Photosynthesis by developing embryos of oilseed rape (Brassica napus L.)

The aim of this study was to assess the photosynthetic potentialof developing seeds of oilseed rape (Brassica napus L.) andto compare photosynthetic properties of embryo plastids withthose of leaf chloroplasts from the same species. Measurementsof CO₂-dependent O₂ evolution show that developing seeds ofB. napus are photosynthetically active in vitro. Essentially,all of the photosynthetic activity of the developing seed isaccounted for by the embryo. The rate of photosynthesis by developingembryos increased until the onset of desiccation, after whichit declined, so that by maturity embryos were no longer photosyntheticallyactive. Photosynthetic activity was positively correlated withchlorophyll content throughout development. Comparison of thephotosynthetic characteristics of leaf and embryo chloroplastsrevealed that rates of uncoupled electron transport were 2.5-foldgreater in those from the embryo. Light-saturated rates of CO₂-dependentO₂ evolution, per unit chlorophyll, and CO₂ saturation pointswere similar for chloroplasts from both tissues. However, light-saturationpoints and chlorophyll a/b ratios were lower for embryo thanfor leaf choroplasts. Embryos and embryo chloroplasts also containedconsiderably less ribulose 1,5-bisphosphate carboxylase/oxygenaseprotein per unit total protein, than leaves. Although excisedembryos were capable of high rates of CO₂-dependent O₂ evolution(90–100 mol mg^–1 chlorophyll h^–1) under asaturating photosynthetic photon flux density (PPFD), low transmittanceof light through the silique wall (30%), together with the highPPFD required to achieve light compensation points in developingseeds (500 mol m^–2 s^–1), suggests that photosynthesisin vivo is unlikely to make a net contribution to carbon economyunder normal environmental conditions. Key words: Embryo, development, photosynthesis, chloroplast, Brassica napus L.     

Glycine as a substrate for photorespiration

Substrates for photorespiration were examined by feeding ¹⁴Clabeled compounds to tobacco and corn leaf segments and by measuring¹⁴CO₂ evolution in light and darkness. CO₂ release in the darkwas rapid, but in light CO₂ release was slow due to refixationby photosynthesis. Carboxyl labeled glycine was more rapidlydecarboxylated than were glyoxylate, glycolate or serine. Hydroxypyridinemethanesulfonate, an inhibitor of glycolate oxidase, blocked CO₂ releasefrom glycolate but not from glycine. Isonicotynyl hydrazideblocked CO₂ release from both glycine and glycolate. DCMU blockedphotosynthetic refixation of the released CO₂, consequentlythe rates of CO₂ release in light and dark were about equal.It was concluded that CO₂ release during photo-respiration camefrom the conversion of 2 molecules of glycine to one serineand one CO₂. ¹⁴CO₂ release from glycine-l-¹⁴C in the dark or with DCMU inlight can be used as an assay for photorespiration ability. CO₂ release from glycine and glycolate by corn leaf segmentsin the dark proceeded at the rate of that in normal tobaccoleaf. This result, together with other work on O₂ exchange andenzymatic analysis, indicates that corn and other plants docarry on photorespiration, but it is not manifested by CO₂ releasein light. A yellow tobacco mutant, Consolation 402, had high rates ofphotorespiration by the ¹⁴CO₂ assay, nearly half (or more) asmany peroxisomes as chloroplasts, and high rates of CO₂ releasefrom glycine-l-¹⁴C or glycolate-l-¹⁴C. A common tobacco, BrightYellow, had lower rates of photorespiration, fewer visible peroxisomes,and slower decarboxylation of glycine and glycolate. The amount of ¹⁴CO₂ release from glycine-l-¹⁴C or glycolate-l-¹⁴Cincreased only slightly when the temperature was raised from25 to 35°C. ¹Parts of this work were abstracted at the Annual Meeting (April,1969) of Japanese Society of Plant Physiologists, Kanazawa ²Department of Biochemistry, Michigan State University, EastLansing, Michigan, U.S.A. (Received September 3, 1969; )     

Photosynthetic Oxygen Production Facilitates Translocation of 11C-Labelled Photoassimilates from Tendrils and Leaflets of Pisum sativum L

