Effect of Supra-High Irradiation on the Photosynthetic System of the Cyanophyte Synechocystis PCC 6714

Stability of thylakoid components under supra-high irradiancewas studied with the cyanophyte Synechocystis PCC 6714. Theactivity of overall photosynthesis was quickly inactivated (T_1/2=20min) under supra-high irradiance (300 W m^–2, white light).In parallel with the inactivation of photosynthesis, QA in PSII was also inactivated. Both inactivations were acceleratedby chloramphenicol (CAP) addition. The reactivation of PS IIrequired weak irradiation and was suppressed by CAP. However,PS I measured as P700 was very stable. The level of PS I measuredas P700 was not significantly reduced by the irradiation for12 h even in the presence of CAP while the level of Cyt b₅₅₉,component of PS II, was decreased markedly. The function ofPS I before and after supra-high irradiation with CAP was examinedby comparing sizes of P700 oxidation induced by a short flash,by a continuous light, and by determination of O₂-and ferredoxin-reduction.No difference was observed in PS I actions before and afterthe irradiation treatment. These results indicate that the PSI complex is very tolerant of supra-high irradiation. However,the cells grown under supra-high irradiance contained much fewerPS I and PS II complexes than Cyt b₆–f complexes. Theformer levels were reduced to a half to one fourth of thosebefore growth while the level of Cyt b₆–f complex wasnot reduced so much. A possible mechanism for changes in thylakoidcomposition under supra-high irradiation was discussed. (Received February 16, 1991; Accepted June 12, 1991)     

Characterization of New Strains of Nonphotosynthetic Mutants of Chlamydomonas reinhardtii III. Photosystem II-Related Thylakoid Proteins in Five Mutants and Double Mutants

PS II-enriched particles of the wild type, of three mutantsand of two double mutants of Chlamydomonas reinhardtii wereanalyzed by lithium dodecylsulfate polyacrylamide gel electrophoresisat 4°C. The mutant Pg 27 was devoid of light-harvestingChl-protein complex (CP) CP II, but had normal cytochrome b-559and displayed all wild type photochemical activities. The mutantFl 50 lacked a pool of cytochrome b-559 photooxidizable at 77K but was able to photooxidize a second pool at 293 K in thepresence of FCCP; it showed some weak PS II activity. The mutantFl 39 lacked both these cytochrome b-559 pools and did not displayany PS II activity. The double mutants Fl 39 Pg 28 and Fl 50Pg 27 had defects similar to those of their respective parentsFl 39 or Fl 50 but, in addition, they were devoid of Chi b andof CP II. In these four mutants having impaired PS II function,five proteins of M_r=50,000, 47,000, 33,000, 27,000 and 19,000were totally (Fl 39, Fl 39 Pg 28) or partly (Fl 50, Fl 50 Pg27) missing. The first two of these proteins corresponded tothe apoproteins of CP III and IV. These results pointed out a strong correlation between thesefive proteins, cytochrome b-559 and PS II primary photochemistry.In mutation and cross experiments, these five PS II-associatedproteins and cytochrome b-559 appeared to be linked characterscontrolled by nuclear gene(s), but they behaved independentlyof CP II. (Received January 24, 1983; Accepted July 20, 1983)     

Functional Structure of the Oxygen-Evolving Unit of Photosystem II as Determined by Radiation Inactivation

The size of the complex that is essential for the electron-transferactivity from the oxygen-evolving center to the secondary electronacceptor, Q_B, is about 250 kDa, as determined by target-sizeanalysis after the radiation inactivation of functions of photosystemII (PS II). Inter-Chl tranfer of excitation energy was insensitiveto the radiation inactivation indicating that the masses ofCP47, CP43, and light-harvesting Chi a/b proteins are not includedin the functional size of the oxygen-evolving PS II complex.The transfer of electrons from the secondary electron donor,Z, to Q_B was catalyzed by a unit of only 65 kDa. The sizes ofthe complexes involved in these light-induced functions of PSII were dependent on the intensity of actinic light. Under saturatingintensities of light, the functional size of the complex fortransfer of electrons from Z to Q_B was 38 kDa, with a correspondingdecrease in the size of the oxygen-evolving PS II from 250 kDato 125 kDa [Takahashi, Mano and Asada (1985) Plant Cell Physiol.26: 383]. The protein of about 30 kDa functions in the photoreductionof the pheophytin molecule, as well as in the electron transferfrom Z to Q_A. Under low-intensity light, complexes having thesame sizes as those of the basal functional complexes undersaturating-intensity light are further required, probably tostabilize separated charges in the PS II reaction center andthe oxygen-evolving center. (Received June 20, 1990; Accepted September 18, 1990)     

