Artificial Quinones Replace the Function of Quinone Electron Acceptor (QA) in the Isolated D1-D2-Cytochrome b559 Photosystem II Reaction Center Complex

Various benzo- and naphthoquinone derivatives were introducedinto the purified photosystem II Dl-D2-cytochrome b₅₅₉ reactioncenter complex, which lacks the intrinsic plasto-quinone electronacceptors. Effects of these quinones on the electron transferreactions in nanoseconds to milliseconds time range were studiedat room and cryogenic temperatures. 1) The addition of quinonesto the purified photosystem II reaction center complex suppressedthe nanosecond charge recombination between oxidized reactioncenter chlorophyll a (P680⁺) and reduced pheophytin a (Ph^–),and stabilized P680⁺ up to millisecond time range at 280 K andat 77 K. 2) In the reaction center complex supplemented withdibromothymoquinone (DBMIB), P68O was almost fully oxidizedand cytochrome b₅₅₉ was partially reduced by flash excitation.A semi-quinone-like signal with a peak around 320 nm was alsoinduced but the shift of pheophytin absorption band (C55O) wasnot observed. 3) Halogenated quinones, especially DBMIB, werebetter electron acceptors than unsubstituted or methylated quinones.4) The affinities of quinones to the reaction center complexwere weakly dependent on their molecular structure. (Received July 9, 1991; Accepted August 15, 1991)     

Photosystem I photochemistry: A new kinetic phase at low temperature

A new phase of charge recombination between the oxidized primary electron donor of photosystem I (P700⁺) and a reduced acceptor has been detected by flash absorption spectroscopy in PS I particles at low temperature. It occurs under highly reducing conditions (the secondary electron acceptors F_A and F_B and one or possibly two ‘more primary’ acceptors being prereduced) with a t_1/2 of about 20 μs between 10 and 80 K.     

Dichroic Orientation of Phytochrome Intermediates in the Pathway from PR to PFR as Analyzed by Double Laser Flash Irradiations in Polarotropism of Adiantum Protonemata

The polarotropic response in protonemata of the fern Adiantumis regulated by phytochrome (Kadota et al. 1984); P_R and P_FRhave been shown to be dichroically oriented parallel and normalto the cell surface, respectively (Kadota et al. 1982). Thischange in the dichroic orientation of phytochrome during photoconversionwas analyzed by a newly-built, polarization plane-rotatabledouble laser flash irradiator. A polarotropic response was effectivelyinduced with a flash of polarized red (640 nm) light (6xl0^–7s) having the vibration plane of the electrical vector parallelto the protonemal cell axis. When a flash of polarized far-red(710 nm) light (6xl0^–7s) was given 30 sec after the redflash, the red flash-induced response was reversed by a far-redflash vibrating normal to the cell axis but not by one vibratingparallel. However, when given 2 µs or 2 ms after the redflash, the polarotropic response was not reversed by a polarizedfar-red flash vibrating normal to the cell axis but was reversedby a parallel-vibrating flash. These results suggest that theorientation of phototransformation intermediates existing 2µs or 2 ms after a red flash is still parallel to thecell surface, and that the change in the orientation of phytochromemolecules occurs between 2 ms and 30 s after the red flash. (Received February 3, 1986; Accepted April 23, 1986)     

Reaction of Reconstituted Acceptor Quinone and Dynamic Equilibration of Electron Transfer in the Photosystem I Reaction Center

Electron transfer mechanism in the spinach photosystem I reactioncenter that contains artificial quinones in place of phylloquinone(2-methyl-3-phytyl-1,4-naphthoquinone, vitamin K₁) as the secondaryelectron acceptor, Q_ø (or A₁) was discussed. (1) Mostof the reconstituted quinones oxidized the primary acceptorchlorophyll a, A⁰, at a rate rapid enough to compete againstthe charge recombination between A₀^– and the oxidizeddonor chlorophyll P700⁺. (2) The pathway of electron transferfrom the semiquinone^– varied depending on the redox potentialvalue of each semiquinone^– /quinone couple. Low potentialquinones reduced the tertiary acceptor iron-sulfur center, F_x,while the high potential ones reduced P700⁺ directly with a200-µs halftime. (3) The E_m value of each semiquinone^–/quinone couple in situ in the reaction center was estimatedto be shifted by about 0.3 volt to the negative side from theirhalf wave redox potential values that were measured polarographicallyin dimethylformamide. The shift seems to represent the acceptorproperty of the protein environment at the Q_ø site. (4)The E_m of reconstituted phylloquinone was estimated to be 50–80mV more negative than that of F_x. (5) The mechanism of efficientelectron transfer in the reaction center was discussed basedon the dynamic equilibria between the electron transfer componentsand on the estimated E_m values. (Received April 9, 1994; Accepted July 7, 1994)     