The translocation profiles of ¹¹C-photoassimilates from eithertendrils or leaflets of the compound leaf of Pisum sativum weresimilar in shape, speed and susceptibility to blockage by chillingand heat girdling. When the feed leaf component was exposedto an anaerobic gas stream consisting of N₂ gas supplementedwith 40 Pa CO₂, the export of previously-fixed ¹¹C-photoassimilatesfrom both leaflets and tendrils continued in the light, butstopped in the dark. However, in the light, translocation of¹¹C-assimilates from the leaflet was rapidly blocked by a flowof pure N₂ (i.e. anoxia). Movement of ¹¹C-assimilates from theleaf of another C₃ plant, sunflower, was similar to that fromthe pea leaflet. In contrast to both laminar leaf components,export from the tendrils was stopped under pure N₂ only in thedark. Taken together the data suggest that photosynthetic O₂production facilitated the movement of ¹¹C-assimilates in theabsence of exogenous O₂. The differences observed between thetendrils and the leaflets exposed to pure N₂ could be attributedto the greater capacity of tendrils to produce and recycle CO₂to support photosynthetic O₂ production in the light. Key words: Pea, ¹¹C-translocation, anoxia, tendril, leaflet     

Effects of nitrogen on Pinus palustris foliar respiratory responses to elevated atmospheric CO2 concentration

Indirect effects of atmospheric CO₂ concentration [CO₂], onlongleaf pine (Pinus palustris Mill.) foliage respiration werestudied by growing trees in a factorial arrangement of low andhigh [CO₂] (369 and 729µmol CO₂ mol^–1) and low andhigh N (40 and 400 kg ha^–1 yr^–1). Direct effectsof [CO₂] on leaf respiration were tested by measuring respirationrates of foliage from all treatments at two CO₂ levels (360and 720µmol CO₂mol^–1) at the time of measurement.Elevated CO₂ did not directly or indirectly affect leaf respirationwhen expressed on a leaf area or mass basis, but a significantincrease in respiration per unit leaf N was observed in treesgrown in elevated [CO₂] (indirect response to elevated [CO₂]).The lack of a [CO₂] effect on respiration, when analysed onan area or mass basis, may have resulted from combined effectsof [CO₂] on factors that increase respiration (e.g. greateravailability of non-structural carbohydrates stimulating growthand carbon export from leaves) and on factors that decreaserespiration (e.g. lower N concentration leading to lower constructioncosts and maintenance requirements). Thus, [CO₂] affected factorsthat influence respiration, but in opposing ways. Key words: Pinus palustris, elevated CO₂, nitrogen, foliar, respiration     

Photosynthetic Characteristics of Spinach Leaves Grown with Different Nitrogen Treatments

Spinach plants (Spinacia oleracea L.) were grown hydroponicallywith different concentrations of nitrate nitrogen, ranging from0.5 to 12 mM, in a glasshouse under full sunlight. Using anopen gas exchange system, the rate of CO₂ assimilation, A, wasdetermined as a function of intercellular partial pressure ofCO₂, P_i, with a constant amount of absorbed light per unit Chl.When expressed on a leaf area basis, A measured at high irradianceand at p_i=500 µbar, was proportional to the in vitro rateof uncoupled whole-chain electron transport as well as to Chlcontent. There was a curvilinear relationship between the mesophyllconductance (the slope of the A : P_i curve near the CO₂ compensationpoint) and the in vitro RuBP carboxylase activity. The curvaturedid not appear to be due to enzyme inactivation in vivo in leaveswith high nitrogen contents. The curvature suggested the presenceof a CO₂ transfer resistance between the intercellular spacesand the site of carboxylation of 2.2 m² s bar mol^–1 CO₂,which is similar to that previously observed in wheat. Thisimplied that, while nitrogen deficiency increased the ratioof in vitro activity of electron transport to that of RuBP carboxylase,the two activities remained balanced in vivo. Irradiance response curves were determined by both net CO₂ andO₂ exchange. The two methods gave reasonable agreement at lightsaturation. The quantum yield measured by O₂ evolution was 0.090?0.003mol O₂ mol^–1 absorbed quanta, whereas after correctingfor p_i = 500µbar, the quantum yield for CO₂ assimilationwas only 82% of that measured by oxygen evolution. ²Present address: Plant Environmental Biology Group, ResearchSchool of Biological Sciences, The Australian National University,G.P.O. Box 475, Canberra, A.C.T. 2601, Australia. (Received July 29, 1987; Accepted November 2, 1987)     

Photosynthesis in Cell Suspension Culture of a C4 Plant, Gisekia pharnaceoides L.

