrome<Emphasis Type="Italic"> b</Emphasis>561 family

Two membrane-bound, ascorbate-dependent b-type cytochromes were identified in etiolated bean (Phaseolus vulgaris L.) hypocotyls. Following solubilization of microsomal membranes and anion-exchange chromatography at pH 8.0, two major cytochrome peaks (P-I and P-II) were separated. Both cytochromes were reduced by ascorbate and re-oxidized by monodehydroascorbate, but P-I reduction by ascorbate was higher and saturated at far lower concentrations of ascorbate with respect to P-II. The -band was symmetrically centered at 561 nm in P-I, but it was asymmetric in P-II with a maximum at 562 nm and shoulder at 557 nm. Ascorbate reduction of P-II, but not P-I, was inhibited by diethyl pyrocarbonate. Reduced P-II but not P-I was readily oxidized by certain ferric chelates, including FeEDTA and Fe-nitrilotriacetic acid. Purified P-I, associated with the plasma membrane, showed up as a 63-kDa glycosylated protein during sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE) and behaved as a monomer of about 70 kDa during size-exclusion chromatography. P-I identified with a previously purified ascorbate-dependent b-type cytochrome of bean hypocotyl plasma membranes [P. Trost et al. (2000) Biochim Biophys Acta 1468:1–5]. Partially purified P-II, on the other hand, correlated with a heme-protein of 27 kDa in SDS–PAGE gels, was dimeric (60 kDa) during size-exclusion chromatography, and was associated with the tonoplast marker V-ATPase in sucrose gradients. The sequence of a peptide of 11 residues obtained by tryptic digestion of P-II was found to be identical to a segment of a putative cytochrome b561 of Zea mays and highly conserved in other related plant sequences, including that of Arabidopsis thaliana cytochrome b561-1 (CAA18169). The biochemical features fully support the assignment of P-II cytochrome to the family of cytochrome b561, ascorbate-dependent (CYBASC) cytochromes, which also includes cytochrome b561 of animal chromaffin granules. The presence of a cytochrome reducing ferric chelates on the tonoplast is consistent with the role of plant vacuoles in iron homeostasis.     

The kinetics of P515 in relation to the lipid composition of the thylakoid membrane

Flash-induced P515 absorbance changes have been studied in dark-adapted chloroplasts isolated from spinach plants grown under two different light intensities. The slow component (reaction 2), normally present in the P515 response of chloroplasts isolated from plants grown at an intensity of 60 W · m^–2, was largely reduced in chloroplasts isolated from plants grown at an intensity of 6 W · m^–2. This reduction of the slow component in the P515 response appeared to be coincident with an alteration in the lipid composition of the thylakoid membrane. Mainly the ratio monogalactosyldiacylglycerol to digalactosyldiacylglycerol appeared to be altered. In thylakoids from plants grown at 6 W · m^–2, the ratio was approximately 35% lower than that of plants grown at 60 W · m^–2. The amount of both cytochromeb ₅₆₃ and cytochromef was largely reduced in chloroplasts isolated from plants grown at low light intensity. These results may indicate a possible correlation between structural organization of the thylakoid membrane and the kinetics of the flash-induced P515 response.     

Comparison between Electron Transfers through Plastocyanin in Spinach Chloroplasts and Cytocbrome C2 in Rhodopseudomonas sphaeroides

