Light-induced Cell Division in Chlorella vulgaris, Beijerinck (Emerson Strain)

The inability of the Emerson strain of Chlorella vulgaris togrow and divide actively in a glucose medium in the dark hasbeen confirmed. It has been shown that although glucose doesnot enhance the rate of cell-division when added to culturesgrowing under saturating photosynthetic conditions, it neverthelessmarkedly increases the growth-rate when supplied to culturesin which photosynthesis is limited by an inadequate CO₂ supply. Transfer of actively growing cultures from light to darknessis followed by a limited period of active cell-division if glucoseis added to the medium; this has been interpreted as indicatingglucose utilization and the synthesis in light only, of somesubstance(s) essential for cell-division. Further evidence forthis view has been obtained from studies of the effect of alight pretreatment on subsequent growth in the dark. With cultures aerated with CO₂-free air, re-exposure to lightafter a period in the dark has been shown to bring about a resumptionof active cell-division accompanied by a decrease in the percentageof ‘giant’ cells in the population. This also suggeststhe participation of some photo-reaction, other than photosynthesis,in the control of active cell-division in this strain of C.vulgaris.     

The Accumulation of Carbohydrate in Chlorella vulgaris under Heterotrophic Conditions

The accumulation of carbohydrate in two strains of Chlorellavulgaris under autotrophic and heterotrophic conditions hasbeen examined. Cells of the Emerson strain, which cannot dividein the dark on a glucose medium, accumulate much more carbohydrateunder heterotrophic conditions than they do when growing autotrophically.Much of the extra carbohydrate is in the form of polysaccharide,particularly starch. The extent of this accumulation is notrelated to the size of the cells. In the Brannon no. 1strain,where there is no light requirement for cell division, thereis also a marked accumulation of carbohydrate, chiefly of somepolysaccharide other than starch. The relation between the carbohydrateaccumulation and the contrasting behaviour of the two strainsunder fully heterotrophic conditions is discussed.     

Physiological changes accompanying the recovery of cell division in "giant" cells of Chlorella vulgaris (EMERSON strain)

A homogeneous population of "giant" cells of the EMERSON strainof Chlorella vulgaris, produced following culture under carefullycontrolled conditions in a glucose medium in the dark, recoversits capacity to undergo cell division when returned to autotrophicconditions. A similar recovery also occurs after a prolongedperiod of culture in the dark. The division of the giant cellsis accompanied, in each case, by marked pigment synthesis anda consequent recovery of photosynthetic capacity. Under autotrophicconditions the recovery of cell division and restoration ofthe full pigment concentration are complete within a 24 hr period.The recovery which takes place in a glucose medium in the darkoccurs only after a period of 10–14 days growth. (Received May 9, 1970; )     

Accumulation of Betacyanin in Phytolacca americana Cells and of Anthocyanin in Vitis sp. Cells in Relation to Cell Division in Suspension Cultures

In suspension cultures of Vitis sp., maximal accumulation ofanthocyanin was observed during the stationary phase. Accumulationof anthocyanin occurred in parallel with the cessation of celldivision under conditions such as a reduction of the concentrationof phosphate in the medium, or the presence of aphidicolin,an inhibitor of DNA synthesis. By contrast, in suspension culturesof Phytolacca americana, aphidicolin inhibited the accumulationof betacyanin and cell division. When aphidicolin was removedfrom cells by washing, partially synchronized division of cellswas induced and the accumulation of betacyanin also occurred,in conjunction with cell division. In the absence of phosphatefrom the medium, cell division did not occur and accumulationof betacyanin also ceased. Readdition of phosphate to cellsstarved for phosphate induced both cell division and the accumulationof betacyanin. These results indicate a positive correlationbetween the accumulation of betacyanin and cell division inPhytolacca which contrasts with a negative correlation betweenthe accumulation of anthocyanin and cell division in Vitis. (Received April 17, 1989; Accepted December 23, 1989)     

THE ROLE OF RESPIRATION AND PHOTOSYNTHESIS IN THE CHLOROPLAST REGENERATION IN THE "GLUCOSE-BLEACHED" CELLS OF CHLORELLA PROTOTHECOIDES