Isolation of the Photoactive Reaction Center Complex that Contains Three Types of Fe-S Centers and a Cytochrome c Subunit from the Green Sulfur Bacterium Chlorobium limicola f. thiosulfatophilum, Strain Larsen

The photoactive reaction center (RC) complex from the greensulfur bacterium Chlorobium limicola f. thiosulfatophilum, strainLarsen, was isolated after solubilization and ammonium sulfatefractionation followed by ion-exchange chromatography. The spectrumof the complex was almost identical with that of the similarRC complex isolated by Feiler et al. [(1992) Biochemistry 31:2608–2614] except for the presence of cytochrome c₅₅₁instead of c₅₅₃ in the latter study. A molecular ratio of BChla to P840 of the isolated RC complex was assayed to be 25–35.SDSPAGE analysis revealed that the isolated complex containedthree major polypeptides with apparent molecular masses of 68,41 and 21 kDa, respectively. The 21-kDa polypeptide was identifiedto be a heme-binding protein by staining the gel for peroxidaseactivity. The cytochrome c₅₅₁ was oxidized by flash light ina biphasic manner with half times of 90 and 390 µs, respectively,that coincided with the reduction half times of P840⁺. Threedistinct iron-sulfur centers assigned to F_A, F_B and F_x, respectively,from their g-values were detected by EPR spectroscopy at cryogenictemperature. These results suggest that the present preparationcontains a minimal functional unit of the RC of this bacterium,and that this complex appears to lie on a evolutionary linebetween RC's of purple bacteria and photosystem I. (Received August 18, 1992; Accepted October 28, 1992)     

Time-Resolved Spectroscopy of Chlorophyll-a like Electron Acceptor in the Reaction Center Complex of the Green Sulfur Bacterium Chlorobium tepidum

The absorption changes of chlorophyll (Chl) a-like pigments(C670) were studied by ns-ms laser spectroscopy at 77 K in theuntreated and urea-treated homodimeric reaction center (RC)complex of the green sulfur bacterium Chlorobium tepidum. Theuntreated RC complex contained 9 molecules of C670 in additionto 41 molecules of Bchl a and 0.9 molecules of menaquinone-7per one primary electron donor Bchl a dimer (P840). Upon photo-oxidationof P840, C670 showed an absorption change of a red-shift withan isosbestic wavelength at 668 nm. The absorption change ofP840 decayed with time constants (t_1/e) of 55 and 37 ms at 283and 77 K, respectively, and was assigned to represent the chargerecombination between P840⁺ and FeS^–. In the urea-treatedRC complex, a bleach peaking at 670 nm with a shoulder peakat 662 nm, which is ascribable to the reduced primary electronacceptor A₀^–, was detected after the laser excitationin addition to the shift at 668 nm indicating the formationof the P840⁺A₀^– state. The P840⁺A₀^– state decayedwith a t_1/e of 43 ns at 77 K and produced a triplet state p840^Tdue to the suppression of the forward electron transfer. Theseresults indicate the two different types of C670 species inthe RC complex; the one peaking at 670 nm functions as A⁰, whilethe other peaking at 668 nm shows the electrochromic shift,which presumably functions as the accessory pigment locatedin the close vicinity of P840. (Received May 17, 1999; Accepted July 14, 1999)     

Phototransformation of the Red-Light-Absorbing Form to the Far-Red-Light-Absorbing Form of Phytochrome in Pea Epicotyl Tissue Measured by a Multichannel Transient Spectrum Analyser

