Short-term Products of 14C-acetate Assimilation by Chlorella pyrenoidosa in the Light

The kinetics of ¹⁴C-2-acetate assimilation by Chlorella pyrenoidosain the light were examined. Under aerobic conditions the primaryproduct of acetate assimilation was succinic acid which, afterten seconds, contained over 60 per cent of the ¹⁴C incorporatedby the cells. The percentage of the total ¹⁴C in succinate fellwith time, while that in citrate and glutamate increased. After1800 sec over 60 per cent of ¹⁴C was present in two compounds,glutamic acid and an unknown compound (X). Glucose-6-phosphate,fructose-6-phosphate, phosphoglyceric acid and phosphoenolpyruvicacid became labelled after 60 sec but together never containedmore than one per cent of the total ¹⁴C incorporated. Underanaerobic conditions succinate was still the primary productof acetate assimilation, and the absence of carbon dioxide resultedin a decrease in ¹⁴C incorporation into compound X. The patternof acetate assimilation in acetate grown and acetate adaptedChlorella was very similar to that in photo-autotrophicallygrown Chlorella. In the presence of 10^–6M DCMU, succinicacid was the primary product of acetate assimilation, but therewas an early Incorporation of ¹⁴C into glutamate, aspartate,and malate. 4 x10^–3M MFA did not effect the early incorporationof ¹⁴C into succinic acid, but resulted in accumulation of ¹⁴Cin citrate and a decreased amount in glutamate and in compound X.     

The Kinetics of Isocitrate Lyase Formation in Chlorella: Evidence for the Promotion of Enzyme Synthesis by Photophosphorylation

The addition of acetate to aerobic Chlorella pyrenoidosa indarkness was followed by the formations of isocitrate lyaseactiity. After a lag period of 40 minutes the formation proceededat a constant rate. By use of actylamide gel electrophoresisit was shown that the increase in enzyme activity was accompaniedby the formation of a new protein which, after separation byelectrophoresis, contained isocitrate lyase activity. The formationof isocitrate lyase was repressed by glucose; it was repressedby light in the presence of carbon dioxide, but not when DCMUwas added. In light, plus DCMU, isocitrate lyase was formedanaerobically and the capacity for photo-formation of isocitratelyase was saturated at 500 ergs/cm²/sec. In this respect theprocess resembled the photo-conversion of glucose to polysaccharidebut differed from the photo-assimilation of carbon dioxide whichbecame saturated at a heigher light intensity. Monochromaticlight of 706 mµ wavelength supported both isocitrate layseformation and the conversion of glucose to polysaccharide butnot carbon dioxide fixation. It is concluded that ATP generatedby cyclic photophosphorylatin can provide the energy for isocitratelyase synthesis in Chlorella.     

Light-induced changes in membrane potential in Spirogyra

Spirogyra cells exhibited changes in membrane potential whenthey were exposed to light. Cells made chloroplast-free didnot show any light-induced potential change (LPC) upon illuminationwith white light and also monochromatic red (680 nm) and farred (720 nm) light. LPC was observed when the cell containedonly a small fragment of chloroplast, whether the cell had anucleus or not. The magnitude of LPC depended on the amountof chloroplast in the cell. DCMU at 10^–5 M, CCCP at 10^–5 M and DNP at 10^–4M at pH 5.5 suppressed LPC, while CCCP at 1–5 ? 10^–6M, NH₄Cl at 5 ? 10^–2 M and DNP at 10^–4 M at pH 7.0stimulated LPC. PMS at 10^–4 M stimulated LPC and couldinduce LPC which was completely inhibited by DCMU. These factssuggest that LPC is related to noncyclic and cyclic electronflows. The influences of light and dark conditions and various metabolicinhibitors (DCMU, DNP, CCCP, NH₄Cl) on ATP level have been investigated.No significant difference in the ATP level was observed betweencells in the light and dark. DNP at 10^–4 M (pH 5.5) andCCCP at 5 ? 10^–6 M decreased the ATP level significantly,while DCMU and NH₄Cl only slightly. Good correlation was notfound between the total ATP level and LPC in Spirogyra. LPC occurred even when the external medium contained only asingle salt such as KCl, NaCl or CaSO₄. LPC was also recorded in chloroplasts in situ and in vitro.The mode of LPC of chloroplasts was quite different from thatof the cell. On illumination, the chloroplast potential changedvery rapidly and transiently in the positive direction thenrecovered spontaneously to almost the original potential level. Possible causes of LPC are discussed in relation to the electrogenicion pump. ¹ Present address: Department of Botany, Faculty of Science,University of Tokyo, Hongo, Bunkyo, Tokyo 113, Japan. (Received November 9, 1977; )     