Photomixotrophic cell suspension culture was established fromthe leaf derived callus cells of Gisekia pharnaceoides L., aC₄ dicotyledonous weed. The late log phase cells possessed shade-typecharacters such as low chlorophyll a/b ratio, less pronouncedO₂ evolution and CO₂ fixation, saturation of photosyntheticCO₂ fixation at low intensity. The chloroplasts from these cellscontained granal stacking with high degree of a very few granawhich are characterized by their wide and high degree of stackings. The predominant labelling of 3-phosphoglyceric acid and sugarphosphates (40% of the total ¹⁴C incorporated) during 5 s exposureto ¹⁴CO₂ in light and subsequent decrease in percentage of ¹⁴Cin these compounds with increase in exposure time indicatedthe operation of the C₃ pathway in these cells. The simultaneoussynthesis of malate (23% of the total ¹⁴C incorporated) is relatedto the much pronounced glycolytic and tricarboxylic acid cycleactivities in these cells. The initial proliferation of callimainly from the zones of vascular supplies in the leaf, highstarch content of the cells, presence of large starch grainsin all the chloroplasts, activities of Calvin cycle enzymes,heavy labelling of C₃ type intermediates and less labellingof aspartate as early photosynthates and rapid accumulationof radioactivity into starch during ¹⁴CO₂ assimilation indicatedthat most of the cells in photomixotrophic culture were derivedfrom bundle sheath cells or the leaf cells of Gisekia changetheir function under culture conditions. ¹Present address: Tropical Botanic Garden and Research Institute,Navaranga Road, Trivandrum 695 011, India. (Received January 29, 1982; Accepted June 4, 1983)     

Photoreduction of 18O2 and H218O2 with Concomitant Evolution of 16O2 in Intact Spinach Chloroplasts: Evidence for Scavenging of Hydrogen Peroxide by Peroxidase

Illuminated intact spinach chloroplasts decomposed one moleculeof H₂¹⁸O₂ which resulted in the evolution of a half moleculeof ¹⁶O₂, but little ¹⁸O₂. The chloroplasts showed the same rateof photoreduction of ¹⁸C₂ as that of the evolution of ¹⁶O₂ withoutaccumulation of H₂¹⁸O₂. These reactions were suppressed by DCMU,and also by several inhibitors of ascorbate peroxidase and dehydroascorbateand monodehydroascorbate reductases in chloroplasts. These observationsindicate that the hydrogen peroxide produced in chloroplastsis reduced to water by a peroxidase using a photoreductant asthe electron donor. The hydrogen peroxide scavenging systemof chloroplasts was inactivated if hydrogen peroxide was addedin the dark, but not if added during the light. (Received May 4, 1984; Accepted July 10, 1984)     

Photosynthetic Characteristics of Chloroplasts Isolated from Euglena gracilis Z Grown Photoautotrophically

Photosynthetically competent chloroplasts were isolated fromcells of Euglena gracilis Z grown photoautotrophically in 1.5%CO₂. The isolated chloroplasts were intact and substantiallyfree from cytosolic, mitochondrial and microbody materials.The effects of some compounds on the activity of photosynthetic¹⁴CO₂ fixation were examined. The optimal pH and sorbitol concentrationwere 8.0 and 0.33 M, respectively. The chloroplasts requireda high level of P, (5 to 20 mM) for the maximal rate of photosynthesis.They were insusceptible to 10 mM of free Mg²⁺. ATP, ADP andAMP at 1 to 5 mM notably stimulated photosynthesis, althoughhigh concentrations of AMP were unfavorable. In the assay mediumdeveloped for this study, the chloroplasts exhibited photosyntheticactivity of 120µmoles-mg^–1 Chl-h^–1 at 30?C. Chloroplasts could also be isolated from cells grown under ordinaryair. The rate of photosynthetic ¹⁴CO₂ fixation at 1 mM NaH^l4CO₃was higher in these chloroplasts than in those isolated fromcells grown in 1.5% CO₂, whereas at 10 mM NaH^l4CO₃, the ratesof the two types of chloroplasts were nearly the same. Theseresults suggest that the CO₂ concentration given during growthof the algal cells affects the affinity for dissolved inorganiccarbon at the chloroplast level. (Received March 30, 1987; Accepted August 17, 1987)     

Elevated CO2 reduces O3 flux and O3-induced yield losses in soybeans: possible implications for elevated CO2 studies

