Topographical Studies on Subunit Polypeptides of the PS I Reaction Center Complex in the Thylakoid Membranes of the Thermophilic Cyanobacterium Synechococcus sp.

The permeability to protein molecules of the outer limitingmembranes and the thylakoid membranes in hypotonically shockedprotoplasts of the thermophilic cyanobacterium Synechococcussp. was studied by examining the effects of NaBr-washing andpronase E-digestion on phycobiliproteins and a 35 kDa proteinwhich are associated with the outer and inner surface of thethylakoid membranes, respectively, and by measuring photooxidationof added cytochrome c. All the results obtained indicate thatthe shocked protoplasts are in essence a homogenous right side-outthylakoid membrane preparation; the outer limiting membranesare leaky to protein molecules, whereas the thylakoid membranesare still impermeable to proteins. The thylakoid membranes becamepermeable to proteins when the protoplasts were mechanicallydisrupted. Following on from these findings, the membrane topology of subunitpolypeptides of the photosystem I reaction center complex wasstudied. Proteolytic digestion of shocked protoplasts with trypsinand pronase E indicated that four of the five subunit polypeptidesof the PS I reaction center complex are exposed at the stromalsurface of thylakoid membranes; two subunits of 14 and 13 kDawere selectively digested by trypsin, whereas two chlorophyll-bindingsubunits of 62 and 60 kDa were preferentially attacked by pronaseE. However, a 10 kDa subunit appears to be strongly resistantto the proteases. Experiments with mechanically disrupted protoplastsfailed to provide evidence for a uniform transmembrane organizationof the PS I subunits. (Received March 31, 1986; Accepted August 18, 1986)     

Polypeptide composition of the Photosystem I complex and the Photosystem I core protein from Synechococcus sp. PCC 6301.

The polypeptide composition of the Photosystem I complex from Synechococcus sp. PCC 6301 was determined by sodium-dodecyl sulfate polyacrylamide gel electrophoresis and N-terminal amino acid sequencing. The PsaA, PsaB, PsaC, PsaD, PsaE, PsaF, PsaK and PsaL proteins, as well as three polypeptides with apparent masses less than 8 kDa and small amounts of the 12.6 kDa GlnB (PII) protein, wee present in the Photosystem I complex. No proteins homologous to the PsaG and PsaH subunits of eukaryotic Photosystem I complexes were detected. When the Photosystem I complex was treated with 6.8 M urea and ultrafiltered using a 100 kDa cutoff membrane, the resulting Photosystem I core protein was found to be depleted of the PsaC, PsaD and PsaE proteins. The filtrate contained the missing proteins, along with five proteolytically-cleaved polypeptides with apparent masses of less than 16 kDa and with N-termini identical to that of the PsaD protein. The PsaF and PsaL proteins, along with the three less than 8 kDa polypeptides, were not released from the Photosystem I complex to any significant extent, but low-abundance polypeptides with N-termini identical to those of PsaF and PsaL were found in the filtrate with apparent masses slightly smaller than those found in the native Photosystem I complex. When the filtrate was incubated with FeCl3, Na2S and beta-mercaptoethanol in the presence of the isolated Photosystem I core protein, the PsaC, PsaD and PsaE proteins were rebound to reconstitute a Photosystem I complex functional in light-induced electron flow from P700 to FA/FB. In the absence of the iron-sulfur reconstitution agents, there was little rebinding of the PsaC, psaD or PsaE proteins to the Photosystem I core protein. No binding of the truncated PsaD polypeptides occurred, either in the presence or absence of the iron-sulfur reagents. The reconstitution of the FA/FB iron-sulfur clusters thus appears to be a necessary precondition for rebinding of the PsaC, psaD and psaE proteins to the Photosystem I core protein.     

