In vitro synthesis and assembly of photosystem II proteins of spinach chloroplasts

The synthesis and assembly of photosystem II (PS II) proteins of spinach chloroplasts were investigated in three different in vitro systems, i.e., protein synthesis in isolated chloroplasts (in organello translation), read-out translation of thylakoid-bound ribosomes, and transport of translation products from spinach leaf polyadenylated RNA into isolated chloroplasts. Polyacrylamide gel electrophoresis of labeled thylakoid polypeptides in the presence of sodium dodecyl sulfate revealed that the first two systems were capable of synthesizing the reaction center proteins of PS II (47 and 43 kDa), the herbicide-binding protein, and cytochrome b559. The reaction center proteins synthesized in organello were shown to bind chlorophyll and to assemble properly into the PS II core complex. One of the reaction center proteins translated by the thylakoid-bound ribosomes (47 kDa) was also found to be integrated in situ into the complex but was lacking bound chlorophyll. Incorporation of radioactivity into the three extrinsic proteins of the oxygen-evolution system (33, 24, and 18 kDa) was detected only when intact chloroplasts were incubated with the translation products from polyadenylated RNA, showing that these proteins are coded for by nuclear DNA. The occurrence of a precursor polypeptide 6 kDa larger than the 33-kDa protein was immunochemically detected in the translation products.     

Calmodulin antagonists inhibit electron transport in photosystem II of spinach chloroplasts

Chlorpromazine, phenothiazine and trifluoperazine, known as calmodulin antagonists, inhibit electron transport in Photosystem II of spinach chloroplasts in concentrations from 20–500 μM. The inhibition site is located on the diphenyl carbazide to indophenol pathway in Tris-treated chloroplasts, indicating that water oxidation is not affected by these drugs. Ca²⁺ ions, bound to chloroplast membranes before the addition of calmodulin antagonists, can protect against inhibition up to 25% of the electron transport rate. In presence of A23187, the Ca²⁺-specific ionophore, Ca²⁺ ions provide less protection against inhibition by the 3 calmodulin antagonists used. A possible role of a calmodulin-like protein in spinach chloroplasts is postulated.     

Photosynthetic control and photophosphorylation in photosystem II of isolated spinach chloroplasts

Two cycles of photosynthetic control have been observed in isolated spinach chloroplasts in the presence of lipophilic class III electron acceptors, which may accept electrons at PS II. $\text{ADP}\text{O}$ ratios of 0.8 to 0.9 were recorded;rates of oxygen evolution were stimulated by phosphorylating reagents and uncouplers. Addition of the plastoquinone antagonist DBMIB decreased photosynthetic control, oxygen evolution and photophosphorylation. We believe that there is a coupling site associated with PSII which can be rate limiting. Comparison of the $\text{P}\text{2e}$ ratios observed with class I and class III electron acceptors leads us to propose that more than 0.6 and possibly approaching one molecule of ATP can be formed for every pair of electrons transported from water to PSII acceptors.     

Effect of imidazole on the activity of photosystem II in spinach chloroplasts

The activity of the Hill reaction was accelerated about 2–3times in the presence of 1–5 mM imidazole. However, inchloroplasts uncoupled by carbonyl cyanide m-chlorophenylhydrazone,the acceleration of the Hill activity was not observed in thesame imidazole concentration range, but a moderate inhibitionof the activity was observed. These results suggest that inthe coupled chloroplasts, the enhanced Hill activity by imidazoleis due to uncoupling of phosphorylation. Imidazole-washing of chloroplasts at neutral pH caused a moderateinhibition of the Hill reaction to about 60% of the control,while a complete loss of the Hill activity was observed afterwashing at pH 10.5. In chloroplasts washed with imidazole atpH 10.5, the variable fluorescence yield was also diminished.These activities were restored by adding an artificial electrondonor to photosystem II. (Received October 14, 1978; )     

Selective thiol inhibition of ferricyanide reduction in photosystem II of spinach chloroplasts

Selective inhibition of ferricyanide reduction in photosystem II by lipophilic thiols indicates a unique pathway of electron transport, which is not involved in reduction of class III acceptors or transfer of electrons to photosystem I. Both aromatic and aliphatic thiols induce the inhibition, but thiol binding reagents such as p-hydroxymercuribenzoate or N-ethylmaleimide do not inhibit. The inhibition can be observed using either dibromothymoquinone or bathophenanthroline to direct electrons away from photosystem I. No pretreatment of chloroplasts with thiols in the light was necessary to inhibit ferricyanide reduction by photosystem II or the O₂ evolution associated with ferricyanide reduction.     