Soybeans were grown for three seasons in open-top field chambersto determine (1) whether elevated CO₂ (360 versus 700 µmolmol^–1) alleviates some of the yield loss due to pollutantO₃, (2) whether the partial stomatal closure resulting fromchronic O₃ exposure (charcoal-filtered air versus 1.5 ambientconcentrations) is a cause or result of decreased photosynthesis,and (3) possible implications of CO₂/O₃ interactions to climatechange studies using elevated CO₂. Leaf conductance was reducedby elevated CO₂, regardless of O₃ level, or by exposure to O₃alone. As.a result of these effects on conductance, high CO₂reduced estimated midday O₃ flux into the leaf by an averageof 50% in charcoal-filtered air and 35% in the high O₃ treatment.However, while exposure to O₃ reduced seed yields by 41% atambient CO₂ levels, the yield reduction was completely amelioratedby elevated CO₂. The threshold midday O₃ flux for yield lossappears to be 20–30 nmol m^–2 s^–1 in this study.Although elevated CO₂ increased total biomass production, itdid not increase seed yields. A/C_i curves show a large reductionin the stomatal limitation to photosynthesis due to elevatedCO₂ but no effect of O₃. These data demonstrate that (1) reducedconductance due to O₃ is the result, and not the cause, of reducedphotosynthesis, (2) 700 µmol mol^–1 CO₂ can completelyameliorate yield losses due to O₃ within the limits of theseexperiments, and (3) some reports of increased yields underelevated CO₂ treatments may, at least in part, reflect the ameliorationof unrecognized suppression of yield by O₃ or other stresses. Key words: Stomatal limitation, elevated CO₂, O₃ flux, Glycine max, yield suppression     

Appearance of Photochemical Activity in Isolated Chloroplasts from Far-red-illuminated Leaves of Phaseolus vulgaris

Chloroplast development was followed in intact bean leaves illuminatedwith far-red light by extracting chloroplasts at various timesto assay photosynthetic activities. Photochemical activity wasdetected in isolated chloroplasts prior to the times which werepreviously reported for intact leaf discs. Cyclic phosphorylationwas observed in isolated chloroplasts after 8 h of far-red illuminationwhile non-cyclic electron transport and phosphorylation weremeasurable after 12 and 16 h of illumination respectively. TheP/2e ratios were less than 0.5 after 24 h of far-red exposurebut approached a value of 1.0 by 60 h of illumination. Ammoniumchloride (10^–3 M) had little effect on electron transportin isolated chloroplasts until after 24 h of far-red illumination.Chlorophyll a accumulated slowly from the onset of far-red illuminationwhile chlorophyll b was not detected until after 48 h of far-redexposure. Leaf fresh weight increased four-fold over the 60h illumination period. Electron microscopy of isolated chloroplasts from far-red-illuminatedleaves indicated the presence of unfused primary thylakoidsby 12 h of exposure and prolamellar bodies throughout the entire60 h illumination period. Grana were not observed in isolatedchloroplasts nor were they induced by a 2 min exposure of thechloroplasts to 172 000 lx of white light. O₂ evolution in leaf discs of far-red-illuminated plants wasmeasurable after 16 h of illumination, attained a maximum valueby 36 h of far-red exposure, and then declined. Net CO₂ fixationwas observed in leaf discs after 8 h of far-red illuminationand the rates remained constant for an additional 16 h, beforeincreasing at least two-fold.     

Effect of Tribenzylphosphate on the Phosphate Translocator of Isolated Pea Chloroplasts

The effect of tribenzylphosphate on the activity of the phosphatetranslocator of intact pea chloroplasts was tested. The translocatoractivity was followed by O₂ evolution, ¹⁴CO₂ fixation and ³²Pback-exchange. The reagent inhibited 3-phosphoglycerate dependent-photosyntheticactivities probably through an interaction with the PGA translocator. (Received September 11, 1985; Accepted November 21, 1985)     

Photosynthetic efficiency of Panicum hians and Panicum milioides in relation to C3 and C4 plants