Heat-Stability of Iron-Sulfur Centers and P-700 in Photosystem I Reaction Center Complexes Isolated from the Thermophilic Cyanobacterium Synechococcus elongatus

Stabilities of iron-sulfur centers and reaction center chlorophyllP-700 in Photosystem I reaction center complex (CP1-a), isolatedby sodium dodecyl sulfate treatment from the thermophilic cyanobacteriumSynechococcus elongatus, were studied by EPR and optical spectroscopy.P-700 was destroyed by treatment at temperatures above 80?Cfor 5 minutes with a half inactivation temperature of 93?C.The three iron-sulfur centers F_A, F_B and F_X showed similar thermalstabilities and were half inactivated at about 70?C. Thus, theisolated Photosystem I reaction center complexes of S. elongatusare still highly resistant to heat. (Received May 9, 1990; Accepted June 25, 1990)     

Light adaptation of cyclic electron transport through Photosystem I in the cyanobacterium Synechococcus sp. PCC 7942

Photosystem I-driven cyclic electron transport was measured in intact cells of Synechococcus sp PCC 7942 grown under different light intensities using photoacoustic and spectroscopic methods. The light-saturated capacity for PS I cyclic electron transport increased relative to chlorophyll concentration, PS I concentration, and linear electron transport capacity as growth light intensity was raised. In cells grown under moderate to high light intensity, PS I cyclic electron transport was nearly insensitive to methyl viologen, indicating that the cyclic electron supply to PS I derived almost exclusively from a thylakoid dehydrogenase. In cells grown under low light intensity, PS I cyclic electron transport was partially inhibited by methyl viologen, indicating that part of the cyclic electron supply to PS I derived directly from ferredoxin. It is proposed that the increased PSI cyclic electron transport observed in cells grown under high light intensity is a response to chronic photoinhibition.Abbreviations DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - ES energy storage - MV methyl viologen - PA_m photoacoustic thermal signal with strong non-modulated background light added - PA_s photoacoustic thermal signal without background light added CIW/DPB Publication No. 1205.     

Phycobilisome Mobility in the Cyanobacterium Synechococcus sp. PCC7942 is Influenced by the Trimerisation of Photosystem I

We have constructed a mutant of the cyanobacterium Synechococcus sp. PCC7942 deficient in the Photosystem I subunit PsaL. As has been shown in other cyanobacteria, we find that Photosystem I is exclusively monomeric in the PsaL(-) mutant: no Photosystem I trimers can be isolated. The mutation does not significantly alter pigment composition, photosystem stoichiometry, or the steady-state light-harvesting properties of the cells. In agreement with a study in Synechococcus sp. PCC7002 [Schluchter et al. (1996) Photochem Photobiol 64: 53-66], we find that state transitions, a physiological adaptation of light-harvesting function, occur significantly faster in the PsaL(-) mutant than in the wild-type. To explore the reasons for this, we have used fluorescence recovery after photobleaching (FRAP) to measure the diffusion of phycobilisomes in vivo. We find that phycobilisomes diffuse, on average, nearly three times faster in the PsaL(-) mutant than in the wild-type. We discuss the implications for the mechanism of state transitions in cyanobacteria.     

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)     

Triplet States in a Photosystem I Reaction Center Complex. Inhibition of Radical Pair Recombination by Bipyridinium Dyes and Naphthoquinones

Flash-induced absorption changes between 400 and 570 nm werestudied in a P700-chlorophyll a-protein complex from the thermophiliccyanobacterium Synechococcus sp. that lacked the bound secondaryelectron acceptors A₂ and P430. A positive peak at 520 nm, whichincreased linearly with the flash intensity and independentlyof the redox state of P700, is ascribed to a carotenoid triplet.Bleaching at 430 nm, which decayed with a half time of about10 µs, was abolished when P700 was oxidized with ferricyanideand saturated at a high flash intensity, indicative of its dependenceon the primary photochemistry of photosystem I. Several bipyridinium dyes and naphthoquinones suppressed the10 µs decay of the 430 nm signal in a way indicating thatthe 10 µs component represents the P700 triplet generatedby the back reaction between the reduced primary electron acceptorand oxidized P700 and that the added oxidants oxidize the reducedprimary acceptor so rapidly that back electron transfer to oxidizedP700 is prevented. Our results also show that the primary electronacceptor is located in a lypophilic environment in the chlorophyll-bindingsubunits of the photosystem I complexes. In a reaction centercomplex containing the secondary electron acceptors, the exogenousoxidants accept electrons only via P430. (Received February 23, 1984; Accepted May 1, 1984)     