Regulation of Electron Transport Composition in Cyanobacterial Photosynthetic System: Stoichiometry among Photosystem I and II Complexes and Their Light-Harvesting Antennae and Cytochrome b6/fComplex

This study was done to confirm our previous observation withthe pattern of changes in electron transport composition inducedby an imbalance of the electron transport state. Contents ofphotosystem (PS) I and II complexes and their antennae and Cytb₆/f complex were determined for systems of cyanobacterium SynechocystisPCC 6714 of different PS I/PS II ratios. The results indicatedthat (1) the observed changes in the PS I/PS II ratio are not-dueto regulation of the activities of the respective PS's but tochanges in their contents, (2) the molar ratio between PS IIand Cyt b₆/f complexes was fairly constant when marked changesoccurred in the PS I content, and (3) the PS II and Cyt b₆/fcontents per cell remained fairly constant while the PS I contentchanged markedly. These findings agree with our previous observationwith autotrophic cells of Anacystis nidulans Tx 20 and supportour argument that in cyanobacterial and red algal electron transportsystems, the content of the terminalcomponent(s), such as PSI complex, is regulated in order to maintain a balance betweenthe electron influx by PS II action to the system and the effluxby PS I action from it. (Received June 3, 1987; Accepted September 20, 1987)     

Chromatic Regulation of Cytochrome Composition and Electron Transfer from Cytochrome b6-f Complex to Photosystem I in Anacystis nidulans (Tx 20)

Cytochrome composition of the cyanobacterial photosyntheticsystem was studied with Anacystis nidulans (Tx 20) in relationto the chromatic regulation of photosystem composition. Comparisonof cytochrome compositions in cells with a high PS I/II ratio(3.0, grown under weak orange light) and with a low ratio (1.6,grown under weak red light) indicated that cytochrome compositionwas also changed in the chromatic regulation of photosystemcomposition. Two types of cytochrome change were observed: 1)contents of cytochromes C₅₅₃ and c₅₄₈ were changed in parallelwith the changes in PS I content, and 2) cytochrome b₅₅₃ andcytochrome b₆-f complex were held at a constant molar ratioto PS II. The molar ratio, PS II : cytochrome b₅₅₉ : cytochromeb₆-f complex : cytochrome c₅₅₃ : PS I : cytochrome C₅₄₈, inthe red-grown cells was 1 : 2.5 : 1.3 : 0.17 : 1.6 : 0.67, andthe ratio in the orange-grown cells, 1:2.4:0.9:0.32:3.0:1.2.In both types of cells, almost all cytochrome f in the cytochromeb₆-f complex was rapidly oxidized after multiple flash activation,indicating that all cytochrome b₆-f complexes in cells of bothtypes are functionally connected to PS I, even when the molarratio to PS I is largely changed. The content of cytochromeC₅₅₃ was at most 0.14 of PS I, suggesting that the cytochrometurns over several times per one turnover of PS I. ¹Present address: Department of Biology, Faculty of Science,Tokyo Metropolitan University, Fukazawa 2-1-1, Setagaya, Tokyo158, Japan. (Received January 20, 1986; Accepted March 17, 1986)     

Purification and Characterization of Arginine Decarboxylase from Soybean (Glycine max) Hypocotyls