Phototransformation of the red-light-absorbing form (P_R) tothe far-red-light-absorbing form (P_FR) of phytochrome in 7-day-oldetiolated pea epicotyl hook segments was examined at 0.5C aftera red laser flash excitation using a multichannel transientspectra analyser with electrically gated photomultiplier. Effectsof a red laser pulse on the induction of phototransformationfrom P_R to P_FR were saturated at Ca. 15 mJ for flash wavelengthsof both 640 and 655 nm. The amount of P_FR induced by a saturatinglaser pulse was ca. 50% of that obtained at the photostationaryequilibrium. A difference spectrum measured 15 µs afterthe flash showed an absorbance increase at 697 nm and a decreaseat 663 nm. A difference spectrum determined 200 ms after theflash showed no such major absorbance increase. Kinetic analysisof the rapid absorbance decrease at 700 and 710 nm gave onesimple first-order reaction component having a rate constantof 2,500 s^–1. Kinetics of P_FR appearance measured by absorbanceincrease at 750 nm was resolved into three first-order reactionshaving rate constants of 5, 1.8 and 0.4 s^–1. The secondflash light of 710 nm given 2 µs and 2 ms after the firstred flash irradiation on P_R resulted in the formation of P_Rrather than P_FR. (Received February 8, 1985; Accepted April 11, 1985)     

Purification and Characterization of a Cytochrome P450 (trans-Cinnamic Acid 4-Hydroxylase) from Etiolated Mung Bean Seedlings

A Cyt P450 (P450_C4H) possessing trans-cinnamate 4-hydroxylase(C4H) activity was purified to apparent homogeneity from microsomesof etiolated mung bean seedlings. Upon SDS-polyacrylamide gelelectrophoresis, the purified preparation gave a single proteinband with a molecular mass of 58-kDa. Its specific P450 contentwas 12.6 nmol (mg protein)^–1. Using NADPH as electrondonor, purified P450_C4H aerobically converted trans-cinnamicacid to p-coumaric acid with a specific activity of 68 nmolmin^–1 nmol^–1 P450 in a reconstituted system containingNADPH-Cyt P450 reductase purified from the seedlings or rabbitliver microsomes, dilauroyl phosphatidylcholine, and cholate.This specific activity is by far the highest for reconstitutedC4H systems so far reported and provides direct evidence thatC4H activity is actually associated with a P450 protein. Inthe oxidized state P450_C4H showed a typical low-spin type absorptionspectrum with a Soret peak at 419 nm. A partial spectral shiftto the high spin state was observed when trans-cinnamic acidwas added to oxidized P450_C4H. By spectral titration, the dissociationconstant of the cinnamic acid-P450_C4H complex was determinedto be 2.8 µM. This value is similar to the K_m value (1.8µM) for trans-cinnamic acid determined in the reconstitutedsystem. (Received November 20, 1992; Accepted February 17, 1993)     

Purification and characterization of the photosystem I complex from the filamentous cyanobacterium Anabaena variabilis ATCC 29413.

A photoactive photosystem I complex has been purified from the filamentous, nitrogen-fixing cyanobacterium Anabaena variabilis ATCC 29413. Cells were broken using glass beads, and the membrane fraction was solubilized with beta-dodecyl maltoside followed by two rounds of fast protein liquid chromatography on anion exchange columns. The polypeptide composition of the isolated complex was determined by sodium dodecyl sulfate-urea-polyacrylamide gel electrophoresis and N-terminal amino acid sequencing of the fractionated proteins. The purified complex consists of at least 11 proteins, identified as the PsaA, PsaB, PsaC, PsaD, PsaE, PsaF, PsaI, PsaJ, PsaK, PsaL, and PsaN proteins. The spectrum of the flash-induced absorbance change measured between 670 and 830 nm shows that the purified complex contains 99 +/- 11 chlorophyll a molecules per P700, the primary donor in photosystem I. The kinetics of the rereduction of oxidized P700 following an actinic flash indicate that forward electron transfer from P700 to the FA/FB iron-sulfur center acceptors is functional in the isolated complex.     