Panicum hians and Panicum milioides were found to have characteristicsintermediate to those of C₃ and C₄ species with respect to CO₂compensation point, percentage inhibition of photosynthesisby O₂ at various O₂/CO₂ solubility ratios, and water use efficiency.C₄ species have a higher carboxylation efficiency than eitherthe intermediate or C₃ species. During photosynthesis, evenunder 2.5% O₂, C₄ species have a higher affinity for intercellularCO₂ (Km 1.6 µM) apparently due to the initial carboxylationthrough PEP carboxylase. Under low O₂ the intermediate and C₃species had a similar affinity for intercellular CO₂ duringphotosynthesis (Km 5–7 µM) consistent with carboxylationof atmospheric CO₂ through RuDP carboxylase. There were considerablevariation in photosynthesis/unit leaf area at saturating CO₂levels in the species examined which in part is due to differencesin RuDP carboxylase /unit leaf area. The highest rates of photosynthesis/unitleaf area under CO₂-saturating conditions were with the C₃ specieswhich had a correspondingly high level of RuDP carboxylase/unitleaf area. Possibilities for the greater efficiency of P. hiansand P. milioides in comparison to C₃ species in utilizing lowlevels of CO₂ in the presence of atmospheric O₂ are discussed. ¹ This research was supported by the College of Agriculturaland Life Sciences, University of Wisconsin, Madison; and theUniversity of Wisconsin Research Committee with funds from theWisconsin Alumni Research Foundation. (Received June 25, 1977; )     

Evidence for the Occurrence of Feedback Inhibition of Photosynthesis in Rice

The response of photosynthesis in the flag leaf of rice (Oryzasativa) to elevated CO₂ or reduced O₂ was investigated relativeto other environmental factors using steady-state gas exchangetechniques. We found under moderate conditions of temperatureand photosynthetic flux density (PFD) (26°C and 700µmolquanta m^–2s^–1 similar to growth conditions) photosynthesisin the flag leaf of rice during heading and grain filling saturatedat near ambient levels of CO₂, with a concomitant loss of O₂sensitivity, when a high stomatal conductance was maintainedby high humidity (low vapor pressure deficit). Under 18°Cthere was near complete loss of O₂ sensitivity of photosynthesisat normal ambient levels of CO₂. This is in contrast to thelarge enhancement of photosynthesis by supra-atmospheric levelsof CO₂ and sub-atmospheric levels of O₂ by suppression of photorespirationwhen there is no limitation on utilizing the initial productof CO₂ assimilation (triose-P) as predicted from Ribulose-l,5-bisphosphatecarboxylase/oxygenase (Rubisco) kinetic properties. Thus, lossof sensitivity to CO₂ and O₂ has been previously explained asa limitation on utilization of triose-P to synthesize carbohydrates.Under high PFD at 25°C, the rate of photosynthesis in ricedeclined over a period of hours around midday, while the intercellularlevels of CO₂ remained constant suggesting a limitation on utilizationof photosynthate. Short-term fluctuations in climatic factorsincluding temperature, light and humidity could result in afeedback limitation on photosynthesis in rice which may be exacerbatedby rising CO₂. (Received March 12, 1998; Accepted May 14, 1998)     

Effects of Oxygen on Metabolism by the Glycollate Pathway in Leaves

Segments of wheat leaves were supplied in the light with ¹⁴C-labelledserine or glucose in atmospheres containing different concentrationsof O₂ and zero or 350 parts/10⁶ CO₂. Some O₂ was necessary forsucrose synthesis from either serine or glucose but sucrosesynthesis from glucose depended on reactions with a high affinityfor O₂ whereas sucrose synthesis from serine depended both onreactions with high and low affinities for O₂. In the presenceof CO₂ sucrose synthesis from serine was decreased when theO₂ concentration was increased from 20 to 80% by volume andCO₂ was liberated; sucrose synthesis from glucose was almostunaffected by the same change in conditions. Also, in an atmospherecontaining 80% O₂ and 350 parts/10⁶ CO₂, radioactivity from[¹⁴C]serine, was incorporated into glycine. This was not truefor glucose feeding. Hence glucose provides a substrate forsucrose synthesis but not for photorespiration whereas serineis used for both processes in the presence of CO₂; in the absenceof CO₂ glucose provides substrate for both sucrose synthesisand photorespiration and serine metabolism to sucrose is restricted.     

Translocation Profiles of [11C] and [13N]-Labelled Metabolites after Assimilation of 11CO2 and [13N]-Labelled Ammonia Gas by Leaves of Helianthus annuus L. and Lupinus albus L.

