Photosynthetic enhancement spectra in higher plants

Enhancement spectra for photosynthesis of intact leaves of higherplants were investigated by means of the rate of CO₂ absorptionunder atmospheric conditions. Enhancement spectra for photosystem(system)II measured with a reference beam of 700 nm had twopronounced peaks at about 480 and 650 nm and lower humps at540–600 nm in all of the nine species tested. By the useof a rice mutant which lacks chlorophyll b, it was revealedthat the 650-nm peak and the middle humps in the spectrum canbe attributed mostly to chlorophyll b absorption, whereas the480-nm peak must be due to the absorption of carotenoids andchlorophyll b. Enhancement for system I in wheat had a peakat about 715 nm, and the maximum was much higher than that ofthe enhancement for system II. Enhancement between a red anda farred light for wheat was much greater for the farred lightthan for the red light in the presence of an excess amount ofthe other light. These results demonstrate that the enhancementphenomenon in higher plants is essentially the same as thatin green algae. (Received November 30, 1977; )     

Carbon and Nitrogen Yield, and N2 Fixation in White Clover Plants Receiving Simulated Continuous Defoliation in Controlled Environments

Single plants of white clover grown in controlled environments,and dependent for nitrogen on N, fixation, were defoliated at1 or 2 d intervals to 3, 2 and 1 expanded leaves per stolon(Expt 1), and to 1,0.5 (1 leaf on every alternate stolon) and0 expanded leaves per stolon (Expt 2), for 43–50 days Plants adapted to severe defoliation by developing much smallerleaves with a slightly reduced specific leaf area, more stolons,a smaller proportion of weight in leaf, root and nodules anda greater proportion of weight in stolons. The daily yield (materialremoved by defoliation) of d. wt and nitrogen generally decreasedwith severity of defoliation, as did the residual plant weight.However, the ‘efficiency’ of yield (daily yield/residualweight x 100) of dry matter and nitrogen was greater in themost severely defoliated treatments, attaining a maximum of5–6 % All plants adapted to the imposed defoliation regimes, howeversevere, with the result that even plants maintained withoutany fully expanded leaves invested a similar fraction of theirmetabolic resources in shoot and root as less severely defoliatedplants, and continued to grow and fix N₂, albeit at a very reducedrate of 1–2 mg Nd^–11. The energetic cost of N₂ fixation(acetylene reduction) remained constant in all treatments at31 mole CO₂ mole C₂H₄^–1, but there was some evidence thatrate of N₂ fixation per unit of nodule weight declined in themost harshly defoliated treatment. Trifolium repens, white clover, continous defolation, growth, N₂ fixation     

The content of photosynthetic pigments and the light conditions in the fruits and leaves of sweet pepper

Investigations were carried out on the fruits of sweet pepper at its two development stages: on green fruits, on mature red and yellow fruits and on leaves. The content of the photosynthetic pigments and the optical properties were examined. In the green fruits when compared with leaves the content of the photosynthetic pigments is smaller by 40 to 50 % and the value of the ratio: chlorophyll a/b is lower. Chlorophyll is absent in mature fruits, while the content of carotenoids is a few times higher. The optical properties of green fruits and of the leaves in the PAR (photosynthetically active radiation) range are the same. In the range 700–1100 nm the green fruits show smaller reflectance and transmittance and a few times greater absorptance of irradiation which contributes to the warming up of the seed bag, while small absorptance of leaves in this range protects them against overheating. In mature fruits, in the PAR range, the reflectance and transmittance are higher, while the absorptance of irradiation in comparison with that of green fruits is smaller. In the range 700 – 1100 nm the changes are rather small and refer to the increase of reflectance and reduction of absorptance, while the transmittance of irradiation remains unchanged.     

Blue light-induced unrolling in rice plant leaves

Blue light-induced unrolling of second leaves in rice plants(Oryza sativa L.) was studied. Light in wavelengths of 400–500nm was most effective for the induction of unrolling, whilethat of 500–800 nm had no influence. This blue light actionon unrolling was observed for both dark and light grown seedlings.Several hours of irradiation was required for the inductionof unrolling at a relatively high intensity. Red light had noinfluence on the blue light action. We concluded that blue lightaction on the unrolling of rice leaves is not mediated by thephytochrome system, but by a high energy blue light reactionwhich differs from the unrolling of wheat and barley leaves. (Received March 3, 1979; )     

Effects of blue light on respiration and carbon dioxide fixation in colorless Chlorella mutant cells