Nature of light-induced absorbance changes at 682 m{micro} and 702 m{micro} in photosynthesis of Anacystis nidulans

Light-induced absorbance changes in the region around the redabsorption band of chlorophyll a were measured in cells andlamella fragments of Anacystis nidulans. In both materials,absorbance decreases were observed at 702 mµ and 682 mµ.(The pigments are designated as P₇₀₀ and P₆₈₀.) The nature ofP₆₈₀ was investigated with special reference to its relationshipto P₇₀₀. In the cells, light absorbed by chlorophyll a causedan absorbance decrease at 682 mµ; Simultaneous illuminationwith light absorbed by phycocyanin caused a partial recoveryof the absorbance decrease. Similar results were observed withthe light-induced absorbance change at 702 mµ. This indicatesthat P₆₈₀ is also an electron carrier in the electron transportchain and occupies a place between the two photoreactions. Inlamella fragments, both the light-induced reversible absorbancechanges of P₆₈₀ and P₇₀₀ appeared in the presence of an electrondonor system; i.e., ascorbate and 2,6-dichlorophenolindophenolor N,N,N',N'-tetramethyl-l,4-phenylenediamine. The experimentsin which the oxidation-reduction potential of the reaction mediumwas changed showed that both P₆₈₀ and P₇₀₀ are one-electroncarriers, having a normal oxidation-reduction potential of 0.44v (assuming that the normal oxidation-reduction potential ofthe ferricyanide-ferrocyanide system is 0.409 v). A possibilitywas suggested that the absorbance change observed at 682 mµis another expression of the oxidation-reduction reaction ofP₇₀₀). (Received October 30, 1968; )     

Preparation and Characterization of P700-Enriched Photosystem-I Complexes from the Thermophilic Cyanobacterium, Synechococcus sp.

P700 was enriched relative to antenna pigments by treating thethylakoid membranes from thermophilic cyanobacterium (Synechococcussp.) with diethylether. The total Chi a/P700 ratio of the membraneswas 147 but decreased to 13 after the treatment with ether whichhad been 70% saturated with water. Vitamin K₁ and carotenoidswere completely removed by this treatment. The low chlorophylla to P700 ratio was retained in photosystem I reaction-centercomplexes purified from the ether-extracted membranes with TritonX-100. The midpoint potential of P700 was considerably loweredby the ether treatment of the thylakoid membranes but was partiallyreversed by the further treatment of the extracted membraneswith Triton X-100. Photo-oxidation of P700 in the purified complexeswas extremely slow under continuous illumination, indicatingthat there is no significant leakage of electrons from the primaryelectron acceptor to other bound acceptors or O₂. The photooxidationof P700 was appreciably accerelated on addition of vitamin K₃(or K₁). (Received June 23, 1988; Accepted November 25, 1988)     

Heat-stabilities of Electron Transport Related to Photosystem I in a Thermophilic Blue-green Alga, Synechococcus sp.

Heat-stabilities of photosystem I reactions in a thermophilicblue-green alga, Synechococcus sp. were studied. All the reactionsexamined were highly resistant to heat as compared with thosein ordinary higher plants and algae. Cyt c-553 photooxidation in vivo was abolished by treatmentat 75?C for 5 min. By contrast, P700 photooxidation was extremelyresistant to heat and could not be completely inactivated bytreatment of the cells or isolated thylakoids at about 100?Cfor 5 min. Photooxidation of added Cyt c-553 by isolated thylakoidmembranes was more heat-stable than was this activity in cells.This suggests that heat-treatment caused a perturbation in thestructural integrity of the membranes which is required forefficient electron transfer from Cyt c-553 to P700 in situ. At higher temperatures, the inactivation of Cyt c-553 photooxidationin the membranes parallels the decrease in the rate of P700photooxidation. Spectrophotometric studies with short flashesindicated that inactivation of the electron transport from Cytc-553 to methyl viologen is due to the denaturation of a secondaryelectron acceptor of photosystem I, A₂, and possibly anotheracceptor, P430. ¹ Present address: The Solar Energy Research Group, the Instituteof Physical and Chemical Research (RIKEN), 2-1 Hirosawa, Wako-shi,Saitama 351, Japan. (Received September 28, 1981; Accepted December 21, 1981)     

Preparation of a Photoactive Reaction Center Complex Containing Photo-reducible Fe-S Centers and Photooxidizable Cytochrome c from the Green Sulfur Bacterium Chlorobium tepidum