Arginine decarboxylase (EC 4.1.1.19 [EC] ) was purified from soybean,Glycine max, hypocotyls by a procedure which includes ammoniumsulfate fractionation, acetone precipitation, gel filtrationchromatography, and affinity chromatography. Using this procedure,ADC was purified to one band in non-denaturing PAGE. The purifiedADC has an M_r of 240 kDa based on gel filtration chromatographyand is a trimer of identical subunits which has an estimatedM_r of 74 kDa based on SDS-PAGE. ADC is active between 30 and50°C and has a K_m value of 46.1 µM. ADC is very sensitiveto agmatine or putrescine but not to spermidine or spermine.In the presence of 0.5 mM agmatine (or putrescine), the enzymeactivity was inhibited by 70%. However, at the same concentrationof spermidine (or spermine), the enzyme activity was inhibitedby only 10–20%. (Received April 2, 1997; Accepted August 18, 1997)     

Allocation of Organ Biomass in Perfect and Imperfect Flowers

Perianth M_P, gynoecium M_G, and androecium M_A dry-weight biomass(in g) of 39 species of perfect flowers was measured. Thesedata were pooled with published data from an additional 51 speciesand used to determine size-dependent variations in (M_G and M_A)in terms of the hypothesis that the quotient of M_G and M_A exceeds1·0 for out-breeding (xenogamous) species and less than1·0 for in-breeding (autogamous) species. Ordinary leastsquare regression of the pooled data (n = 90) showed M_G = 0·118M^0·916_P (r² = 0·884) and M_A = 0·186 M^0·975_P(r² = 0·865), indicating that the biomass of the gynoeciumproportionally decrease as floral size increases. The exponentsof these regressions indicate that the ratio of gynoecial toandroecial biomass decreased with increasing floral size suchthat comparatively small flowers (M_P < 0·0021 g) hadM_G/M_A > 1·0 (predicted for 'out-breeders') while comparativelylarger flowers (M_P > 0·0021 g) had M_G /M_A < 1·0(predicted for 'in-breeders'). Thus, on average, the type ofbreeding system was a size-dependent phenomenon. To test whether the biomass of a floral organ-type is a legitimateindicator of gender reproductive effort, the biomass (in g)of stamen filaments M_m and anther sacs M_AS of 39 species wasdetermined. Least square regression of these data showed M_AS= 0·188 M^0·854_fil (r² = 0·967), indicatingthat species with larger stamen filaments, on the average, boreproportionally smaller anther sacs and thereby cautioning againstthe uncritical use of the allocation of biomass to floral organ-typeas a strict gauge of gender-function investment. To determine whether the loss of one gender-function resultsin proportional reallocation of biomass to the remaining gender-function,the size-dependency of androecial and gynoecial biomass wasdetermined for a total of 33 perfect and imperfect flowers ofCucumis melo. Regression of the data obtained from perfect flowersyielded M_A = 0·402 M^1·47_P (r² = 0·898)and M_G = 4·63 M^1·36_P (r² = 0·842). SinceM_G/M_A M^0·11_P , the biomass allocation to the gynoeciumrelative to the androecium decreased with increasing floralsize. This result was consistent with the broad interpecificcomparison based on 90 species with perfect flowers . Regressionof the data for imperfect flowers yielded M_A = 0·151M^1·02_P (r² = 0·675) and M_G = 4·68 M^1·47_P(r² = 0·996), indicating a near allometric relation forthe androecium and a strong positive anisometry for the gynoecium.Thus, for flowers of comparable size, a loss of female genderobtains a modest to significant again in androecial biomasswhereas the loss of male gender yields only a slight increasein gynoecial biomass. Collectively, the results of these studies indicate that biomassallocation patterns are size-dependent phenomena whose complexitieshave been largely ignored in the literature.Copyright 1993,1999 Academic Press Allometry, floral biomass, reproduction     

Regulation of Photosystem Stoichiometry in the Photosynthetic System of the Cyanophyte Synechocystis PCC 6714 in Response to Light-Intensity