Specific inhibition of photosystem II activity in chloroplasts by fumigation of spinach leaves with SO2

The phytotoxic effects of sulfur dioxide (SO₂) were investigatedby fumigating spinach plants with SO₂. Inhibition of 2,6-dichloroindophenol(DCIP) photoreduction was observed in spinach chloroplasts isolatedfrom fumigated leaves. NADP and DCIP photoreductions were inhibitedto a similar extent by fumigation with 2.0 ppm SO₂ but electronflow from reduced DCIP to NADP was not affected. When electronflow from H₂O to NADP was inhibited by 36%, a 39% inhibitionof non-cyclic photophosphorylation was observed. However, phenazinemethosulfate(PMS)-catalyzed cyclic photophosphorylation wasas active as in the control chloroplasts. Moreover, in the presenceof PMS, no significant suppression was observed in the extentof light-induced H⁺ uptake or in the rate of H⁺ efflux in chloroplasts.From these results, it can be concluded that SO₂ inhibits theelectron flow driven by photosystem II when plants have beenfumigated with SO₂. In spinach leaves fumigated with SO₂, the rate of photosyntheticO₂ evolution was reduced under light-limited conditions, whilethe rate of respiratory O₂ uptake changed slightly. (Received February 8, 1979; )     

Tandem mass spectrometric identification of spinach Photosystem II light-harvesting components

Light-harvesting proteins harness light energy for photosynthesis. Sequences of the Photosystem II (PS II) light harvesting proteins, Lhcb1–6, have been deduced from many plants. However, limited information is available for spinach Lhcb sequences, although a spinach PS II preparation (BBY) is commonly used as a model for plant photosynthetic oxygen evolution [DA Berthold, GT Babcock and CF Yocum (1981) FEBS Lett 134: 231–234]. In this work, we describe the use of tryptic digestion, liquid chromatography, tandem mass spectrometry, and database searching to identify light-harvesting proteins in the spinach BBY preparation. Using this approach, partial amino acid sequences were assigned to the PS II-associated light-harvesting proteins, Lhcb1–6. The identified stretches of sequence are predicted to contain intra-membranous chlorophyll ligands, extra-membranous loop regions, and lutein-binding sites. In addition, we find that at least two distinct Lhcb4 (CP29) polypeptides and two distinct Lhcb1 polypeptides are present in the BBY preparation. One of these Lhcb4 polypeptides has a subsequence that has not been reported for Lhcb4 in any other organism. This work demonstrates the utility of tandem mass spectrometry in the characterization of photosynthetic membrane proteins. This revised version was published online in June 2006 with corrections to the Cover Date.     

Tandem mass spectrometry identifies sites of three post-translational modifications of spinach light-harvesting chlorophyll protein II. Proteolytic cleavage, acetylation, and phosphorylation

The photosynthetic membranes of spinach (Spinacia oleracea L.) chloroplasts were incubated with [gamma-32P] ATP. When the thylakoid membrane kinase was activated with light, the 25- and 27-kDa forms of the light-harvesting chlorophyll a/b protein (LHC II) were phosphorylated on their amino termini. Treatment of the membranes with proteinase K or thermolysin released phosphopeptides which were purified by ferric ion affinity chromatography and reverse phase high performance liquid chromatography. Sequencing of the phosphopeptides was performed with tandem quadrupole mass spectrometry. Three different phosphopeptides Ac-RKTAGKPKT, Ac-RKTAGKPKN, and Ac-RKSAGKPKN originating from class I LHC II were examined after release by thermolysin. One phosphopeptide, Ac-RRTVKSAPQ, originating from class II LHC II was examined after release by proteinase K. Each of the four LHC II phosphopeptides was derived from the amino terminus of a distinct protein. Peptides were acetylated at their amino-terminal arginine and were phosphorylated on either threonine or serine in the third position. We conclude that proteolytic processing of pre-LHC II occurs at a conserved methionyl-arginyl bond and is followed by amino-terminal acetylation of the arginine and nearby phosphorylation of the mature LHC II. Eight different peptides were synthesized in acetylated and nonacetylated forms as substrates for the thylakoid membrane kinase. From a comparison of the kinetics of phosphate incorporation into the peptides, we conclude that basic residues on both sides of the phosphorylation site are important for enzyme recognition. Acetylation of the amino terminus is not required for phosphorylation.     