1. As previously demonstrated, entirely chlorophyll-less cellsof Chlorella protothecoides are obtained when the alga is grownin a medium rich in glucose and poor in nitrogen source (urea).These cells, which are referred to as "glucose-bleached" cells,have neither discernible chloroplast structures nor photosyntheticactivity. When the "glucose-bleached" cells are incubated, inthe light, in a nitrogen-enriched mineral medium without addedglucose, they turn green, after an induction period, with regenerationof chloroplasts and development of the capacity for performingnormal photosynthesis. In the present study, changes in respiratoryactivity of algal cells during the process of greening (chloroplastregeneration) were followed, and the effects of various inhibitorsof respiration and photosynthesis on the greening process wereexamined. 2. The glucose-bleached cells showed a very low activity ofrespiration, and the activity increased markedly during an earlyphase of chloroplast regeneration, showing, however, a decreaseduring the subsequent phase of greening. 3. Some antimetabolites which inhibited the cell respiration,were found to suppress also the greening of cells. 2,4-Dinitrophenoland azide, potent inhibitors of oxidative phosphorylation, acceleratedconsiderably both the respiration and greening of algal cells.CMU inhibited completely photosynthesis of the greening cells,but suppressed only slightly the greening process. 4. Based on these results it was concluded that the primaryrole of respiration in the chloroplast regeneration in the glucose-bleachedcells is to produce oxidized carbon compounds (and perhaps reducedforms of NAD and NADP) for various biosynthetic reactions. Itwas further suggested that ATP may be supplied for the chloroplastregeneration by a certain means different from the oxidativephosphorylation or photophosphorylation. The activities of photosyntheticphosphorylation and CO₂-fixation developing in the greeningcells do not appear to play any essential role in the chloroplastregeneration. (Received December 27, 1965; )     

Studies in the Physiology of Lichens: With one Figure in the Text: Absorption and Utilization of Some Simple Organic Nitrogen Compounds by Peltigera polydactyla

Peltigera discs can accumulate relatively very large amountsof asparagine from solution by a process which involves theentry and accumulation of asparagine in the tissues as the completemolecule. Utilization of absorbed asparagine occurs at a relativelyslow rate and involves the preliminary deamidation of it toammonia. Asparagine absorption is completely inhibited by sodiumfluoride, and partially inhibited by glucose. Absorption isaccompanied by a release of ammonia in the medium and also byincreases in respiration rates and a change in R.Q. None ofthe absorbed asparagine can be washed out of the tissues. Discsalso show strong powers of absorption from solutions of glutamine,and glutamic and aspartic acids. There is more organic thaninorganic nitrogen in solution in the liquids available to thelichen in its habitat. The amounts of glucose and of phosphate which Peltigera andsome other lichens can accumulate from solution are also verylarge considering the slow growth-rates of these plants. Itis suggested that the possession of strong powers of absorptionof substances from solution may be a general characteristicof lichens and plants of similar habitats: it may representan adaptation to existence in barren conditions where the concentrationof nutrients in solution is very low. Utilization of absorbednutrients at a slow rate may be an adaptation to the need tosurvive long periods of starvation. The ecological implicationsof these suggestions are also discussed.     

The Effect of Glucose on the Biochemical and Ultrastructural Characteristics of Developing Euglena Chloroplasts*

SYNOPSIS. Chloroplast development is inhibited in Euglena gracilis strain Z, when greened in a medium containing glucose. This inhibition is reflected not only in the pattern of chlorophyll accumulation but also in the chloroplast ultrastructure and activities of the 2 light reactions of photosynthesis. Chloroplasts of cells greening in the presence of glucose are delayed in déveloping certain structures. Photosystem I activity develops at about the same rate as that of the controls during the first 48 h of greening, after which it develops at a slower rate. The rate of development of photosystem II activity in cells greening in a glucose medium lags considerably behind that of the controls until the later hours of greening. There are similarities between glucose inhibition and chloramphenicol inhibition of chloroplast development. Glucose may inhibit a step in chloroplast development ultimately controlled by the chloroplast genome.     