Light-induced changes in stoichiometry among three thylakoidcomponents, PS I, PS II and Cyt b₆-f complexes, were studiedwith the cyanophyte Synechocystis PCC 6714. Special attentionwas paid to two aspects of the stoichiometric change; first,a comparison of the patterns of regulation in response to differencesin light-intensity with those induced by differences in light-quality,and second, the relationship between regulation of the stoichiometryand the steady state of the electron transport system. Resultsfor the former indicated that (1) the abundance of PS I on aper cell basis was reduced under white light at the intensityas high as that for light-saturation of photosynthesis, butPS I per cell was increased under low light-intensity, (2) PSII and Cyt b₆-f complexes remained fairly constant, and (3)changes in the abundance of PS I depended strictly on proteinsynthesis. The pattern was identical with that of chromaticregulation. For the second problem, the redox steady-statesof Cyt f and P700 under white light of various intensities weredetermined by flash-spectroscopy. Results indicated that (1)Cyt f and P700 in cells grown under low light-intensity [highratio of PS I to PS II (PS I/PS II)] were markedly oxidizedwhen the cells were exposed to high light-intensity, while theyremained in the reduced state under low light-intensity. (2)After a decrease in the abundance of PS I, most of P700 remainedin the reduced state even under high light-intensity, whilethe level of reduced Cyt f remained low. (3) Both Cyt f andP700 in cells of low PS I/PS II were fully reduced under lowlight-intensity, and Cyt f reduction following the flash wasrapid, which indicates that the turnover of PS I limits theoverall rate of electron flow. After an increase in the abundanceof PS I, the electron transport recovered from the biased state.(4) The redox steady-state of the Cyt b₆-f complex correlatedwell with the regulation of PS I/PS II while the state of thePQ pool did not. Based on these results, a working model ofthe regulation of assembly of the PS I complex, in which theredox steady-state of the Cyt b₆-f complex is closely relatedto the primary signal, is proposed. (Received August 2, 1990; Accepted December 10, 1990)     

Characterization of Storage Proteins in Daucus carota L.: Two Novel Proteins Display Zygotic Embryo Specificity

Although maturation-related proteins are well known in the endospermof albuminous seeds, an important question is whether the zygoticembryo possesses its own maturation proteins. We report on theisolation and partial characterization of storage proteins ofcarrot (Daucus carota L. var Nandor) dry achenes and isolatedzygotic embryos, using one- and two-dimensional electrophoresistechniques, HPLC and amino acid sequencing. The presence ofa series of abundant polypeptides showing charge heterogeneity,that are rapidly degraded upon germination, was revealed inthe endosperm. These proteins consisted of glycoproteins, themost abundant of which displayed a molecular mass (M_r) of 58,000,albumins of M_r 42,000 comprising at least one rß-1,3-glucanase,and two globulins of M_r 90,000 and 50,000–55,000 respectively,the second being an oligomer composed of three subunits of M_r13,000, 20,000 and 30,000. None of these storage proteins identifiedin the endosperm were detected in zygotic embryos. In contrast,two novel proteins were isolated from zygotic embryos, namelya globulin family of M_r 50,000 and pI 6.3–6.8, which wasnamed "daucin", and a late embry-ogenesis abundant (LEA) proteinfamily of M_r 25,000 and pI6.3–6.6, named "RAB25". Sincethe latter proteins are apparently absent of the endosperm,these results suggest that the maturation of carrot zygoticembryos requires its own specific set of storage and LEA proteins. (Received July 15, 1997; Accepted October 28, 1997)     

Identification of Stylar RNases Associated with Gametophytic Self-Incompatibility in Almond (Prunus dulcis)