Ammonia Induces Starch Degradation in Chlorella Cells

When ammonia was added to cells of Chlorella which had fixed¹⁴CO₂ photo synthetically, ¹⁴C which had been incorporated intostarch was greatly decreased. A similar effect was observedwhen potassium nitrate and sodium nitrite were added. The ammonia-induceddecrease in ¹⁴C-starch was observed in all species of Chlorellatested. With cells of C. vulgaris 11h, most of the radioactivityin starch was recovered in sucrose, indicating that ammoniainduces the conversion of starch into sucrose. The percent of¹⁴C recovered in sucrose differed from species to species andpractically no recovery in sucrose was observed in C. pyrenoidosa.In most species tested, the enhancing effects of blue lightand ammonia on O₂ uptake as well as the ammonia effect on starchdegradation were greater in cells which had been starved inphosphate medium in the dark than in non-starved cells. In contrast,the enhancing effect of ammonia on dark CO₂ fixation was muchgreater in non-starved cells. C. pyrenoidosa was unique in thatblue light did not show any effect on its O₂ uptake. (Received August 15, 1984; Accepted November 16, 1984)     

Photophosphorylation in intact algae: Effects of inhibitors, intensity of light, electron acceptor and donors

The luciferin-luciferase method was used to determine ATP extractedfrom darkmaintained and light-exposed samples of the green algaChlorella pyrenoidosa and of the blue-green alga Anacystis nidulans.A few measurements on Synechococcus lividus (a bluegreen thermophile,clone 65?C) are also reported.

1. The light-minus-dark ATP levels (ATP) from aerobic cells ofChlorella and Anacystis were negative; however, ATP from Synechococcuswas positive. Large positive ATP was obtained in regularly grown(RG: moderate light) Chlorella treated with oligomycin; darklevels were reduced, light levels remained essentially unaffected.In high-light exposed (HLE) Chlorella, oligomycin reduced bothlight and dark ATP levels, but positive ATP was still obtained.However, in Anacystis, which has a different organization ofthylakoid membrane, oligomycin severely reduced both the lightand the dark ATP levels and the ATP remained negative.
2. Theoligomycin (12 µM) treated Chlorella and the untreatedAnacystis and Synechococcus show the presence of cyclic photophosphorylationunder conditions in which the non-cyclic electron flow fromphotosystem II to photosystem I is blocked by 10 µM 3-(3,4-dichlorophenyl)-l,l-dimethylurea(DCMU), or not allowed to operate by the absence of CO₂. Cyclicphotophosphorylation ranged from 10–30% of the maximumATP in RG, to 40–50% in HLE Chlorella. In RG Chlorella,cyclic and non-cyclic (in the absence of DCMU) photophosphorylation(ATP) saturate at about 10³ ergs cm^–2 sec^–1 and10⁴ ergs cm^–2 sec^–1 and 10⁴ ergs cm^–2 sec^–1red (>640 nm) light, respectively; a lag was observed inthe light curve.
3. In Chlorella, the addition of the photosystemI electron acceptormethyl viologen (MV; 1 mM) increased ATPby twofold. Furtheraddition of DCMU (25 µm) reduced thisto the level observedwith DCMU alone. If 1 mM reduced dichlorophenolindophenol orphenazine methosulphate (DCPIPH₂ or PMSH₂, respectively)wasadded along with DCMU, the ATP level was 30–40% ofthecontrol. Further addition of MV increased the JATP to be70–80%of that of the control. These and other resultsconfirm thepresence of both non-cyclic and cyclic photophosphorylationin vivo, the former predominating in Chlorella, and the latterin Anacystis and Synechococcus.