A photoactive reaction center (RC) complex was isolated fromthe green sulfur bacterium Chlorobium tepidum by solubilizationof membranes with Triton X-100, followed by sucrosedensity gradientcentrifugation, DEAE Bio-Gel A chromatography, and hydroxyapatitechromatography. The purified RC complex contained about 50–70bacteriochlorophyll molecules (BChl) per P840, as assayed byphotooxidafion. It showed a near-infrared BChl a absorptionpeak at 814 nm and shoulders at about 800 and 835 nm at roomtemperature. SDS-PAGE analysis revealed 6 polypeptides withapparent molecular masses of 100, 65, 41, 32, 23, and 18 kDa.The RC complex binds functional P840 and Cyt c₅₅₁, which werephotooxidized by continuous illumination at room temperature.Upon flash excitation, the bound Cyt c₅₅₁ was oxidized, andrereduced in the dark with a half-time of 16 and 400 ms in thepresence and absence of 0.1 mM 2,6-dichlorophenol indophenol,respectively, at room temperature. At 551 nm, the amount ofthe Cyt c photooxidized by continuous illumination was 60% ofthe amount determined by chemical oxidation-reduction. The functionalCyt c₅₅₁/P840 ratio was calculated to be 1.2–1.7. EPRspectroscopy at cryogenic temperatures revealed that the RCcomplex binds three photoreducible Fe-S centers designated tobe CF_A, CF_B and CF_X (C for Chlorobium). CF_A and CF_B were reducedin the dark with dithionite at pH 10. (Received May 26, 1993; Accepted October 4, 1993)     

Picosecond Photochemistry of P700-Enriched and Vitamin K1-Depleted Photosystem I Particles Isolated from Spinach

Picosecond transient absorption changes, with a laser intensityas low as one photon absorbed per single reaction center, weremeasured with vitamin K₁-depleted and P700-enriched particleswhich were obtained by ether treatment of spinach PS-I particles.When P700 was in the oxidized state, a bleaching that correspondedto about one-seventh of the ground state absorption was observedjust after a laser flash (0 picosecond delay). A major partof the bleaching decayed with a lifetime of about 35 picoseconds,which corresponds to the relaxation of the excited antenna chl-ato the ground state. By contrast, when P700 was in the reducedstate, the bleaching observed at a 0 ps delay was broader, especiallyon the longer wavelength side than the ground state absorption,probably because of the generation of the excited state of P700.About one half of the bleaching decayed within 35 ps and theremaining half, which had a broad spectrum and a peak around682 nm, was conserved up to 2 ns. This long-lived bleachingprobes no picosecond decay of the radical pair P700⁺-A₀^–because electrons were not transferred from A₀¹ to A₁ in vitaminK₁-depleted particles. After addition of vitamin K₃, an analogof vitamin K₁, to the reduced particles, the bleaching around685 nm decayed successively with an apparent rate of about 150picosecond, while the bleaching around 700 nm was conservedfor up to 2 nanosecond. Thus, the bleaching remaining at 2 nsresembled the difference spectrum of P700, suggesting a subnanosecondquenching of A₀¹ by the externally added vitamin K₃. These observationssupport a recent proposal that the secondary electron acceptorA₁, in photosystem I, is vitamin K₁. ³Permanent address: Optics Laboratory, Korea Standards ResearchInstitute, Daedok Science Town, Chungnam 300-31, Korea. (Received October 24, 1988; Accepted April 14, 1989)     

Dibromothymoquinone (DBMIB) Replaces the Function of QA at 77 K in the Isolated Photosystem II Reaction Center (D1-D2-Cytochrome b559) Complex: Difference Spectrum of the P680+(DBMIB-) State