A colorless mutant of Chlorella vulgaris (Mutant #125) starvedin darkness, showed suppressed rates of respiration and darkCO₂ fixation, which were significantly recovered by illuminationwith blue light. The main CO₂ fixation product under blue lightwas aspartate. Such enhancements did not take place in cellsactively growing in the glucose medium. Both enhancing effectsof blue light (456 nm) were saturated at light intensities aslow as 400–800 erg.cm^-2.sec^-1. The action spectra forthese enhancing effects were similar to each other; both showedpeaks at 460 nm and 380 nm, which correspond to the absorptionmaxima of flavin. All these findings indicate that the samemechanism underlies the observed effects of blue light on CO₂fixation and respiration. The role of blue light which bringsabout the enhancements in CO₂ fixation and respiration is discussed. (Received June 1, 1974; )     

Differences between Spinach and Kidney Bean Plants in Terms of Sensitivity to Fumigation with NO2

Fumigation of plants of five species with NO₂ in darkness causedvisible injuries to leaves, with the most severe injuries inkidney bean plants and the least severe in spinach plants. Fumigationof these plants in the light caused virtually no visible injuries.NO₂-fumigated leaves accumulated nitrite in the darkness butnot in the light. The level of accumulated NO₂^– was decreasedby light much more rapidly in spinach leaves than in those ofkidney bean, with much less injury to spinach leaves than tothose of kidney bean. A larger amount of NO₂^– accumulatedin the trifoliate leaves of kidney bean plants cultivated withNO₃^– as a main source of nitrogen than in those of plantscultivated with NH₄⁺, and the former plants were more susceptibleto injury from NO₂ than the latter. Administration of NO₂^–to leaves of spinach and kidney bean plants induced the destructionof Chi in the light. The extent of the destruction of Chi wassmaller in spinach than in kidney bean, consistent with theirrespective responses to NO₂. The NO₂^–-induced destructionof Chi was inhibited to some extent by scavengers of free radicals.Activities of superoxide dismutase (SOD) were higher in leavesof spinach than in those of kidney bean. These results indicatethat NO₂^– is the toxic species generated by fumigationwith NO₂ and that spinach has a greater tolerance for NO₂ thankidney bean, probably as a result both of a higher capacityfor reduction of NO₂^– and a higher level of activity ofSOD. (Received June 5, 1991; Accepted January 27, 1992)     

Synchronization of Phosphorylation of a Chloroplast Protein with the Cell Division Cycle in Heterosigma akashiwo

Fumigation of plants of five species with NO₂ in darkness causedvisible injuries to leaves, with the most severe injuries inkidney bean plants and the least severe in spinach plants. Fumigationof these plants in the light caused virtually no visible injuries.NO₂-fumigated leaves accumulated nitrite in the darkness butnot in the light. The level of accumulated NO₂^– was decreasedby light much more rapidly in spinach leaves than in those ofkidney bean, with much less injury to spinach leaves than tothose of kidney bean. A larger amount of NO₂^– accumulatedin the trifoliate leaves of kidney bean plants cultivated withNO₃^– as a main source of nitrogen than in those of plantscultivated with NH₄⁺, and the former plants were more susceptibleto injury from NO₂ than the latter. Administration of NO₂^–to leaves of spinach and kidney bean plants induced the destructionof Chi in the light. The extent of the destruction of Chi wassmaller in spinach than in kidney bean, consistent with theirrespective responses to NO₂. The NO₂^–-induced destructionof Chi was inhibited to some extent by scavengers of free radicals.Activities of superoxide dismutase (SOD) were higher in leavesof spinach than in those of kidney bean. These results indicatethat NO₂^– is the toxic species generated by fumigationwith NO₂ and that spinach has a greater tolerance for NO₂ thankidney bean, probably as a result both of a higher capacityfor reduction of NO₂^– and a higher level of activity ofSOD. (Received October 4, 1991; Accepted January 31, 1992)     

Effect of Elevated CO2 on the Photosynthesis, Respiration and Growth of Perennial Ryegrass