(Received May 1, 1973; )     

Uptake and Utilization of Fructose by Anabaena variabilis ATCC 29413. Effect on Respiration and Photosynthesis

Anabaena variabilis ATCC 29413 showed a constitutive mechanismfor fructose uptake which was further enhanced by growing thecells with fructose. The uptake process was energydependentas indicated the inhibitory effect of the uncoupler carbonylcyanidem-chlorophenylhydrazone (CCCP) and the reduction induced byincubating the cells in the dark or in the light with DCMU.Cells adapted to growth on fructose showed increased rates ofrespiration both in the dark and in the light. The rate of ¹⁴CO₂evolved from radiolabelled fructose was lower in the light thanin the dark or in the presence of DCMU. This fact can be partiallyexplained by the photosynthetic reutilization of respiratory¹⁴CO₂. Modifications in photosynthesis were observed in fructose-growncells. PS I and PS II activity measured in spheroplasts obtainedby lysozyme treatment were enhanced by fructose probably asa way to compensate the lower concentration of chorophyll showedby fructose-grown cells. The photosynthetic affinity for externalCO₂ and the rate of photosynthesis dependent on external inorganiccarbon were reduced by fructose. (Received September 24, 1991; Accepted February 14, 1992)     

Effect of Oxygen on Photosynthetic 14CO2 Fixation in Chroomonas sp. (Cryptophyta) II. Effects of Inhibitors, Uncouplers and an Artificial Electron Mediator on the Inhibition of 14CO2 Fixation by Anaerobiosis

In "air-grown" Chroomonas sp. cells, low concentrations of DCMU(less than 0.1 µM) could prevent the inhibition of ¹⁴CO₂fixation by anaerobiosis under light-saturating conditions (morethan 40 W.m^–2), with phenazine methosulfate showing asimilar effect. Antimycin A, carbonyl cyanide m-chlorophenylhydrazone(CCCP), and N,N'-dicyclohexylcarbodiimide strongly inhibitedanaerobic photosynthesis at concentrations which did not significantlyinhibit the rate under 2% O₂ at high light intensity (200 W.m^–2),although 0.2 µM CCCP stimulated the rate under 2% O₂ tosome extent. On the other hand, KCN inhibited the rate muchmore strongly under 2% O₂ than N₂, although it inhibited therate very strongly at concentrations above 5 µM both underN₂ and 2% O₂. These results suggest that the inhibition of photosynthetic¹⁴CO₂ fixation by anaerobiosis in this alga result from ATPdeficiency caused by over-reduction of electron carriers ofthe cyclic electron flow and that oxygen can prevent the over-reduction.Cyclic electron flow seems to be necessary to provide additionalATP for CO₂ reduction under anaerobic conditions, although itseems to be less necessary under aerobic conditions. (Received July 21, 1983; Accepted January 23, 1984)     

Glycollate Formation during the Photorespiration of Acetate by Chlorella

WhenChlorella pyrenoidosa photoassimilates ³H-¹⁴C-acetate theglycollic acid formed shows a high ³H/¹⁴C ratio, the only othercompounds showing similar ratios being glycerate and serine.The ³H/¹⁴C ratio of glycollate was unaffected by the TCA cycleinhibitors MFA, diethylmalonate and arsenite showing that ³Hin glycollate does not result from the oxidation of acetatevia the TCA cycle, the resulting NADP³H₂ or NAD³H₂ being usedfor the reduction of the glycollate precursor. Although DCMUdecreased the ³H/¹⁴C ratio, complete inhibition of glycollatelabelling was not observed with 10^–6 M DCMU, at whichconcentration complete inhibition of the Hill reaction is achieved.Although the ³H/¹⁴C ratio was unaltered, total dpm of both ¹⁴Cand ³H in glycollate were increased by INH. The ³H/¹⁴C ratiosof glycerate and serine were decreased by INH, as were the totaldpm of ³H and ¹⁴C incorporated into these compounds. Thus, INHinhibits the further metabolism of glycollate to glycerate andserine. The effect of INH on incorporation of ¹⁴C-I-acetateinto various cell fractions was investigated. The incorporationof ¹⁴C into polysaccharide and lipid was decreased, while theincorporation of ¹⁴C into the water-soluble fraction of cellsand therelease of ¹⁴CO₂ were little affected. Although glycollicacid was an early product of acetate photoassimilation in Chlorellapyrenoidosa, glycollate excretion does not take place undera wide range of environmental conditions shown to favour glycollateexcretion by other algae. However, small amounts of labelledglycollate were detected in the supernatant from the cells duringthe photoassimilation of ³H-¹⁴C-acetate, but this glycollatedid not show the high ³H/¹⁴C ratio of glycollate present withinthe cell. The failure of Chlorella pyrenoidosa to excrete appreciableamounts of glycollate when photoassimilating acetate or carbondioxide was considered to result from the presence of glycollateoxidase (EC 1.1.3.1 [EC] ) which allowed the further metabolism ofglycollate. Besides glycollate oxidase, glyoxylate reductasewas also demonstrated in Chlorella pyrenoidosa so that glycollatecould function in hydrogen transfer during the photoassimilationof acetate.     