Effect of Light on Glucose Utilization by Euglena gracilis

The effect of light on glucose consumption by wild-type Euglena gracilis Z. and mutant cells has been studied. When dark- or light-grown wild-type cells are transferred from a medium containing sodium butyrate as the only carbon source to a glucose-containing medium, glucose consumption is blocked for 6 to 7 days when cultures are incubated under a light intensity of at least 600 lux. During this time cells multiply at the same rate as controls kept on media devoid of any utilizable organic carbon source. This light-induced inhibition of glucose consumption and of growth on glucose-containing medium is not related to photosynthesis since: (a) glucose consumption is inhibited by light intensities much lower than those required for high phototrophic growth; (b) the inhibition of photosynthesis by 3-(3,4-dichlorophenyl)-1, 1-dimethylurea does not overcome the inhibition of glucose consumption; and (c) nonphototrophic-growing mutants also show light-induced inhibition of glucose consumption and of growth on glucose-containing medium. This inhibition of growth by light might be explained by modification in the permeability of the cellular membrane.     

Effects of DCMU on long-day flowering of Lemna perpusilla 6746 and photosynthetic mutant strain 1073

Long-day flowering of wild-type Lemna perpusilla (strain 6746)on ammonium-free medium with sucrose occurred in continuouslight of low intensity (25 ft-c). In higher intensities of light,frond production was increased and flowering was reduced. Thephotosynthetic inhibitor DCMU inhibited frond production andpromoted flowering in the presence or absence of exogenous sucrose.In the photosynthetic mutant strain 1073, the higher intensitiesof light inhibited frond production, but did not reduce flowering.DCMU increased mutant frond production, thus leading to increasedflowering percents. The mechanism by which DCMU affects floweringand growth appears to differ from that of other flower-promotingsupplements reported by Takimoto and Tanaka. The results suggestthat inhibition of photosynthesis enhances flowering in longdays. (Received June 25, 1977; )     

Changes in the Cytochrome c Oxidase Activity in Response to Light Regime for Photosynthesis Observed with the Cyanophyte Synechocystis PCC 6714

Changes in the activity of cytochrome c oxidase (EC 1.9.3.1 [EC] ,Cyt-oxidase) in response to growth conditions were studied withthe cyanophyte Synechocystis PCC 6714 in relation to changesin PSI abundance induced by light regime for photosynthesis.The activity was determined with the V_max of mammalian cytochromec oxidation by isolated membranes. The activity of glucose-6-phosphate(G-6-P):NADP⁺ oxidoreductase (EC 1.1.1.49 [EC] ) was also determinedsupplementarily. Cyt-oxidase activity was enhanced by glucoseadded to the medium even when cell growth maintained mainlyby oxygenic photosynthesis. G-6-P:NADP⁺ oxidoreductase was alsoactivated by glucose. The enhanced level of Cyt-oxidase washigher under PSII light, which causes high PSI abundance, thanthat under PSI light, which causes low PSI abundance. The levelwas intermediate under hetetrotrophic conditions. Although theactivity level was low in cells grown under autotrophic conditions,the level was again lower in cells grown under PSI light thanunder PSII light. The change of Cyt-oxidase activity in responseto light regime occurred in the same direction as that for thevariation of PSI abundance. Results suggest that in SynechocystisPCC 6714, the capacity of electron turnover at the two terminalcomponents of thylakoid electron transport system, Cyt-oxidaseand PSI, changes in parallel with each other in response tothe state of thylakoid electron transport system. ¹Present address: Institute of Botany, Academia Sinica, Beijing100044, China ²Present address: Department of Botany, Utkal University, Bhubaneswar,India 751004     

The Effect of Sugar Supply Rate on Photosynthetic Development of Ocimum basilicum (Sweet Basil) Cells in Continuous Culture

The fructose supply rate to continuous cultures of Ocimum basilicumL. cells was changed in two ways. The concentration of fructosein the medium feed was diminished or the dilution rate was increasedin fructose-limiting conditions. When fructose in the feed wasdecreased, whilst maintaining constant dilution rate (0.87 µ_max),the specific rate of chlorophyll production increased—thebiomass became greener. Actual photosynthesis rate (dry biomass^–1)measured in the steady state conditions also increased. When fructose supply rate was increased by increasing the dilutionrate, the specific rate of chlorophyll production and actualphotosynthesis rate (dry biomass^–1) increased until acritical dilution rate (0.64 µ_max) was reached, thereafterdecreasing. The potential photosynthesis rate was measured on samples ofcells supplied with additional photons. This was inversely relatedto dilution rate. It seemed possible that the concentration of residual fructoseoutside the cells was related to specific growth rate but probablynot according to the Monod model. The specific production ofchlorophyll may be regulated by the intracellular concentrationof a catabolite of fructose, possibly glucose. Results suggestthat the specific production rate of chlorophyll was inhibitedwhen glucose concentration in the cells was above a thresholdof about 1.2% dry biomass. The degree of inhibition was a functionof glucose concentration above this threshold. Key words: Continuous culture, Photosynthesis, Greening, Ocimum basilicum     