Characterization of a Synechococcus sp. strain PCC 7002 mutant lacking Photosystem I. Protein assembly and energy distribution in the absence of the Photosystem I reaction center core complex

A Synechococcus sp. strain PCC 7002 psaAB::cat mutant has been constructed by deletional interposon mutagenesis of the psaA and psaB genes through selection and segregation under low-light conditions. This strain can grow photoheterotrophically with glycerol as carbon source with a doubling time of 25 h at low light intensity (10 E m^–2 s^–1). No Photosystem I (PS I)-associated chlorophyll fluorescence emission peak was detected in the psaAB::cat mutant. The chlorophyll content of the psaAB::cat mutant was approximately 20% that of the wild-type strain on a per cell basis. In the absence of the PsaA and PsaB proteins, several other PS I proteins do not accumulate to normal levels. Assembly of the peripheral PS I proteins PsaC,PsaD, PsaE, and PsaL is dependent on the presence of the PsaA and PsaB heterodimer core. The precursor form of PsaF may be inserted into the thylakoid membrane but is not processed to its mature form in the absence of PsaA and PsaB. The absence of PS I reaction centers has no apparent effect on Photosystem II (PS II) assembly and activity. Although the mutant exhibited somewhat greater fluorescence emission from phycocyanin, most of the light energy absorbed by phycobilisomes was efficiently transferred to the PS II reaction centers in the absence of the PS I. No light state transition could be detected in the psaAB::cat strain; in the absence of PS I, cells remain in state 1. Development of this relatively light-tolerant strain lacking PS I provides an important new tool for the genetic manipulation of PS I and further demonstrates the utility of Synechococcus sp. PCC 7002 for structural and functional analyses of the PS I reaction center.Abbreviations ATCC American type culture collection - Chl chlorophyll - DCMU 3-(3,4-dichlorophyl)-1,1-dimethylurea - DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - HEPES N-[2-hydroxyethyl]piperazine-N-[2-ethanesulfonic acid] - PCC Pasteur culture collection - PS I Photosystem I - PS II Photosystem II - SDS sodium dodecyl sulfate     

The structure of Photosystem I from the thermophilic cyanobacterium Synechococcus sp. determined by electron microscopy of two-dimensional crystals.

The structure of the Photosystem I (PS I) complex from the thermophilic cyanobacterium Synechococcus sp. has been investigated by electron microscopy and image analysis of two-dimensional crystals. Crystals were obtained from isolated PS I by removal of detergents with Bio-Beads. After negative staining, either single layers or two superimposed layers with a rotational different orientation were observed. The layers have a rectangular unit cell of 16.0 x 15.0 nm, which contains two PS I monomers. The monomers are arranged alternating up and down in each layer. For double-layer crystals, the images of the two layers could be separately processed by a combination of Fourier-peak-filtering and correlation averaging. Features in the two-dimensional plane can be seen with a resolution up to 1.5-1.8 nm. A model for the PS I structure was obtained by combining three-dimensional reconstructions from three tilt-series. The model shows an asymmetric PS I complex. On one side (presumably the stromal side) there is a 3 nm high ridge. This is most likely comprised of the psaC, psaD and psaE subunits. The other side (presumably the lumenal side) is rather flat, but in the center there is a 3 nm deep indentation, which possibly separates partly the two large subunits psaA and psaB.     

PsaE Is Required for in Vivo Cyclic Electron Flow around Photosystem I in the Cyanobacterium Synechococcus sp. PCC 7002