Photosynthesis-Dependent Volume Regulation in Guard Cell Protoplasts from Vicia faba L.

A rapid and convenient procedure was developed for isolatingguard cell protoplasts (GCPs) from epidermal strips of Viciafaba L. The mean rates of O₂ uptake in the dark and evolutionin light of the isolated GCPs were 200 and 290 µmol O₂mg^–1 Chl h^–1, respectively, showing net O₂ evolutionin light. Photosynthetic O₂ evolution was suppressed completelyby 5 µM DCMU. Addition of 5 µM DCMU to the incubationmedium after 30 min of light exposure also suppressed the light-inducedswelling of GCP, indicating possible participation of PS IIin volume regulation in GCP. ⁴Present address: Division of Environmental Biology, The NationalInstitute for Environmental Studies, Yatabe machi, Tsukuba,Ibaraki 305, Japan. (Received December 17, 1983; Accepted March 21, 1984)     

Studies on cytochromes in photosynthetic electron transport system I. photoreduction and photo-oxidation of cytochrome b559 by photosystem II in spinach chloroplasts

Light-induced redox-reactions of cytochrome b₅₅₉ in spinachchloroplasts were investigated. Illumination of chloroplastsinduced photoreduction of cytochrorne b₅₅₉ Red light (650 nm)was more effective than far-red light (725 nm), indicating thatthe photoreduction is a photosystem II-mediated reaction. Onaddition of DCMU, the photoreduction was eliminated and a photooxidationof cytochrome b₅₅₉ was observed. The rate of this photooxidationwas faster with photosystem II light than with photo-systemI light. On addition of Mn⁺⁺ the photooxidation was partly suppressed;far-red light became as effective as red light in inducing photooxidationof cytochrome b₅₉₉, in the presence of DCMU and Mn⁺⁺. Ascorbate completely suppressed photooxidation of cytochromeb⁵⁵⁹ In the presence of ascorbate, however, photooxidation wasobserved in the presence of inhibitors or after inhibitory treatmentsof chloroplasts which affected the oxidizing side of systemII. These inhibitors and inhibitory treatments, but not DCMU,decreased the redoxpotential of cytochrome b₅₅₉. Reactivationof Hill reaction in Tris-washed chloroplasts by indophenol-ascorbatetreatment was not accompanied by an abolishment of photooxidationof cytochrome b₅₅₉. A possible mechanism is proposed to account for these reactionsof cytochrome b₅₅₉ in the photosynthetic electron transportin chloroplasts. (Received April 4, 1972; )     

Scavenging of Hydrogen Peroxide in Prokaryotic and Eukaryotic Algae: Acquisition of Ascorbate Peroxidase during the Evolution of Cyanobacteria

Ascorbate (AsA) peroxidase was found in six species of cyanobacteriaamong ten species tested. Upon the addition of H₂¹⁸O₂ to thecells of AsA peroxidase-containing cyanobacteria, ¹⁶O₂ derivedfrom water and ¹⁸O₂ derived from H₂^I8O₂ were evolved in thelight. The evolution of ¹⁶O₂ was inhibited by DCMU and did notoccur in the dark, but ^I8O₂ was evolved even in the dark orin the presence of DCMU. Similar light-dependent evolution of¹⁶O₂ was observed in the cells of AsA peroxidase-containingEuglena and Chlamydomonas. However, the cells of AsA perox-idase-lackingcyanobacteria evolved only ¹⁸O₂ in either the light or dark.Furthermore, the quenching of chlorophyll fluorescence inducedby hydrogen peroxide was observed only in the cells of the AsAperoxidase-containing Synechocystis 6803, and not in the cellsof Anacystis nidulans which lacks AsA peroxidase. Thus, cyanobacteriacan be divided into two groups, those that has and those thatlacks AsA peroxidase. The first group scavenges hydrogen peroxidewith the peroxidase using a photoreductant as the electron donor,and the second group only scavenges hydrogen peroxide with catalase. (Received July 23, 1990; Accepted October 18, 1990)     