Tracer amounts of atmospheric [¹³N]-Iabelled ammonia gas, wereabsorbed by leaves of Lupinus albus and Helianthus annuus inboth the light and the dark. Exogenous [¹³N]-ammonia was onlyabsorbed in the dark when the feeding occurred shortly aftera period of illumination and the tissue was not depleted ofits carbohydrate reserves (e.g. starch). Incorporation of the[¹³N]-ammonia appeared to occur via the leaf glutamine synthetase/glutamatesynthase (GS/GOGAT) cycle since 2.0 mol m^–3 MSX, an inhibitorof the GS reduced uptake in both the light and dark. Photosyntheticincorporation of ¹¹CO₂ was not affected by this treatment Therate of movement of [¹³N]-assimilates in the petiole of attachedleaves of Helianthus and Lupinus was similar to that of the¹¹Cl-photo assimilates. Export of both [¹³N] and [¹¹C]-Iabelledassimilates from the leaf and movement in the petiole in boththe light and the dark was inhibited by source leaf anoxia (i.e.nitrogen gas). Translocation was re-established at the samerate when the feed leaf was exposed to gas containing more than2% O₂ which permitted dark respiration to proceed. After aninitial feeding of either ¹¹CO₂ or [¹³N]-ammonia at ambient(21%) O₂ exposure of the source leaf to 2% O2, or 50% O² didnot alter the rates of translocation, indicating that changesin photosynthetic activity in the source leaf due to photorespiratoryactivity need not markedly alter, at least during the shortperiod, the loading and translocation of either [¹¹C ] or [¹³N]-labelledleaf products. Key words: Translocation, CO₂, NH₃, Leaves, Helianthus annuus, Lupinus albus     

Effect of linolenate on photosynthesis by intact spinach chloroplasts II. Influence of preillumination of leaves on the inhibition of photosynthesis by linolenate

The inhibitory effect of linolenate on intact spinach chloroplastsdepends on the level of the internal pool of metabolites. Chloroplastsfrom preilluminated leaves or chloroplasts artificially loadedwith 3-phosphoglyceric acid required higher concentrations oforthophosphate for maximal rates of CO₂ dependent O₂ evolutionthan untreated chloroplasts. The loaded chloroplasts were moresensitive to linolenate, and in the presence of linolenate theoptimal phosphate concentration was shifted toward lower values.We propose that the inhibition of photosynthesis by linolenateis due to inhibition of the "phosphate translocator". ¹ Part of this work has been published in the Book of Abstracts,4th International Congress on Photosynthesis, Reading, U.K.,1977, p. 265–266. ² This work is part of a doctoral programme carried out by L.Mv6 Akamba in this laboratory. ³ To whom reprint requests should be adressed. (Received October 14, 1978; )     

Photosynthesis by Flag Leaves of Wheat in Relation to Protein, Ribulose Bisphosphate Carboxylase Activity and Nitrogen Supply

The effects of nitrate supply on the composition (cell numbers,protein and chlorophyll contents) of flag leaves of winter wheatgrown with two amounts of N fertilizer and of spring wheat grownin the glasshouse under controlled nitrate supply are describedand related to photosynthesis. Nitrogen deficiency decreasedthe size of leaves, mainly by reducing cell number and, to asmaller extent, by decreasing cell volume. Protein content perunit leaf area, per cell and per unit cell volume was largerwith abundant N. Total soluble protein, ribulose bisphosphatecarboxylase-oxygenase (RuBPc-o) protein and chlorophyll changedin proportion irrespective of nitrogen supply and leaf age.Photosynthesis per unit area of flag leaf and carboxylationefficiency in both winter and spring wheat were proportionalto the amount of total soluble protein up to 7.0 g m^–2and to the amount of RuBPc-o protein up to 4.0 g m^–2.However, photosynthesis did not increase in proportion to theamount of total soluble or RuBPc-o protein above these amounts.In young leaves with a high protein content the measured ratesof photosynthesis were lower than expected from the amount andactivity of RuBPc-o. Carboxylation per unit of RuBPc-o protein,measured in vitro, was slightly greater in N-deficient leavesof winter wheat but not of spring wheat. RuBPc-o activity perunit of RuBPc-o protein was similar in winter and spring wheatleaves and remained approximately constant with age, but increasedin leaves showing advanced senescence. RuBPc-o protein fromN-deficient leaves migrated faster on polyacrylamide gels thanprotein from leaves with high N content. Regulation of the rateof photosynthesis in leaves and chloroplasts with a high proteincontent is discussed. The conductance of the cell to the fluxof CO₂ from intercellular spaces to RuBPc-o active sites iscalculated, from cell surface areas and CO₂ fluxes, to decreasethe CO₂ partial pressure at the active site by less than 0.8Pa at an internal CO₂ partial pressure of 34 Pa. Thus the decreasein partial pressure of CO₂ is insufficient to account for theinefficiency of RuBPc-o in vivo at high protein contents. Otherlimitations to the rate of photosynthesis are considered. Key words: Wheat, photosynthesis, nitrogen, ribulose, bisphosphate carboxylase     