Stylar proteins of 13 almond (Prunus dulcis) cultivars withknown S-genotypes were surveyed by IEF and 2D-PAGE combinedwith immunoblot and N-terminal amino acid sequence analysesto identify S-RNases associated with gametophytic self-incompatibility(SI) in this plant species. RNase activities corresponding toS_a and S_b, two of the four S-alleles tested, were identifiedby IEF and RNase activity staining. The S_a-RNase band reactedwith the anti-S₄serum prepared from Japanese pear (Pyrus serotina);no reaction with the antiserum was observed with the s_bRNaseband. When the s_a-RNase band was excised from an IEF gel stainedfor RNase activity, subjected to SDS-PAGE, and detected by immunoblotting,it appeared that this band consisted of a single protein thatreacted with the anti-s₄serum with M_r of about 28 kDa. With2D-PAGE and silver staining of the stylar extracts, all fourS-proteins could be successfully distinguished from each otherin the highly basic zone of the gel. Although S_b-, S_c-, andS_dproteins had roughly the same M_r of about 30 kDa, the S_c-proteinseemed to be slightly smaller than the S_b-protein and slightlylarger than the S_aprotein. In 2D-PAGE profiles as well, theS_a-protein had M_r of about 28 kDa, apparently smaller than theother three proteins. A bud sport, in which one of the two S-allelesof the original cultivar is impaired, was visualized as a lossof S_cprotein, which is consistent with the previous pollinationstudy. All four S-proteins reacted with the anti-S₄serum, probablybecause of the differing conformations of these S-proteins inthe IEF and 2D-PAGE gels. The S_a-protein in 2D-PAGE appearedto be identical to S_a-RNase in IEF; both bad the same M_r andwere reactive with the anti-S₄-serum. N-terminal amino acidsequence analysis of the four 5-proteins revealed that theywere highly homologous to each other and similar to the 5-RNasesof Malus, Pyrus, Scrophulariaceae, and Solanaceae. Taken together,RNases in the style are strongly suggested to be associatedwith the gametophytic SI of al- mond. This is the first reportidentofiying and characterizing S-RNase in almond. (Received July 11, 1996; Accepted December 26, 1996)     

Molecular Structure of a High-Potential Form of Thylakoid Cytochrome b-559 as Determined by Radiation Inactivation

Cytochrome b-559 in photosystem II can be characteristicallyconverted from a high- to a low-potential form. Taking thisresponse of Cyt b-559 as evidence for the denaturation of proteinmolecules, the sizes of the structures that stabilize the high-potentialform of Cyt b-559 in PS II membranes and thylakoids from spinachwere determined by radiation inactivation. When a target of26 kDa was inactivated in PS II membranes, Cyt b-559 was convertedto the low-potential form. The size was consistent with a molecularweight of Cyt b-559 in a proposed tetrameric structure thatconsists of two sets of 9.2-kDa and 4.3-kDa subunits [Widgeret al. (1985) FEBS Lett. 191: 186–190]. In contrast tothe functional size of 26 kDa in the PS II membranes, the functionalsize was 116 kDa in thylakoid membranes. The results suggestthe presence of an extra 90-kDa electron carrier between a redoxtitrator outside the membranes and the Cyt b-559, which maynot expose its active site to the surface of the thylakoids. (Received March 9, 1989; Accepted June 23, 1989)     

Effects of CaCl2-washing on EPR Signals of Cytochrome b559 in Photosystem II Preparation from Spinach Chloroplasts

Washing of PS II preparation by 1 M CaCl₂ inactivates oxygenevolution without loss of bound manganese [Ono and Inoue (1983)FEBS Lett. 164: 255]. Most of the high-potential Cyt b₅₅₀, whichamounts to about a half of the total Cyt b₅₅₉ in untreated preparation,was converted to its low-potential form by CaCl₂-washing. Theeffect was similar to that of Tris-washing. The peak positionof the g_s band of the EPR spectrum of the CaCl₂-washed preparation(g=2.95) was the same as that of the low potential form of untreatedpreparation but was slightly different from that of the Tris-washedor heat-treated preparation (g=2.98). ¹ Present address: Department of Biology, Faculty of Science,Tokyo Metropolitan University, Fukazawa 2-1-1, Setagaya, Tokyo158, Japan. (Received November 14, 1984; Accepted January 30, 1985)     

Preliminary Characterization of Glutathione S-Transferases That Accumulate in Callus Cells of Pumpkin (Cucurbita maxima Duch.)

Glutathione S-transferases (GSTs; EC 2.5.1.18 [EC] ) in sarcocarptissue of pumpkin (Cucurbita maxima Duch.) fruit and in callusinduced from the tissue were examined. The specific activityof GST in the callus was 6.9-fold higher than that in the tissue.The specific activity in the callus remained constant duringcultivation. Column chromatography on DEAE-cellulose, hydroxylapatite,and S-hexylglutathione-agarose was used to fractionate solubleproteins that were precipitated by ammonium sulfate at 30% to70% saturation from homogenates of the sarcocarp tissue of pumpkinfruit and the callus and GST activity was monitored. Two andseven isozymes of GST were identified in the tissue and in thecallus, respectively. Furthermore, column chromatography onSephadex G-200 and SDS-polyacrylamide gel electrophoresis, indicatedthat these GST isozymes were homo- and heterodimers of subunitsof M_r 22,000 (Puga), and 23,000 (Pugb), 24,000 (Pugc) or 24,500(Pugd). Puga and Pugb were predominant in the sarcocarp tissueand in the callus, respectively. Puga, Pugb, Pugc and Pugd hadacidic pI values of 5.45, 5.00, 5.35 and 5.75, respectively.Rabbit antiserum against Pugb did not cross-react with the threeother subunits of GST during immunoblotting. (Received July 15, 1993; Accepted December 14, 1993)     