EGTA, a calcium chelator, inhibits electron transport in photosystem II of spinach chloroplasts at two different sites

A fifteen minute incubation of spinach chloroplasts with the divalent Ca²⁺ chelator, EGTA, in concentrations 50–250 μM, inhibits electron transport through both photosystems. All photosystem II partial reactions, including indophenol, ferricyanide and the DCMU-insensitive silicomolybdate reduction are inhibited from 70–100%. The photosystem II donor reaction, diphenyl carbazide → indophenol, is also inhibited, indicating that the inhibition site comes after the Mn²⁺ site, and that the first Ca²⁺ effect noted (site II) is not on the water oxidation enzyme, as is commonly assumed, but between the Mn²⁺ site and plastoquinone A pool. The other photosystem II effect of EGTA (Ca²⁺ site I), occurs in the region between plastoquinone A and P700 in the electron transport chain of chloroplasts. About 50% inhibition of the reaction ascorbate + TMPD → methyl viologen is given by incubation with 200 μM EGTA for 15 min. Ca²⁺ site II activity can be restored with 20 mM CaCl₂. Ca²⁺ site I responds to Ca²⁺ and plastocyanin added jointly. More than 90% activity in the ascorbate + TMPD → methylviologen reaction can be restored. Various ways in which Ca²⁺ ions could affect chloroplast structure and function are discussed. Since EGTA is more likely to penetrate chloroplast membranes than EDTA, which is known to remove CF₁, the coupling factor, from chloroplast membranes, and since Mg²⁺ ions are ineffective in restoring activity, it is concluded that Ca²⁺ may function in the electron transport chain of chloroplasts in a hitherto unsuspected manner.     

Intermolecular relations of the photosystem II complex in spinach chloroplasts as detected by immunochemical assay

Polyclonal antibodies were prepared to the subunits of the spinach photosystem II fraction (PS II): p47, p43, p27, p33, p24, and p17. (The protein nomenclature refers to Mr). p47 and p43 are the subunits of reaction center complex, and p27 is light-harvesting chlorophyll protein. p33, p24, and p17 are extractable from PS II with 1 M Tris, and p24 and p17 with 1 M NaCl. With untreated PS II fractions, the antibody to p24 inhibited the photosynthetic oxygen-evolving activity, but not the DCPI-photoreduction activity in the presence of DPC, indicating that p24 played an important role in the former activity. Bindings of the respective antibodies to the PS II treated with sodium dodecyl sulfate were regarded as 100%. To untreated PS II, the bindings were 20-30% for p47, p43, and p27, about 50% for p33, and 70-80% for p24 and p17. To NaCl-washed PS II, the binding to p33 increased by 9%, indicating that p33 was adjacent or bound with p24 or/and p17. To Tris-washed PS II, the binding to p43 increased by 7%, indicating that p43 was adjacent or bound with p33. To PS II treated with 3% of Brij 58, only the binding to p27 increased appreciably. To PS II treated with 1% of octyl glucoside, the binding to p47 was still lower than 50%, whereas those to the other subunits were 74-91%. These values could be a measure of the extents to which the subunits were exposed to the aqueous phase, because of the nature of polyclonal antibodies. These results suggest that in intact PS II, p47, p43, and p27 were in most part buried in the inside, p47 being located at the most central and p27 at the outermost part, whereas p33, p24, and p17 were exposed to the outside by 50-75%.     