Sulphate Influx in Characean Cells: II. LINKS WITH LIGHT AND METABOLISM IN CHARA AUSTRALIS

Light filters and metabolic inhibitors have been used to investigatefurther the active transport of sulphate into Chara australis.Two states of influx, light (basal) and dark (transiently stimulated),have been described. The stimulated state noted on transferto dark has been found when the incident intensity of monochromaticlight is reduced, and when photosystem 2 in photosynthesis isinhibited, either by use of cut-ofT filters or by DCMU. Thelight influx is insensitive to CCCP when photosynthetic ¹⁴CO₂fixation is totally inhibited, and is less sensitive to DNPthan the dark influx. Dark influx is inhibited by CCCP, DNP,and NaCN but is insensitive to DCMU. It is proposed that a respiratoryATP source may be sufficient energy supply for sulphate influxand that the state of influx is under separate control. It issuggested that a ‘triggering’ mechanism may bringabout the change from the light- to the dark-influx state.     

Effects of dark preincubation and chloramphenicol on blue light-induced CO2 incorporation in Chlorella cells

Chlorella cells incubated in the dark longer than 12 hr showedpronounced blue light-induced ¹⁴CO₂ fixation into aspartate,glutamate, malate and fumarate (blue light effect), whereasthose kept under continuous light showed only a slight bluelight effect, if any. 2) During dark incubation of Chlorellacells, phosphoenolpyruvate carboxylase activity and the capacityfor dark ¹⁴CO₂ fixation decreased significantly, whereas ribulose-1,5-diphosphatecarboxylase activity and the capacity for photosynthetic ¹⁴CO₂fixation (measured under illumination of white light at a highlight intensity) did not decrease. 3) In cells preincubatedin the dark, intracellular levels of phosphoenolpyruvate and3-phosphoglycerate determined during illumination with bluelight were practically equal to levels determined during illuminationwith red light. 4) The blue light effect was not observed incells incubated widi chloramphenicol, indicating that blue light-inducedprotein synthesis is involved in the mechanism of the effect. (Received April 9, 1971; )     

Ethylene Release from Leaves of Xanthium strumarium L. and Zea mays L.

The release of ethylene into sealed Erlenmeyer flasks by intactleaves and leaf discs of Xanthium strumarium L. a C₃ plant andZea mays L. a C₄ plant were compared both in white light andin darkness. The effects of the presence or absence of addedCO₂ (in the form of sodium bicarbonate) the photosynthetic inhibitor3-[3,4-dichlorophenyl]-l, l-dimethyl urea (DCMU) and 1-aminocyclopropane-1-carboxylicacid (ACC), the precursor of ethylene in higher plants, werealso investigated. The rate of ethylene release from leaf tissue of Xanthium inthe absence of added CO₂ was markedly reduced in the light (i.e.at the CO₂ compensation point). Treatments that would enhancethe CO₂ availability to the tissue (i.e. added bicarbonate,darkness, treatment with DCMU) allowed higher levels of ethylenerelease. Incubation of the tissue with ACC considerably enhancedthe release of ethylene compared to that from the correspondingcontrol tissue without ACC. However, the pattern of ethylenerelease induced by the various treatments was similar with orwithout added ACC. When tissue, in the absence of added CO₂, was transferred fromlight to darkness, and back to light for 90 min periods, theethylene release rates Increased during the interposed darkperiod but resumed the lower rate during the final light period.The addition of CO₂ in the light resulted in a similar rateof ethylene release to that found in the dark. The overall pattern of ethylene release from Zea leaf tissuesubjected to light and dark in the presence or absence of addedCO₂ was similar to that of Xanthium. However, two or three timesmore ethylene was released from maize leaves in the light whenCO² was added compared to that generated in the dark. This isin marked contrast to Xanthium, where, under the light conditionsused, the ethylene release rate in the dark equalled or exceededthat occurring in the light, even in the presence of high levelsof CO₂. A very low rate of ethylene release was observed atthe CO₂ compensation point of maize. A speculative model is presented to explain how photosyntheticactivity might act as a key factor in regulating ethylene evolutionfrom leaf tissue in these experiments. It invokes the conceptof an inhibition by CO₂ of ethylene retention or breakdown thuspermitting more ethylene to be released from the leaves.     