Photosynthetic electron transfers through the water-solubleperipheral membrane proteins of plastocyanin and cytochromec₂, were studied in spinach chloroplasts and the photosyntheticbacterium Rhodopseudomonas sphaeroides. In spinach chloroplasts,the rate of flash-induced oxidation of cytochrome f was highlydependent on the salt concentration in the suspending medium.The maximum rate with a half time of 200 µs was observedin the presence of 50 mas KCl or 5 mM MgCl₂. The salt effectwas similar to that on the reaction rate between P700 in thylakoidfragments and externally added plastocyanin. On the other hand,in intact cells of R. sphaeroides, in which cytochrome c₂ islocated in the periplasmic space exposed to the outer ionicenvironment, the rate of cytochrome c₁ oxidation via cytochromec₂ was almost independent of salt concentration. This independencewas a contrast to the strong dependence on salt concentrationof reactions between isolated reaction centers and cytochromec₂ These results suggest that plastocyanin reacts collisionallywith the photosystem I reaction center and cytochrome b₆f complexin a manner that is controlled by the surface electrostaticpotential. Cytochrome c₂, on the other hand, reacts with thebacterial reaction center and cytochrome bc₁ complex probablyby forming a complex prior to activation of the reaction center. ¹ Present address: Department of Biology, Faculty of Science,Tokyo Metropolitan University, Fukazawa 2-1-1, Setagaya, Tokyo158, Japan.     

Melittin: An inhibitor of chloroplast photochemical reactions

Melittin, a polypeptide component of bee venom, is an inhibitor of photochemical reactions in chloroplasts isolated from higher plants. At concentrations around 5 μM, melittin acts as an uncoupler of photophosphorylation and abolishes the 518 nm light induced absorbance changes. At higher concentrations (30–50 μM), melittin abolishes both the light-induced photooxidation of cytochrome $\text{f}$, and partially inhibits other reactions of photosynthetic electron transfer, without causing lysis of the membrane. The observed inhibitions appear to be due to changes in the properties of the membrane lipid bilayer, caused by penetration of melittin molecules.     

Respiratory control over photosynthetic electron transport in chloroplasts of higher-plant cells: evidence for chlororespiration

Flash-induced primary charge separation, detected as electrochromic absorbance change, the operation of the cytochrome b/f complex and the redox state of the plastoquinone pool were measured in leaves, protoplasts and open-cell preparations of tobacco (Nicotiana tabacum L.), and in isolated intact chloroplasts of peas (Pisum sativum L.). Addition of 0.5–5 mM KCN to these samples resulted in a large increase in the slow electrochromic rise originating from the electrogenic activity of the cytochrome b/f complex. The enhancement was also demonstrated by monitoring the absorbance transients of cytochrome f and b ₆ between 540 and 572 nm. In isolated, intact chloroplasts with an inhibited photosystem (PS) II, low concentrations of dithionite or ascorbate rendered turnover of only 60% of the PSI reaction centers, KCN being required to reactivate the remainder. Silent PSI reaction centers which could be reactivated by KCN were shown to occur in protoplasts both in the absence and presence of a PSII inhibitor. Contrasting spectroscopic data obtained for chloroplasts before and after isolation indicated the existence of a continuous supply of reducing equivalents from the cytosol.Our data indicate that: (i) A respiratory electron-transport pathway involving a cyanide-sensitive component is located in chloroplasts and competes with photosynthetic electron transport for reducing equivalents from the plastoquinone pool. This chlororespiratory pathway appears to be similar to that found in photosynthetic prokaryotes and green algae. (ii) There is an influx of reducing equivalents from the cytosol to the plastoquinone pool. These may be indicative of a complex respiratory control of photosynthetic electron transport in higher-plant cells.Abbreviations and symbols A₅₁₅ flash-induced electrochromic absorbance change at 515 nm - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - PS photosystem - SHAM salicylhydroxamic acid     

Phospholipids in the cytochrome oxidase reaction

Phospholipids and Emasol activate cytochrome oxidase by increasing its affinity for its substrate, cytochromec. Cardiolipin was most effective in activating cytochrome oxidase among phospholipids tested. Prior formation of a cytochromec-cytochrome oxidase complex changes the effect of phospholipids. In addition to their structural role in the last segment of the electron transport system, phospholipids can protect the enzyme from heat treatment and mercurial inhibition. They facilitate the interaction between cytochrome oxidase and cytochromec, as well as the cytochromec analogue, protamine.     