Transient absorbance changes of the primary electron donor chlorophylla (P680) and acceptor pheophytin a (H) were measured at 77 Kby nanosecond laser spectroscopy in the D1-D2-cytochrome b₅₅₉photosystem II reaction center complex containing dibromomethylisopropylbenzoquinone (DBMIB). After the laser excitation of the reactioncenter in the presence of DBMIB, only the P680⁺-(DBMIB^-) statewas detected. P680⁺ mainly decayed with a t_1/e of 11 ms. Inthe absence of DBMIB, the excitation produced the P680⁺H^- radicalpair. The radical pair produced the triplet state (P680^T) witha t_1/e of 50 ns, and P680^T then decayed with a t_1/e of 2.1 ms.It was concluded that H_- was oxidized by DBMIB in a time rangefaster than the detecting time resolution (3.5 ns) even at 77K. The rapid oxidation of H^- by DBMIB was also confirmed bythe suppression of delayed fluorescence with a decay t_1/e of50 ns. The P680⁺(DBMIB^-)/P680(DBMIB) difference spectrum exhibiteda Q_y, band with a peak at 682 nm with a shoulder at 673 nm.The spectral shape was almost temperature insensitive between77 and 265 K. The feature of this spectrum in the wavelengthrange between 330 and 720 nm was compared with that of P680_T/P680or H^-/H at 77 K. (Received May 8, 1996; Accepted June 24, 1996)     

Properties of Chlamydomonas Photosystem II Core Complex with a His-Tag at the C-Terminus of the D2 Protein

A His-tagged PSII core complex was purified from recombinantChlamydomonas reinhardtii D2-H thylakoids by single-step Ni²⁺-affinitycolumn chromatography and its properties were partially characterizedin terms of their PSII functions and chemical compositions.The PSII core complex that has a His-tag extension at the C-terminusof the D2 protein evolved oxygen at a high rate of 2,400 µmol(mg Chl)^–1h^–1 at the optimum pH of 6.5 with ferricyanideand 2,6-dichlorobenzoquinone as electron acceptors in the presenceof Ca²⁺ as an essential cofactor, and approximately 90% of theactivity was blocked by 10 µM DCMU. The core complex exhibitedthe thermoluminescence Q-band but not the B-band regardlessof the presence or absence of DCMU, although both bands wereobserved in the His-tagged thylakoids. The core complex wasfree from PSI and contained one Y_D, Tyr 160 of the D2 protein,four Mn atoms, two cytochrome b-559, about 46 Chl a molecules,and probably one Q_A, the primary acceptor quinone of PSII. Itwas inferred from these results that His-tagging at the C-terminusof the D2 protein does not affect the functional and structuralintegrity of the PSII core complex, and that the ‘His-tagstrategy’ is highly useful for biochemical, physicochemical,and structural studies of Chlamydomonas PSII. (Received October 22, 1998; Accepted December 25, 1998)     

Secondary pair charge recombination in photosystem I under strongly reducing conditions: temperature dependence and suggested mechanism.

Photoinduced electron transfer in photosystem I (PS I) proceeds from the excited primary electron donor P700 (a chlorophyll a dimer) via the primary acceptor A0 (chlorophyll a) and the secondary acceptor A1 (phylloquinone) to three [4Fe-4S] clusters, Fx, FA, and FB. Prereduction of the iron-sulfur clusters blocks electron transfer beyond A1. It has been shown previously that, under such conditions, the secondary pair P700+A1- decays by charge recombination with t1/2 approximately 250 ns at room temperature, forming the P700 triplet state (3P700) with a yield exceeding 85%. This reaction is unusual, as the secondary pair in other photosynthetic reaction centers recombines much slower and forms directly the singlet ground state rather than the triplet state of the primary donor. Here we studied the temperature dependence of secondary pair recombination in PS I from the cyanobacterium Synechococcus sp. PCC6803, which had been illuminated in the presence of dithionite at pH 10 to reduce all three iron-sulfur clusters. The reaction P700+A1- --> 3P700 was monitored by flash absorption spectroscopy. With decreasing temperature, the recombination slowed down and the yield of 3P700 decreased. In the range between 303 K and 240 K, the recombination rates could be described by the Arrhenius law with an activation energy of approximately 170 meV. Below 240 K, the temperature dependence became much weaker, and recombination to the singlet ground state became the dominating process. To explain the fast activated recombination to the P700 triplet state, we suggest a mechanism involving efficient singlet to triplet spin evolution in the secondary pair, thermally activated repopulation of the more closely spaced primary pair P700+A0- in a triplet spin configuration, and subsequent fast recombination (intrinsic rate on the order of 10(9) s(-1)) forming 3P700.     