Regulation of the Stoichiometry of Thylakoid Components in the Photosynthetic System of Cyanophytes: Model Experiments Showing that Control of the Synthesis or Supply of Chl a can Change the Stoichiometric Relationship between the Two Photosystems

Regulation of the assembly of the photosystem I (PS I) complexin response to the light regime in the photosynthetic systemof cyanophytes was studied in Synechocystis PCC 6714. The relationshipbetween the assembly of the PS I complex and synthesis of Chla was examined by model experiments in which synthesis of Chla was controlled by two inhibitors, gabaculine (GAB) and 2,2'-dipyridyl(DP). Both inhibitors caused a change to a lower ratio of PSI to PS II even under light that normally induces a high ratioof PS I to PS II. The change in stoichiometry induced by theseinhibitors was suppressed when protein synthesis was inhibitedby chloram-phenicol, similarly to the change in the stoichiometryinduced by light that excites mainly PS I (PS I light). Comparisonof the levels of PS I, PS II and Cyt b₆-f complexes per cellindicated that a selective suppression of the assembly of thePS I complex was induced by the inhibitors: the stoichiometricrelationship among PS I, PS II and Cyt b₆-f complexes was identicalto that induced by PS I light or white light of high intensity.GAB induced a decrease in size of the phycobilisome also, whileDP did not, similarly to PS I light. The results indicate thatthe ratio of PS I to PS II can be changed by the control ofsynthesis of Chl a. They also suggest that control of the synthesisor supply of Chl a probably exerted at site(s) in or after theprocess of the Mg-protoporphyrin branch, is involved in themechanism of regulation of the assembly of the PS I complexin cyanophytes. (Received September 7, 1989; Accepted November 20, 1989)     

Ganglioside-binding proteins in skeletal and cardiac muscle

Several ganglioside-binding proteins have been identified inguinea pig skeletal and cardiac muscle. In the cytosolic fractionsof both tissues, a 130-kD protein was found to have the highestpropensity to bind lucifer yellow CH-labelled G_M1. This bindingcould be abolished by prior incubation of the protein with G_M2.Polysialogangliosides including G_D1a, G_D1b, G_T1b, and G_Q1b wereless effective. The 130-kD protein migrated as a doublet withapparent isoelectric points (pI) of 6.3 and 6.5, respectively,in isoelectric focusing gel, but as a single species with anapparent M_r of 43000 in SDS-polyacrylamide gel. Both the ganglioside-bindingand the immunological properties of the 43-kD subunit proteinwere different from those of rabbit skeletal muscle actin. Cardiacmuscle extract also contained a 77-kD minor ganglioside-bindingprotein that was absent in skeletal muscle. This protein hadan apparent pI of 5.4 and migrated as a 39-kD species in SDSgels. By contrast, only the particulate fraction of skeletalmuscle was found to contain a 180-kD major ganglioside-bindingprotein. Binding of fluorescent G_M1 to this protein was blockedby pre-incubation of the protein with G_M1 or G_M2. The 180-kDprotein migrated as a 98-kD species in SDS gels. However, itspropensity to bind lucifer yellow CH-G_M1 was at least 10 timesgreater than that of rabbit skeletal muscle phosphorylase b(M_r = 97400). The apparent pI (6.5) of the 180-kD protein alsowas slightly higher than that of rabbit phosphorylase. Tissuedistribution studies revealed that both the 130-kD and the 180-kDmajor ganglioside-binding proteins were muscle specific. Itis, therefore, possible that these two proteins may play someunique roles in ganglioside-related functions in muscle tissues. gangliosides ganglioside-binding proteins muscle     