Effect of Glucose on the Induction of the Carbonic Anhydrase and the Change in K1/2(CO2 of Photosynthesis in Chlorella vulgaris llh

Increases in carbonic anhydrase activity and decreases in K_1/2(CO)₂for photosynthesis in Chlorella vulgaris llh, which are inducedby adaptation of cells to low CO₂, were suppressed by the additionof glucose to the growth medium. The results show that phenomenainduced by decreases in CO₂ are controlled by glucose or itsmetabolites. (Received July 11, 1990; Accepted December 25, 1990)     

The Effects of Nitrogen Fertilization and the Growing Season on Photosynthesis of Field-grown Tall Fescue (Festuca arundinacea Schreb.) Canopies

Canopy gross photosynthesis of tall fescue receiving three tofour rates of N fertilization was studied under field conditionsduring three contrasting growing seasons. Under non-limitingN growing conditions, the growing seasons did not have a significanteffect on the maximum canopy gross photosynthesis (canopy grossphotosynthesis at saturating PAR) and the maximum light yield(quantum efficiency of the canopy at low PAR). In the absenceof N fertilization and for a similar LAI, the values of themaximum canopy gross photosynthesis were approximately equalto 70% of those obtained under non-limiting N conditions. Thisresponse of the tall fescue canopy to N concentration is muchsmaller than that reported at the leaf level. The reductionin canopy photosynthetic capacity with no N applied comparedto non-limiting N conditions is much less than the reductionobserved previously in above-ground dry matter accumulation.The effect of N fertilization on above-ground dry matter accumulationis due primarily to changes in C partitioning and the resultingfaster leaf area development and greater light interceptionrather than the effect of N on the canopy photosynthetic capacityper se .Copyright 1993, 1999 Academic Press Festuca arundinacea Schreb., photosynthesis, nitrogen, grass, carbon     

The Control of Branch Growth on Potato Tubers: II. THE PATTERN OF SPROUT GROWTH

Following the end of dormancy or after desprouting, many budson a potato tuber start to grow. However, if the storage temperaturefavours rapid growth, a number may remain inhibited. After atime, the smaller sprouts stop growing. This inhibition affectsonly those sprouts below a certain length, which is proportionalto the length of the longest sprout. This critical length isrelatively greater for small tubers than for large ones (i.e.longer sprouts are inhibited); it is also greater for tubersstored under dry conditions than for those under moist conditions.The results are interpreted in terms of a correlative inhibitior,continuously produced under the influence of growing buds andcontinuously destroyed as it moves up into all stems. It issuggested that in the terminal bud of the stem there is a sensitiveregion which controls the growth of the other stem tissues andon which the inhibitor acts. It stems longer than the criticallength the inhibitor is possibly inactivated before it reachesthis sensitive tissue; in shorter stems the inhibitor acts onthe tissue and hence inhibits stem elongation.     

Flower-Promoting Effects of Iron and EDDHA in Lemna paucicostata 151

Lemna paucicostata 151 cultured in 1/10 strength M medium containing50 µM FeCl₃ easily flowered in response to short days,although it scarcely flowered under any photoperiod when themedium contained the standard amount of iron (2 µM FeCl₃).The flowering response was accomparied by an increase in theiron content of the plants, which was maximal at pH 5.0. Instandard M medium containing 50 µM FeCl³, this plant didnot flower even though it had a high iron content. Ethylenediamine-di (o-hydroxyphenylacetic acid) (EDDHA) inducedflowering of this strain under continuous light even in theabsence of iron and copper, and its effect was slightly loweredby the presence of iron in the medium. Thus the flower-inducingactivity of EDDHA could not be attributed to the action of ironor copper. EDTA inhibited both the iron uptake and floweringin Fe-rich medium under short-day conditions. (Received May 16, 1986; Accepted July 25, 1986)     

Effect of Laurie Acid on Cell Division, Macromolecular Synthesis and Membrane Lipid Organization in Escherichia coli