Electron transfer rates to P700+ have been determined in wild-type and three interposon mutants (psaE-, ndhF-, and psaE- ndhF-) of Synechococcus sp. PCC 7002. All three mutants grew significantly more slowly than wild type at low light intensities, and each failed to grow photoheterotrophically in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) and a metabolizable carbon source. The kinetics of P700+ reduction were similar in the wild-type and mutant whole cells in the absence of DCMU. In the presence of DCMU, the P700+ reduction rate in the psaE mutant was significantly slower than in the wild type. In the presence of DCMU and potassium cyanide, added to inhibit the outflow of electrons through cytochrome oxidase, P700+ reduction rates increased for both the psaE- and ndhF- strains. The reduction rates for these two mutants were nonetheless slower than that observed for the wild-type strain. The further addition of methyl viologen caused the rate of P700+ reduction in the wild type to become as slow as that for the psaE mutant in the absence of methyl viologen. Given the ability of methyl viologen to intercept electrons from the acceptor side of photosystem I, this response reveals a lesion in cyclic electron flow in the psaE mutant. In the presence of DCMU, the rate of P700+ reduction in the psaE ndhF double mutant was very slow and nearly identical with that for the wild-type strain in the presence of 2,4-dibromo-3-methyl-6-isopropyl-p-benzoquinone, a condition under which physiological electron donation to P700+ should be completely inhibited. These results suggest that NdhF- and PsaE-dependent electron donation to P700+ occurs only via plastoquinone and/or cytochrome b6/f and indicate that there are three major electron sources for P700+ reduction in this cyanobacterium. We conclude that, although PsaE is not required for linear electron flow to NADP+, it is an essential component in the cyclic electron transport pathway around photosystem I.     

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)     

Requirement of Manganese for Electron Donation of Hydrogen Peroxide in Photosystem II Reaction Center Complex

Mn²⁺ was required for the electron donating reaction from H₂O₂,but not for that from diphenylcarbazide (DPC), in the PS IIreaction center complex which was prepared from spinach chloroplastsby Triton X-100 extraction. The reaction center complex showeda high activity of 2,6-dichloroindophenol (DCIP) photoreductionin the presence of DPC, but a low activity with H₂O₂. The H₂O₂-supportedDCIP photoreduction was suppressed by EDTA and enhanced by asmall amount of Mn²⁺. Ca²⁺ and Mg²⁺ could not replace Mn²⁺.The activation by Mn²⁺ and its binding showed two binding sitesof Mn²⁺ in the reaction center complex, with high (1.5?10⁷ M^–1)and low (1 ? 10⁶ M^–1) binding constants. (Received November 8, 1986; Accepted April 10, 1987)     

Harvesting far-red light: Functional integration of chlorophyll f into Photosystem I complexes of Synechococcus sp. PCC 7002

The heterologous expression of the far-red absorbing chlorophyll (Chl) f in organisms that do not synthesize this pigment has been suggested as a viable solution to expand the solar spectrum that drives oxygenic photosynthesis. In this study, we investigate the functional binding of Chl f to the Photosystem I (PSI) of the cyanobacterium Synechococcus 7002, which has been engineered to express the Chl f synthase gene. By optimizing growth light conditions, one-to-four Chl f pigments were found in the complexes. By using a range of spectroscopic techniques, isolated PSI trimeric complexes were investigated to determine how the insertion of Chl f affects excitation energy transfer and trapping efficiency. The results show that the Chls f are functionally connected to the reaction center of the PSI complex and their presence does not change the overall pigment organization of the complex. Chl f substitutes Chl a (but not the Chl a red forms) while maintaining efficient energy transfer within the PSI complex. At the same time, the introduction of Chl f extends the photosynthetically active radiation of the new hybrid PSI complexes up to 750 nm, which is advantageous in far-red light enriched environments. These conclusions provide insights to engineer the photosynthetic machinery of crops to include Chl f and therefore increase the light-harvesting capability of photosynthesis.     

Reduction of Photosystem I Reaction Center in DrgA Mutant of the Cyanobacterium Synechocystis sp. PCC 6803 Lacking Soluble NAD(P)H:Quinone Oxidoreductase

Photoautotrophically grown cells of the cyanobacterium Synechocystis sp. PCC 6803 wild type and the Ins2 mutant carrying an insertion in the drgA gene encoding soluble NAD(P)H:quinone oxidoreductase (NQR) did not differ in the rate of light-induced oxygen evolution and Photosystem I reaction center (P700+) reduction after its oxidation with a white light pulse. In the presence of DCMU, the rate of P700+ reduction was lower in mutant cells than in wild type cells. Depletion of respiratory substrates after 24 h dark-starvation caused more potent decrease in the rate of P700+ reduction in DrgA mutant cells than in wild type cells. The reduction of P700+ by electrons derived from exogenous glucose was slower in photoautotrophically grown DrgA mutant than in wild type cells. The mutation in the drgA gene did not impair the ability of Synechocystis sp. PCC 6803 cells to oxidize glucose under heterotrophic conditions and did not impair the NDH-1-dependent, rotenone-inhibited electron transfer from NADPH to P700+ in thylakoid membranes of the cyanobacterium. Under photoautotrophic growth conditions, NADPH-dehydrogenase activity in DrgA mutant cells was less than 30% from the level observed in wild type cells. The results suggest that NQR, encoded by the drgA gene, might participate in the regulation of cytoplasmic NADPH oxidation, supplying NADP+ for glucose oxidation in the pentose phosphate cycle of cyanobacteria.     