Developmental Changes in Amounts of Thylakoid Components in Plastids of Barley Leaves

Changes in the amounts of several components of the photosyntheticelectron-transport system during greening of etiolated barleyleaves were studied on a "per plastid" basis. P700 and Q_A, whichwere initially absent from etioplasts, appeared 2 h after thestart of illumination in complete complexes of PS I and PS II,respectively. From 6 h, they increased rapidly in amount witha constant stoichiometric ratio of 1:1. Amounts of Cyt f, Cytb₆, Cyt b-559 and FeS, initially present in etioplasts at levelsthat were one-third to half of those in mature chloroplasts,also increased rapidly after 6 h of illumination. The molarratio of Cyt f, Cyt b₆ and Cyt b-559 was the same in etioplastsand in mature chloroplasts, namely 1:2:2. After 4 h of illumination,levels of FeS increased at nearly the same rate as those ofthe PS I complex. The increase in levels of all components wasmarked after 6 h of illumination, probably due to the energysupplied by developing plastids that had just become photosyntheticallycompetent. The results are discussed in relation to the timeof appearance of chlorophyll-protein complexes and photochemicalactivities. ¹ Present address: Department of Botany, Faculty of Science,Kyoto University, Kyoto, 606-01 Japan.     

An Oxygen-Evolving Photosystem II Complex Associated with the Core Substructure of the Phycobilisome from Synechococcus elongatus

Oxygen-evolving photosystem II (PS II) particles isolated fromthe thermophilic cyanobacterium Synechococcus elongatus consistedof about twenty polypeptides. Six polypeptides were identifiedby reaction with specific antisera as constituent subunit polypeptidesof oxygen-evolving PS II reaction center complexes. The mostabundant polypeptides were the and ß subunits ofallophycocyanin. Comparison with the polypeptide profile ofisolated phycobilisomes, as well as immunoblotting with an antiserumagainst the large linker polypeptide, showed that the largelinker polypeptide or some proteolytic fragments of it werepresent in the preparation. Thus, each PS II particle is, inessence, an oxygen-evolving PS II complex that is associatedwith the core substructure of the phycobilisome. Cross-linkingexperiments indicated that fragments of the large linker polypeptidesare closely associated with one another and that the Chl-carrying47- kDa polypeptide is located in close proximity to the D2protein and the extrinsic 33-kDa protein. (Received November 12, 1991; Accepted January 23, 1992)     

Supramolecular Assembly and Function of Subunits Associated with the Chlorophyll a-b Light-Harvesting Complex II (LHC II) in Soybean Chloroplasts

The chlorophyll (Chl) a-b light harvesting complex II (LHC II)contains more than 80% of the light-harvesting pigments of photosystemII (PS II) in chloroplasts. The supramolecular assembly andfunction of this auxiliary antenna system was investigated inChi b-deficient and Chi b-less mutant chloroplasts from soybeanand barley plants, and in their wild-type counterparts. Fourdistinct LHC II polypeptides were resolved by SDS-PAGE (subunitsa, b, c and d), having apparent molecular masses of 29, 28,27.2 and 26.8 kDa, respectively. The analysis of LHC II subunitcomposition in different developmental stages of the PS II unitin soybean (3>Chla/Chlbb>6), indicated the associationof specific subunits with the LHC H-inner and LHC II-peripheralin the chloroplast. The amount of subunit a in PS II was constantover a broad range of Chl a/Chl b ratios, suggesting that thissubunit is closely associated with the PS II-core complex. Subunitd also appeared to be constant over a wide range of Chl a/Chlb ratios, suggesting close association with the LHC II-inner.The PS II content in subunits b and c increased with the PSII antenna development in soybean but the ratio of b/c remainedconstant in all developmental stages and equal to 2 :1. Subunita was present in the Chl b-less chlorina f2 mutant of barleygrown under continuous illumination but was absent under intermittentillumination. The results suggest that each subunit binds 13-15Chl molecules. A working hypothesis is presented on the PS IIantenna development and LHC II subunit composition in soybeanchloroplasts. (Received October 11, 1988; Accepted January 19, 1989)     