Annonaceous acetogenins: Naturally occurring inhibitors of ATP synthesis and photosystem II in spinach chloroplasts

The effects of squamocin ( 1 ), bullatacin ( 2 ) and motrilin ( 3 ), 3 bis-tetrahydrofuran Annonaceous acetogenins, isolated from Annona purpurea (Annonaceae), were investigated on several photosynthetic activities in spinach thylakoids. The results indicated that compounds 1 – 3 significantly inhibited both ATP synthesis and uncoupled electron transport. In addition, they enhanced light-activated Mg2+-ATPase, and basal electron flow. Therefore, acetogenins 1 – 3 behave as uncouplers and Hill reaction inhibitors. Natural products 1 – 3 did not affect photosystem I (PSI) activity but they inhibited photosystem II (PSII) electron flow. The study of the partial PSII reactions from H2O to DCPIPox, H2O to SiMo and diphenylcarbazide to DCPIP established that the site of inhibition was at the oxygen-evolving complex (OEC). Chlorophyll a fluorescence measurements confirmed the behavior of the Annonaceous acetogenins as water-splitting enzyme inhibitors.     

Inhibitory effect of p-nitrothiophenol in the light on the photosystem II activity of spinach chloroplasts.

The treatment of spinach chloroplasts with p-nitrothiophenol in the light at acidic and neutral pH'S caused specific inhibition of the Photosystem II activity, whereas the same treatment in the dark did not affect the activity at all. The photosystem I activity was not inhibited by p-nitrothiophenol both in the light and in the dark. The inhibition was accompanied by changes of fluorescence from chloroplasts. As observed at room temperature, the 685-nm band was lowered by the p-nitrothiophenol treatment in the light and, at liquid nitrogen temperature, the relative height of the 695-nm band to the 685-nm band increased and the 695-nm band shifted to longer wavelengths. The action spectra for these effects of p-nitrothiophenol on the activity and fluorescence showed a peak at 670 nm with a red drop at longer wavelengths. It was concluded that the light absorbed by Photosystem II is responsible for the chemical modification of chloroplasts with p-nitrothiopehnol to causing the specific inhibition of Photosystem II.     

Quantitative analysis of membrane components in a highly active O2-evolving photosystem II preparation from spinach chloroplasts

Stoichiometry of membrane components associated with Photosystem II was determined in a highly active O₂-evolving Photosystem II preparation isolated from spinach chloroplasts by the treatment with digitonin and Triton X-100. From the analysis with sodium dodecyl sulfate polyacrylamide gel electrophoresis and Triton X-114 phase partitioning, the preparation was shown to contain the reaction center protein (43 kDa), the light-harvesting chlorophyll-protein complex (the main band, 27 kDa), the herbicide-binding protein (32 kDa) and cytochrome b-559 (10 kDa) as hydrophobic proteins, and three proteins (33, 24 and 18 kDa) which probably constitute the O₂-evolution enzyme complex as hydrophilic proteins. These proteins were associated stoichiometrically with the Photosystem II reaction center: one Photosystem II reaction center, approx. 200 chlorophyll, one high-potential form of cytochrome b-559, one low-potential form of cytochrome b-559, one 33 kDa protein, one (to two) 24 kDa protein and one (to two) 18 kDa protein. Measurement of fluorescence induction showed the presence of three electron equivalents in the electron acceptor pool on the reducing side of Photosystem II in our preparation. Three molecules of plastoquinone A were detected per 200 chlorophyll molecules with high-performance liquid chromatography. The Photosystem II preparation contained four managanese atoms per 200 chlorophyll molecules.     

Tricolorin A, a potent natural uncoupler and inhibitor of photosystem II acceptor side of spinach chloroplasts