Unraveling the Photosystem I Reaction Center: A History,or the Sum of Many Efforts

This article describes some aspects of the history of the discovery of the structure and function of Photosystem I (PS I). PS I is the largest and most complex membrane protein for which detailed structural and functional information is now available. This short historical review cannot cover all the work that has been carried out over more than 50 years, nor provide a deep insight into the structure and function of this protein complex. Instead, this review focuses on more personal views of some of the key discoveries, starting in the 1950s with the discovery of the existence of two photoreactions in oxygenic photosynthesis, and ending with the race towards an atomic structure of PS I.     

Crystallization of Photosystem I Complexes from the Thermophilic Cyanobacterium, Synechococcus vulcanus

PSI complexes were isolated from the thermophilic cyanobacterium,Synechococcus vulcanus, by mild detergent treatment of the thylakoidmembranes, purified by sucrose-density gradient centrifugation,and then crystallized. High resolution SDS-PAGE revealed thepresence of the product of the psaI gene in S. vulcanus PSIcomplexes and crystals. Crystals of the PSI complexes retainedall of the components of electron carriers and subunit polypeptides(including PsaX) known in cyanobacteria. (Received July 22, 1998; Accepted October 19, 1998)     

Contents of Cytochromes, Quinones and Reaction Centers of Photosystems I and II in a Cyanobacterium Synechococcus sp.

The contents of photosystem I and photosystem II reaction centers,cytochrome c-553, cytochrome c-550, cytochrome f, cytochromeb-559, cytochrome b-563, plastoquinone and vitamin K₁ in thecyanobacterium Synechococcus sp. were determined. About threephotosystem I reaction centers were present for each photosystemII reaction center. The amounts of cytochromes functioning betweenthe two photosystems were approximately half those of the photosystemI reaction center. Plastocyanin was not detected, while plastoquinoneand vitamin K₁ were present in excess of other electron carriersand reaction centers. The results indicate the importance ofplastoquinone and cytochrome c-553 for cooperation of the tworeaction centers through electron transport. ¹Present address: Toray Basic Research Laboratory, 1111 Tebiro,Kamakura, Kanagawa 248, Japan. (Received June 17, 1982; Accepted January 17, 1983)     

Photosystem stoichiometry and state transitions in a mutant of the cyanobacterium Synechococcus sp. PCC 7002 lacking phycocyanin

Phycobilisomes (PBS) function as light-harvesting antenna complexes in cyanobacteria, red algae and cyanelles. They are composed of two substructures: the core and peripheral rods. Interposon mutagenesis of the cpcBA genes of Synechococcus sp. PCC 7002 resulted in a strain (PR6008) lacking phycocyanin and thus the ability to form peripheral rods. Difference absorption spectroscopy of whole cells showed that intact PBS cores were assembled in vivo in the cpcBA mutant strain PR6008. Fluorescence induction measurements demonstrated that the PBS cores are able to deliver absorbed light energy to photosystem (PS) II, and fluorescence induction transients in the presence of DCMU showed that PR6008 cells could perform a state 2 to state 1 transition with similar kinetics to that of the wild-type cells. Thus, PBS core assembly, light-harvesting functions and energy transfer to PS I were not dependent upon the assembly of the peripheral rods. The ratio of PS II:PS I in the PR6008 cells was significantly increased, nearly twice that of the wild-type cells, possibly a result of long-term adaptation to compensate for the reduced antenna size of PS II. However, the ratio of PBS cores:chlorophyll remained unchanged. This result indicates that approximately half of the PS II reaction centers in the PR6008 cells had no closely associated PBS cores.