Photoactivation of Oxygen-Evolving Enzyme in Dark-Grown Pine Cotyledons: Relationship between Assembly of Photosystem II Proteins and Integration of Manganese and Calcium

Dark-grown cotyledons of pine (Pinus thunbergit) did not exhibitO₂ evolution, but this capability was rapidly activated by illuminationfor a short period (photoactivation). To examine the biochemicalchanges which accompany the process of photoactivation in gymnosperms,a method enabling the preparation of highly active O₂-evolvingphotosystem II (PS II) membranes was applied to light-grown,dark-grown, and photoactivated cotyledons. PS II membranes preparedfrom light-grown cotyledons exhibited high O₂-evolving activity,and contained all the intrinsic proteins as well as the threeextrinsic proteins (32, 23 and 17 kDa) associated with PS II.These membranes were also found to contain 4.4 Mn and 0.83 Ca/PSII reaction center. PS II membranes from dark-grown cotyledonscontained all the intrinsic proteins, but preserved only 32kDa extrinsic protein, and zero Mn and 0.85 Ca/PS II reactioncenter. The two extrinsic proteins (23 and 17 kDa) absent inthe PS II membranes from dark-grown cotyledons were, however,present as mature forms in whole thylakoid membranes from thecorresponding sample. The PS II membranes isolated from photoactivatedcotyledons showed a high activity of O₂ evolution and retainedthe three extrinsic proteins, 5.3 Mn and 1.1 Ca/PS II reactioncenter, respectively. The results indicated that Mn and thetwo extrinsic proteins were tightly integrated in the O₂-evolvingapparatusduring the process of photoactivation but integration of Capreceded the integration of Mn by photoactivation. (Received December 9, 1991; Accepted February 1, 1992)     

Thylakoid Membrane Development and Differentiation: Assembly of the Chlorophyll a-b Light-Harvesting Complex and Evidence for the Origin of Mr=19, 17.5 and 13.4 kDa Proteins

Pea plants were grown under intermittent illumination (ImL)conditions. The low dosage of light given to ImL plastids limitedthe rate of chlorophyll (Chl) a and Chl b biosynthesis and,therefore, it retarded the rate of photosynthetic unit formationand thylakoid membrane development. Depending on the developmentalstage of the photosynthetic unit, ImL plastids had variableChl a/Chl b ratios (2.7 <Chl a/Chlb<20) and showed distinctintermediates in the assembly of the chlorophyll a–b light-harvestingcomplex (LHC) of photosystem-II (PSII). The results are consistentwith a step-wise increment in the PSII antenna size involvingthree distinct forms of the PSII unit: (i) a PSII-core formwith about 37 Chl a molecules; (ii) a PSIL_ß form containingthe PSII-core and the LHC-II-inner antenna with a total of about130 Chl (a + b) molecules, and (iii) the mature PSII_a form containingPSII_ß and the LHC-II-peripheral antenna with a totalof 210–300 Chl (a + b) molecules. The thylakoid membranecontained polypeptide subunits b, c and d (the Lhcb1, 2 and3 gene products, respectively) when only the LHC-II-inner waspresent. Polypeptide subunit a, (the apoprotein of the chlorophyll-proteinknown as CP29), along with increased amounts of b and c appearedlater in the development of thylakoids, concomitant with theassembly of the LHC-II-peripheral. The results suggest thatpolypeptide subunit d has priority of assembly over subunita. It is implied that, of all LHC-II constituent proteins, subunitd is most proximal to the PSII-core complex and that it servesas a linker in the transfer of excitation energy from the bulkLHC-II (subunits b and c) to the PSII-core. The work also addressesthe origin of low-molecular-weight proteins (M_r = 19, 17.5 and13.4 kDa) which co-isolate with intact developing plastids andwhose abundance decreases during plastid development. Aminoacid compositional and immunoblot analyses show a nuclear histoneorigin for these low-molecular-weight proteins and suggest co-isolationof histone-containing nuclear vesicles along with intact developingplastids. ¹Present address: Plant Physiology Research Group, The Universityof Calgary, Department of Biological Sciences, 2500 UniversityDrive N.W., Calgary, Alberta CANADA T2N 1N4.