Single, seed-grown plants of ryegrass (Lolium perenne L. cv.Melle) were grown for 49 d from the early seedling stage ingrowth cabinets at a day/night temperature of 20/15 C, witha 12 h photoperiod, and a CO₂ concentration of either 340 or680µI 1^–1 CO₂. Following complete acclimation tothe environmental regimes, leaf and whole plant CO₂ effluxesand influxes were measured using infra-red gas analysis techniques.Elevated CO₂ increased rates of photosynthesis of young, fullyexpanded leaves by 35–46% and of whole plants by morethan 50%. For both leaves and whole plants acclimation to 680µI^–1 CO₂ reduced rates of photosynthesis in bothCO₂ regimes, compared with plants acclimated to 340µll^–1. There was no significant effect of CO₂ regime onrespiration rates of either leaves or whole plants, althoughleaves developed in elevated CO₂ exhibited generally lower ratesthan those developed in 340µI I^–1 CO₂. Initially the seedling plants in elevated CO₂ grew faster thantheir counterparts in 340µI I^–1 CO₂, but this effectquickly petered out and final plant weights differed by onlyc. 10%. Since the total area of expanded and unexpanded laminaewas unaffected by CO₂ regime, specific leaf area was persistently13–40% lower in elevated CO₂ while, similarly, root/shootratio was also reduced throughout the experiment. Elevated CO₂reduced tissue nitrogen contents of expanded leaves, but hadno effect on the nitrogen contents of unexpanded leaves, sheathsor roots. The lack of a pronounced effect of elevated CO₂ on plant growthwas primarily due to the fact that CO₂ concentration did notinfluence tiller (branch) numbers. In the absence of an effecton tiller numbers, any possible weight increment was restrictedto the c. 2.5 leaves of each tiller. The reason for the lackof an effect on tillering is not known. Key words: Lolium perenne, ryegrass, elevated CO₂, photosynthesis, respiration, growth, development     

Effect of blue light on the photonastic reaction of rice leaves

Effect of blue light on the epinastic reaction of rice plantleaves (Oryza saliva L.) was studied. The inclination angleof intact leaves, when the plants were grown either in the lightor in the dark, was greatly increased by blue light irradiationbut not much increased by green, yellow, orange, red or whitelight. The effect of blue light on the epinastic reaction was,however, obscure in excised leaves, especially when they wereplaced on the horizontal. The photonastic reaction requireda prolonged irradiation of high intensity. The photosensitivesite localized at the leaf-nodal part. Response spectra forthe photonastic reaction were characterized by 2 distinct peaksat 420–440 mµ and 460–480 mµ and a fairlystrong response in the near ultra-violet region. (Received April 17, 1969; )     

An Endogenous Circadian Rhythm in the Rate of Carbon Dioxide Output of Bryophyllum: VI. ACTION SPECTRUM FOR THE INDUCTION OF PHASE SHIFTS BY VISIBLE RADIATION

A comparison has been made of the effectiveness of a 4-h exposureto equal quantum-flux densities of radiation in different zonesof the visible spectrum in shifting the phase of the endogenouscircadian rhythm of carbon dioxide metabolism in leaves of Bryoyihyllumfedtschenkoi. At an incident quantum-flux density of 8.9 ? 10^–13einsteins cm^–2 8^–1, only radiation between 600 and700 nm induced a phase shift, maximum activity being found at(560 nm. At a higher incident quantum-flux density of 1.9 ?10^–11 einsteins cm^–2 8^{– 1}, the peak of activitywas broader and extended from 560 to 700 nm. At both flux densitiesa sharp cut-off occurred at 700 nm. The action spectra are somewhat similar to the absorption spectrumof phytochrome except that they show no minor peak in the bluezone. No evidence has yet been obtained that the inductive effectof red light can be reversed by exposure to far-red radiationas in the case of a typical phytochrome-mediated response. Ultra-violet radiation at 237 nm had no effect upon the phaseof the rhythm.     

FA/FB Protein from the Spinach Photosystem I Complex: Isolation in a Native State and Some Properties of the Iron-Sulfur Clusters

The F_A/F_B protein of the photosystem I complex was isolatedfrom spinach leaves in a native state by use of anaerobic systems.The protein contained 8.5 non-heme iron atoms and 8.0 acid-labilesulfur atoms per molecule, consistent with the current conceptthat it has two [4Fe-4S] clusters. Its absorption spectrum wasvery similar to those of bacterial-type ferredoxins. The ratioof the absorbance at 390 nm to that at 280 nm was 0.6, and themolar extinction coefficient at 390 nm was 32,000 M^–.cm^–.Theoxidation-reduction properties of the iron-sulfur clusters wereexamined by redox potentiometry and EPR spectroscopy. The twoclusters were distinguishable in terms of their oxidation-reductionmidpoint potentials; their E_m values were determined to be about-470mV and-560 mV, respectively. (Received July 16, 1990; Accepted October 8, 1990)     