Effects of dibromothymoquinone and bathophenanthroline on flash-induced cytochrome f oxidation in spinach chloroplasts

The effects of several electron transport inhibitors on themagnitude and kinetics of cytochrome f oxidation induced byflash illumination were studied in the - and -band regions.On the flash excitation only a fraction of cytochrome f presentin the chloroplasts was oxidized with a half time of 0.1 to0.3 msec and then reduced with a half time of 10 to 25 msec. Dibromothymoquinone (DBMIB) at concentrations which severelysuppressed the reduction of cytochrome f approximately doubledthe magnitude of cytochrome f oxidation caused by a flash, mainlyby inducing an additional slow oxidation of cytochrome f witha half time longer than 1 msec. Enhancement of the cytochromef oxidation was also observed in the presence of bathophenanthroline.Such enhanced oxidation in duced by the two inhibitors was largelydiminished with the addition of reduced 2,6-dichlorophenolindophenolwhich accelerated cytochrome f reduction. In contrast, the inhibitionof cytochrome f reduction by 3-(3,4-dichlorophenyl)-1,1-dimethylurea(DCMU) was not associated with an increase in the magnitudeof cytochrome f oxidation. However, addition of DBMIB to theDCMU-poisoned chloroplasts enhanced cytochrome f oxidation,suggesting that this is related to a block of the electron transportbetween plastoquinone and cytochrome f. The results are explainedby assuming the occurrence of an electron carrier between plastoquinoneand cytochrome f. (Received May 10, 1978; )     

Characterization of cytochrome b in the isolated ubiquinol-cytochrome c2 oxidoreductase from Rhodopseudomonas sphaeroides GA

Extinction coefficients for cytochrome b and c₁ in the isolated cytochrome bc₁ complex from Rhodopseudomonas sphaeroides GA have been determined. They are 25 mM^?1.cm^?1 at 561 nm for cytochrome b and 17.4 mM^?1.cm^?1 at 553 nM for cytochrome c₁ for the difference between the reduced and the oxidized state. Cytochrome b is present in two forms in the complex. One form has an E_m7 of 50 mV, an α-peak of 557 nm at liquid N₂ temperature and of 561 nm at RT, which is red-shifted by antimycin A. The other form has an E_m7 of ?90 mV, a double α-peak of 555 and 561 nm at liquid N₂ temperature corresponding to 559 and 566 nm at RT. The absorption at 566 nm is red-shifted by myxothiazol. The two shifts are independent of each other. Both midpoint potentials of cytochromes b are pH-dependent. The redox center compositions of the cytochrome bc₁ complexes from Rhodopseudomonas sphaeroides and from mitochondria are identical.     

b-Type cytochromes in plasma membranes ofPhaseolus vulgaris hypocotyls,Arabidopsis thaliana leaves, andZea mays roots

Summary The plasma membrane of higher plants contains more than one kind ofb-type cytochromes. One of these has a high redox potential and can be fully reduced by ascorbate. This component, the cytochromeb ₅₆₁ (cytb ₅₆₁), has its characteristic -band absorbance close to 561 nm wavelength at room temperature. Cytb ₅₆₁ was first isolated from etiolated bean hook plasma membranes by two consecutive anion exchange chromatography steps. During the first step performed at pH 8, cytb ₅₆₁ did not bind to the anion exchange column, but otherb-type cytochromes did. In the second step performed at pH 9.9, cytb ₅₆₁ was bound to the column and was eluted from the column at an ionic strength of about 100 mM KCl. However, when the same protocol was applied to the solubilized plasma membrane proteins fromArabidopsis thaliana leaves and maize roots, the ascorbate-reducible cytb ₅₆₁ bound already to the first anion exchange column at pH 8 and was eluted also at an ionic strength of about 100 mM KCl. Otherb-type cytochromes than the ascorbate-reducible cytb ₅₆₁ from the plasma membranes of Arabidopsis leaves and maize roots showed similar Chromatographic characteristics to that of bean hypocotyls. These results demonstrate particular differences in the Chromatographic behavior of cytb ₅₆₁ from different sources.Abbreviations cyt b ₅₆₁ cytochromeb ₅₆₁ - PM plasma membrane - PAGE polyacrylamide gel electrophoresis