Tricolorin A, (11 S )-11-hydroxyhexadecanoic acid 11- O - α - l - rhamnopyranosyl-(1↠3)- O - α - l -{2- O -(2 S -methylbutanoyl)-4- O -(2 S -methylbutanoyl)}-rhamnopyranosil-(1↠2)- O - β - d -glucopyranosil-(1↠2)- β -fucopyranoside-(1,3'-lactone), the major phytogrowth inhibitor isolated from Ipomoea tricolor Cav. (Convolvulaceae) was found to be a potent uncoupler (U₅₀=0.33 μ M ) of photophosphorylation in spinach chloroplasts. Tricolorin A inhibited H⁺-uptake and adenosine 5'-triphosphate (ATP) synthesis, and stimulated basal and phosphorylating electron flows. Using a combination of two well-known fluorescent ΔpH probes, 9-aminoacridine and 9-amino-6-chloro-2-methoxyacridine, the uncoupling behavior of tricolorin A was also demonstrated for submitochondrial particles. Polarographic data showed that high concentrations (20 μ M ) of tricolorin A inhibited photosystem II (PSII) electron flow at the level of plastoquinone B (Q_B). Chlorophyll (Chl) a fluorescence analysis showed that tricolorin A induced accumulation of Q_A⁻ and strongly decreased the electron transport capacity, suggesting that the target of this molecule was located at the Q_B level. The macrocyclic lactone-type structure of this allelopathic agent proved to be an important structural requirement for uncoupling activity since its hydrolysis caused loss of the inhibitory potential.     

Effects of phospholipase A2 and alkaline pH on photosystem II particles isolated from spinach chloroplasts

An O₂-evolving photosystem II fraction (PS II particles) isolated from spinach ( Spinacia oleracea L.) chloroplasts by Triton X-100 was treated by phospholipase A₂ or by an alkaline pH. Phospholipase A₂ depleted the particles of all phosphatidylcholine and of a part of phosphatidylglycerol containing trans -hexadecenoic acid, and induced a parallel inactivation of the PS II activity. The protein pattern remained similar to that of the control particles. The addition of exogenous polar lipids from thylakoids could not reactivate PS II activity. Treatment of PS II particles by an alkaline pH, known to release the 33, 24 and 18 kdalton polypeptides and to inactivate PS II activity, did not affect the lipid composition. The involvement of lipids in PS II activity is discussed.     

Isoforms of photosystem II antenna proteins in different plant species revealed by liquid chromatography-electrospray ionization mass spectrometry

The high selectivity offered by reversed-phase high-performance liquid chromatography on-line coupled to electrospray ionization mass spectrometry has been utilized to characterize the major and minor light-harvesting proteins of photosystem II (Lhcb). Isomeric forms of the proteins, revealed either on the basis of different hydrophobicity enabling their chromatographic separation or on the basis of different molecular masses identified within one single chromatographic peak, were readily identified in a number of monocot and dicot species. The presence of several Lhcb1 isoforms (preferably in dicots) can explain the tendency of dicot Lhcb1 to form trimeric aggregates. The Lhcb1 molecular masses ranged from 24,680 to 25,014 among different species, whereas within the same species, the isoforms differed by 14-280 mass units. All Lhcb1 proteins appear to be highly conserved among different species such that they belong to a single gene group that has several different gene family members. In all species examined, the number of isoforms corresponded more or less to the genes cloned previously. Two isoforms of Lhcb3 were found in petunia and tomato. For Lhcb6, the most divergent of all light-harvesting proteins, the greatest number of isoforms was found in petunia, tobacco, tomato, and rice. Lhcb2, Lhcb4, and Lhcb5 were present in only one form. The isoforms are assumed to play an important role in the adaptation of plants to environmental changes.     

Photoprotective energy dissipation involves the reorganization of photosystem II light-harvesting complexes in the grana membranes of spinach chloroplasts

Plants must regulate their use of absorbed light energy on a minute-by-minute basis to maximize the efficiency of photosynthesis and to protect photosystem II (PSII) reaction centers from photooxidative damage. The regulation of light harvesting involves the photoprotective dissipation of excess absorbed light energy in the light-harvesting antenna complexes (LHCs) as heat. Here, we report an investigation into the structural basis of light-harvesting regulation in intact spinach (Spinacia oleracea) chloroplasts using freeze-fracture electron microscopy, combined with laser confocal microscopy employing the fluorescence recovery after photobleaching technique. The results demonstrate that formation of the photoprotective state requires a structural reorganization of the photosynthetic membrane involving dissociation of LHCII from PSII and its aggregation. The structural changes are manifested by a reduced mobility of LHC antenna chlorophyll proteins. It is demonstrated that these changes occur rapidly and reversibly within 5 min of illumination and dark relaxation, are dependent on ΔpH, and are enhanced by the deepoxidation of violaxanthin to zeaxanthin.