Inhibition of photosystem I and photosystem II in chloroplasts by UV radiation

The effects of UV radiation on the low temperature fluorescenceand primary photochemistry of PSII and PSI of spinach chloroplastswere studied. Fluorescence induction curves at –196°Cwere measured at 695 nm for PSII fluorescence and at 730 nmfor PSI fluorescence to determine both the initial F_o and finalF_M levels. The primary photochemistry of PSII was measured asthe rate of photoreduction of C-550 at – 196°C, thatof PSI as the rate of photooxidation of P₇₀₀ at –196°C.The results were analyzed in terms of a model for the photosyntheticapparatus which accounts for the yields of fluorescence andprimary photochemistry. According to this analysis UV radiationincreases nonradiative decay processes at the reaction centerchlorophyll of PSII. However, the effect of UV radiation isnot uniform throughout the sample during irradiation so thataccount must be taken of the fraction of PSII reaction centerswhich have been irradiated at any given time. UV radiation alsoinactivates P700 and causes a slight increase in nonradiativedecay in the antenna chlorophyll of PSI. All fluorescence ofvariable yield, F_V = F_M–F_o, at 730 nm is due to energytransfer from PSII to PSI so that the sensitivity of Fv to UVradiation is the same at 730 and 695 nm. ¹Present address: Department of Biology, Faculty of Science,Toho University, Narashino, Chiba 275, Japan. ²Present address: Central Research Laboratories, Fuji PhotoFilm Co., Ltd., 105 Mizonuma, Asaka-Shi, Saitama 351, Japan. (Received September 10, 1975; )     

Photosynthetic Carbon Sources of Stream Macrophytes

Rates of photosynthesis of four submerged stream macrophyteswere examined under varying pH and composition of inorganiccarbon species. Callitriche stagnatis and Sparganium simplexused only CO₂ for photosynthesis. Potamogeton crispus and P.pectinatus used HCO₃ in addition to CO₂, but with much lowerefficiency. The photosynthetic rates at air equilibrium anda total inorganic carbon concentration of 5.0 mM were 2–3times lower than maximum rates at CO2 saturation for the HCO₃users and 10–14 times lower for the CO₂ users. The CO₂compensation point of entire plants of Callitriche (2.5 µM)and Sparganium (6.0µM) was well below the equilibriumconcentration (15 µM). and the low saturation points (250–500µM) also pointed to efficient use of CO2. Callitricheand Sparganium compete successfully with HCO₃^– users inhardwater streams, which have a higher exchange and generationcapacity of CO2 than stagnant and more soft waters. Rates ofphotosynthesis of Potamogeton crispus and P. pectinatus decreasedat high pH. Depending on the two alternative hypotheses forHCO₃use, this decline can be explained by CO₃^––inhibition of HCO₃^– uptake or by increasing capacity tobuffer H+efflux from the plant. Habitats subject to high pH,e. g. small ponds with dense vegetation, may have a strong selectionfor efficient mechanisms of HCO₃ use. Key words: Photosynthesis, Macrophytes, Carbon-source     

Long-Term Chilling of Young Tomato Plants under Low Light. III. Leaf Development as Reflected by Photosynthesis Parameters

Young tomato plants were exposed to two weeks of chilling undernon-photoinhibiting or mild photoinhibiting conditions. Thedevelopment of the leaves was studied under chilling and controlconditions by measuring several physiological parameters. Agradual decrease of the efficiency of the photosynthetic apparatuswith maturation and ageing occurred in unchilled plants. Thiswas reflected by gradual changes in CO₂-saturated photosynthesisand protein and rubisco contents. Except for senescing leaves,a correlation close to 1 : 1 was observed between maximum rubiscoactivity and CO₂-saturated photosynthesis. Chlorophyll (Chl)contents and photochemical chlorophyll fluorescence quenchingshowed strong decreases only in the last phase of senescencein the oldest leaves. In plants chilled under non-photoinhibitingconditions (10C, 100–150 µE m^–2 s^–1or 6C, 30–50 µE m^-2 s^–1), a similar patternof ageing was observed, and no indications were found for aninduction of protein or rubisco degradation by chilling. Sincethese plants stopped growing in the cold, they revealed lowertotal photosynthetic capacities than unchilled plants of thesame size. When the chilling conditions were mildly photoinhibitory(6C, 100–150 µE m^–2 s^–1), a much strongerdepression of rubisco activity and photosynthetic capacity wasfound in all leaves, which was partly reversible in the youngones. This decrease in CO₂fixation capacity, in turn, led toa higher susceptibility of the chilled plants to photoinhibitionat 20C. It is concluded that the decrease of both photosyntheticcapacity and growth after long-term chilling in tomato is aconsequence of the preceeding ageing and senescing of the leavesduring chilling, in contrast to chilling-tolerant species withthe ability for acclimation to low temperatures. (Received April 26, 1993; Accepted September 7, 1993)     