Laurie acid (1 mg/ml) sharply suppressed the cell division ofan acrA mutant strain of Escherichia coli K12. However, thewild type acrA^$ strain was resistant to the fatty acid. Capricacid and myristic acid were not so toxic. Laurie acid inhibitedboth DNA and protein synthesis of the acrA mutant strain, withthe former being more sensitive than the latter. On the otherhand, DNA polymerase activity of toluene-treated cells was stimulatedrather than inhibited by the presence of 1 mg/ml of lauric acid.Fatty acid composition of phospholipids in the inner membranewas largely altered by the addition of lauric acid. These resultssuggest that addition of lauric acid to the medium causes adisorganization of the membrane lipids in the acrA mutant celland activities of DNA polymerase and other intramembranous enzymesare consequently inhibited. ¹Present address: Osaka City Institute of Public Health andEnvironmental Sciences. Osaka 543, Japan. (Received January 28, 1983; Accepted November 15, 1983)     

Light-induced reactions of ubiquinone in photosynthetic bacterium, Chromatium D. II. Effects of inhibitors and other experimental conditions

Light-induced reactions of ubiquinone in starved cells of ChromatiumD, were investigated under various experimental conditions. The "low amplitude" photoreduction observed on illuminationwithout addition of substrate under aerobic conditions and the"light-off spikes" observed under anaerobic conditions wereshown to be related to the cyclic flow of electrons in the photosyntheticsystem. Both of these were inhibited by o-phenanthroline, HOQNOand piericidin A. The "high amplitude" photoreduction of ubiquinoneobserved in the presence of thiosulfate under aerobic conditionswas inhibited by PCMB, PMA and KCN. The "high amplitude" photooxidationof ubiquinone in the presence of malate under anaerobic conditionswas inhibited by HOQNO, piericidin A, rotenone and PMA. In the presence of KCN and succinate, similar "high amplitude"photooxidation was obtained even under aerobic conditions. Underaerobic conditions, the addition of malate did not affect the"high amplitude" photoreduction due to thiosulfate. On the contrary,under anaerobic conditions, the "high amplitude" photooxidationwith malate was almost completely abolished by the additionof thiosulfate. This apparent counteraction of the oxidationand reduction of ubiquinone was inferred to represent an optimumstate of its efficient turn-over in the noncyclic electron transportchain of photosynthesis inChromatium. ¹This article is the second of a series of studies previouslyreported under the same title in Vol. 8 of this journal (Reference14). (Received August 23, 1968; )     

Sink-stimulated photosynthesis, increased transpiration and increased demand-dependent stimulation of nitrate uptake: nitrogen and carbon relations in the parasitic association Cuscuta reflexa-Coleus blumei

When parasitizing Coleus blumei Benth., grown in quartz sandculture and fed with 0.2, 1 or 5 mM nitrate, the biomass productionof Cuscuta reflexa Roxb. was inhibited to a similar extent asthat of the host supplied limiting concentrations of nitrate.In the presence of Cuscuta the growth and dry matter increaseof the host plant was severely inhibited. However, dry matterproduction of host plus parasite was only slightly less thanor at 0.2 mM nitrate almost the same as that of uninfected Coleusplants. Under all conditions of nitrate nutrition, parasitismby Cuscuta led to a substantial increase in photosynthesis inhost leaves under light-saturating conditions and in transpiration.Particularly with 0.2 mM and mM     

The Role of Cyclic and Pseudocyclic Photophosphorylation in Photosynthetic 14CO2 Fixation in Hydrodictyon africanum

Experiments are reported in which the effects on photosynthesisof various inhibitors of cyclic photophosphorylation were investigated.These inhibitors, generally had only a small inhibitory effecton photosynthesis, and the inhibition was not increased by conditionswhich inhibit pseudocyclic photophosphorylation. These inhibitorsdo not inhibit the Emerson enhancement effect. From these resultsit was concluded that photosynthesis does not need any ATP otherthan that produced in non-cyclic photophosphorylation. The effectsof these inhibitors on active K influx in light-anaerobic conditionsin the presence or absence of CO₂ suggest that some of the ATPproduced by non-cyclic photophosphorylation can be used to supportactive K influx. The results are discussed in relation to themechanism of the Emerson effect, the stoichiometry of non-cyclicphotophosphorylation, and the ATP requirements for autotrophicgrowth.