The Transport of Photosynthetic Products from the Chloroplasts of Tobacco Leaves

Tobacco leaves were fractionated by the non-aqueous method afterphotesynthesis for short periods in ¹⁴CO₂ and with or withoutsubsequent photosynthesis in ¹²CO₂ or respiration in the dark.Phosphate esters became labelled only slowly in the non-chloroplastparts of the leaf; glycine and serine which became rapidly labelledin the non-chloroplast leaf fraction appear to be concernedin the transport of newly assimilated carbon from the chloroplast.     

DNA Synthesis in Chloroplasts: III. THE DNA GYRASE INHIBITORS NALIDIXIC ACID AND NOVOBIOCIN INHIBIT BOTH THYMIDINE INCORPORATION INTO DNA AND PHOTOSYNTHETIC OXYGEN EVOLUTION BY ISOLATED CHLOROPLASTS

The influence of two DNA gyrase inhibitors, nalidixic acid andnovobiocin, on DNA synthesis in isolated pea chloroplasts wasexamined. Novobiocin at 1–5 mol m^–3 markedly lowered[³H]thymidine incorporation into DNA (30–95% inhibition);while less effective, nalidixic acid at similar concentrationsalso diminished incorporation (25–35% inhibition). Theinhibition of chloroplast DNA (ctDNA) biosynthesis by nalidixicacid and novobiocin was confirmed by autoradiography and densitometry.These data are consistent with the view that chloroplasts containa DNA gyrase-like enzyme which is necessary for DNA replication.Despite this, interpretation of the results is not straightforward,as both nalidixic acid and novobiocin also inhibited photosyntheticactivity. Each substance (at millimolar levels) reduced ferricyanide-dependentO₂ evolution in isolated chloroplasts. However, at lower concentrations(0.05–0.3 mol m^–3) they slightly enhanced photosyntheticelectron flow; thus, these compounds may act as uncouplers ofphotophosphorylation as well as inhibitors of electron transport.Nalidixic acid and novobiocin at relatively low (0.1 mol m^–3)concentrations also strongly reduced CO₂-dependent O₂ evolution(an index of CO₂ photo-assimilation) in isolated plastids. Thus,caution must be exercised in assessing results from studiesin which nalidixic acid and novobiocin are used with whole plants,cells, protoplasts or isolated chloroplasts. Key words: Chloroplast, DNA replication, novobiocin, nalidixic acid, DNA gyrase     

Oxygen Exchange in Relation to Carbon Assimilation in Water-stressed Leaves During Photosynthesis

In a study on metabolic consumption of photosynthetic electronsand dissipation of excess light energy under water stress, O₂and CO₂ gas exchange was measured by mass spectrometry in tomatoplants using ¹⁸O₂ and ¹³CO₂. Under water stress, gross O₂ evolution(E_O), gross O₂ uptake (U_O), net CO₂ uptake (P_N), gross CO₂ uptake(TPS), and gross CO₂ evolution (E_C) declined. The ratio P_N/E_Ofell during stress, while the ratios U_O/E_O and E_C/TPS rose.Mitochondrial respiration in the light, which can be measureddirectly by ¹²CO₂ evolution during ¹³CO₂ uptake at 3000 µll^{–1 13}CO₂, is small in relation to gross CO₂ evolutionand CO₂ release from the glycolate pathway. It is concludedthat PSII, the Calvin cycle and mitochondrial respiration aredown-regulated under water stress. The percentages of photosyntheticelectrons dissipated by CO₂ assimilation, photorespiration andthe Mehler reaction were calculated: in control leaves morethan 50 % of the electrons were consumed in CO₂ assimilation,23 % in photorespiration and 13 % in the Mehler reaction. Undersevere stress the percentages of electrons dissipated by CO₂assimilation and the Mehler reaction declined while the percentageof electrons used in photorespiration doubled. The consumptionof electrons in photorespiration may reduce the likelihood ofdamage during water deficit.