Photosynthetic Properties of Guard Cell Protoplasts from Vicia faba L.

Guard cell protoplasts were isolated enzymatically from theepidermis of Vicia faba L. and their photosynthetic activitieswere investigated. Time courses of light-induced changes inthe chlorophyll a fluorescence intensity of these protoplastsshowed essentially the same induction kinetics as found formesophyll protoplasts of Vicia. The transient change in thefluorescence intensity was affected by DCMU, an inhibitor ofphotosystem II; by phenylmercuric acetate, an inhibitor of ferredoxinand ferredoxin NADP reductase; and by methyl viologen, an acceptorof photosystem I. Low temperature (77 K) emission spectra ofthe protoplasts had peaks at 684 and 735 nm and a shoulder near695 nm. A high O₂ uptake (175 µmol mg^–1 Chl hr^–1)was observed in guard cell protoplasts kept in darkness, whichwas inhibited by 2 mM KCN or NaN₃ by about 60%. On illumination,this O₂ uptake was partially or completely suppressed, but itssuppression was removed by DCMU, which indicates that oxygenwas evolved (150 µmol mg^–1 Chl hr^–1) photosynthetically.We concluded that both photosystems I and II function in guardcell chloroplasts and that these protoplasts have high respiratoryactivity. (Received January 30, 1982; Accepted May 15, 1982)     

Phototransformation of the Far-red Light-absorbing Form of Large Pea Phytochrome by Laser Flash Excitation

Phototransformation of the far-red light absorbing form (P_FR)of large pea phytochrome to the red-light absorbing form (P_R)was examined at 2?C after a 715 nm laser flash excitation usinga custom-built multichannel transient spectra analyzer. Themaximum amount of phototransformation intermediates was producedby a pulse of about 50 mJ, which resulted in ca. 65% of P_R obtainedat the photostationary equilibrium. Some flash-induced intermediateswere assumed to return to P_FR in the dark. A difference spectrummeasured at 10 µsec after the flash showed an absorbanceincrease at 651 nm and a decrease at 724 nm. When the samplewas left in darkness after the flash light irradiation, absorbancein the red and far-red region gradually increased, but thatin the green region rapidly decreased. The decay curve of intermediatesmeasured at 554 nm could be resolved into three reaction componentshaving rate constants of 2,500, 590 and 48 sec^–1, respectively.Difference spectra also indicated that a small but significantincrease in absorbance between 370 and 380 nm and a decreasearound 415 nm took place 10–310 µsec after a flash. (Received February 13, 1982; Accepted April 21, 1982)     

Effect of Oxygen on Photosynthetic 14CO2 Fixation in Chroomonas sp. (Cryptophyta) II. Effects of Inhibitors, Uncouplers and an Artificial Electron Mediator on the Inhibition of 14CO2 Fixation by Anaerobiosis

In "air-grown" Chroomonas sp. cells, low concentrations of DCMU(less than 0.1 µM) could prevent the inhibition of ¹⁴CO₂fixation by anaerobiosis under light-saturating conditions (morethan 40 W.m^–2), with phenazine methosulfate showing asimilar effect. Antimycin A, carbonyl cyanide m-chlorophenylhydrazone(CCCP), and N,N'-dicyclohexylcarbodiimide strongly inhibitedanaerobic photosynthesis at concentrations which did not significantlyinhibit the rate under 2% O₂ at high light intensity (200 W.m^–2),although 0.2 µM CCCP stimulated the rate under 2% O₂ tosome extent. On the other hand, KCN inhibited the rate muchmore strongly under 2% O₂ than N₂, although it inhibited therate very strongly at concentrations above 5 µM both underN₂ and 2% O₂. These results suggest that the inhibition of photosynthetic¹⁴CO₂ fixation by anaerobiosis in this alga result from ATPdeficiency caused by over-reduction of electron carriers ofthe cyclic electron flow and that oxygen can prevent the over-reduction.Cyclic electron flow seems to be necessary to provide additionalATP for CO₂ reduction under anaerobic conditions, although itseems to be less necessary under aerobic conditions. (Received July 21, 1983; Accepted January 23, 1984)