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)     

Light-induced redistribution of excitation energy in leaves as observed in terms of fluorescence induction

Intact leaves of Phascolus mdgaris were illuminated with strongblue light to induce a transition of pigment states from a highfluorescent state (State I) to a low fluorescent state (StateII), and their fluorescence induction curves were measured atroom temperature and low temperature. The induction curves at –196°C were measured at 692and 730 nm in order to investigate the states of PhotosystemII and Photosystem I separately. At 692 nm, the leaves in StateII showed one level of fluorescence without any variation, F_s,which was approximately the same as the initial F_o level inState I. At 730 nm, however, the F_s level was rather close tothe maximal F_M level in State I. These results are discussed according to the model of photochemicalapparatus of photosynthesis proposed previously and interpretedthat the excitation energy is transferred directly from thereaction centers of Photosystem II to Photosystem I. (Received April 2, 1976; )     

Carbon Dioxide Fixation and Ribulose-1, 5-bisphosphate Carboxylase Activity in Intact Leaves of Sugar Beet Plants Exposed to Salinity and Water Stress

The influence of salinity in the growing media on ribulose-1,5-bisphosphate (RuBP) carboxylase and on CO₂ fixation by intactsugar beet (Beta vulgaris) leaves was investigated. RuBP carboxylase activity was mostly stimulated in young leavesafter exposure of plants for 1 week to 180 mM NaCl in the nutrientsolution. This stimulation was more effective at the higherNaHCO₂ concentrations in the reaction medium. Salinity also enhanced CO₂ fixation in intact leaves mostlyat rate-limiting light intensities. A 60 per cent stimulationin CO₂ fixation rate was obtained by salinity under 450 µEm^–2 s^–1. At quantum flux densities of 150 µEm^–2 s^–1 (400–700 nm) this stimulation was280 per cent. Under high light intensities no stimulation bysalinity was found. In contrast, water stress achieved by directleaf desiccation or by polyethylene glycol inhibited enzymeactivity up to fourfold at –1.2 MPa. Beta vulgaris, sugar beet, ribulose-1, 5-bisphosphate carboxylase, salt stress, water stress, carbon dixoide fixation, salinity     

Geophylly: Consequences for Ledebouria ovatifolia in its Natural Habitat

Geophylly is the phenomenon, exhibited by certain plants, ofgrowing with their leaves tightly appressed to the soil surface.The plants concerned usually produce only a few broad leavesat a given time Ledebouria ovatifolia (Bak.) Jess., is sucha plant and is a bulbous member of the Liliaceae growing onopen spots in the grassveld of the summer rainfall area of SouthAfrica- The spectral optical properties of the leaves, the temperaturesof the leaves and the soil, transpiration rate, rate of CO₂-gasexchange and microclimatic conditions were measured on a plantin its natural habitat and the energy budget was calculated.The deciduous amphistomatic leaves absorb 71% of the incidentglobal radiation. As a result of the high energy input, theleaf temperature at noon is 10.1 K higher than the air temperaturebut still 7-5 K lower than the surface temperature of the baresoil. Important in the energy budget of L. ovatifolia is thehigh energy loss by transpiration (1.73 g dm^–2 h^–1)and the convective cooling by transient free-forced convection.CO₂ uptake (18.2 mg dm^–2 h^–1) occurs only at theupper leaf surface because insufficient light penetrates themesophyll to produce net photosynthesis near the lower leafsurface.     

High Net Assimilation Rates of Sunflower Plants in an Arid Climate

Net assimilation rates of sunflower plants (Heliantkus annuus),grown widely spaced with soil nutrients and water non-limiting,reached 2.0 g dm^–3 wk^–1 in clear weather at midsummerin an arid climate. These rates exceed all previously recordedand are roughly double those hitherto taken to be maximal insunflower. They suggest that maximum rates of photosysnthesisin the most active leaves were 50–65 mg CO₂ dm_–2h_–1. These high rates are a response to the high levels of radiationin the arid climate. They imply that (given non-limiting soil)plants can attain higher productivity in the arid climate thanin any other.