Physiological Studies of the Sulpholipids of Diatoms

The sulpholipids of three species of freshwater and marine diatomNitzschia palae Kutz, Navicula muralis Lewin and Navicula incertaGrün, have been investigated under various culture conditions.The plant sulpholipid, sulphoquinovosyl diglyceride, was predominantlysynthesized in the light rather than in the dark while the unknownsulpholipids, designated as U₁ and U₂, were produced more inthe dark than in the light. It was found that cells starvedof carbon or sulphate utilized their sulpholipid reserve assources of these materials. Generally, cultures incubated inthe light and bubbled with air (with or without CO₂) showeda high level of incorporation of ³⁶S into sulpholipids. In culturesbubbled with oxygen-free nitrogen the incorporation of tracerwas very small. The photosynthetic and respiratory inhibitors,DCMU and DNP appreciably reduced the amount of tracer incorporatedinto the sulpholipids.     

Induction of the H+ Release from Thylakoid Membranes by Illumination in the Presence of Protonophores at High Concentrations

The generally observed light-induced uptake of protons intothe thylakoid lumen is diminished by adding protonophores. Insteadof the H⁺ uptake, the release of protons was observed duringillumination in the presence of various protonophores at highconcentrations, namely, 1 µM nigericin, 10 µM carbonylcyanidem-chlorophenylhydrazone or 30 µM gramicidin. An uncoupler,NH₄C1 (4 mM), and a detergent, Triton X-100 (0.02%), also inducedthe H⁺ release but a K⁺ ionophore, valinomycin, did not. Theamount of H⁺ released reached about 100 nmol H⁺ (mg Chl)^–1at pH 7.5 under continuous illumination. The rate of the H⁺release was similar to that of the conventional H⁺ uptake butits dark relaxation was much slower than that of the H⁺ uptake.We compared the H⁺ release in protonophore-added thylakoidswith the previously reported H⁺ release in coupling factor 1(CF₁-depleted thylakoids. The H⁺ release in thylakoids withnigericin showed similar characteristics to that in CF₁-depletedthylakoids in terms of their responses to pH, phenazine methosulfateand light intensity. Both types of H⁺ release were relativelyinsensitive to DCMU and were stimulated somewhat by DCMU atlow concentrations (around 200 nM). Nigericin did not inhibitthe superoxide dismutase activity of the membranes. These resultsindicate that the H⁺ release in protonophore-added thylakoidsand that in CF₁ depleted thylakoids involve the same mechanismand that water-derived protons from PS II that result from animpairment of the activity of superoxide dismutase, as previouslyproposed, are not involved. Judging from the rate of electronflow and the lumenal acidification under the illumination, weconclude that the H⁺ release is a light-dependent scalar processwhich can be observed in thylakoid membranes with high H⁺ permeability.The H⁺ release of this type was not observed in mitochondriafrom rat liver or in chromatophores from Rhodobacter sphaeroides. (Received November 29, 1990; Accepted June 27, 1991)     

Effect of hydrogen peroxide on the fluorescence and the G550 absorption change of spinach chloroplast fragments

Effects of H₂O₂ on the transient phase of fluorescence and thelight-induced absorption change of C550 in the presence of ferricyanidewere studied in spinach chloroplast fragments at room temperature.In the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU),the parameter of the variable fluorescence, work integral, wasincreased by the addition of H₂O₂ and the rate of its recoveryin the dark was decreased. The steady-state fluorescence yieldwas decreased by H₂O₂. Essentially the same results were obtainedin the absence of ferricyanide. In the presence of DCMU, H₂O₂ decreased the steady-state absorptionchange of C550 and inhibited its reoxidation in the dark. Thesame effects were observed when H₂O₂ was added to chloroplastfragments in the presence of DCMU and carbonyl cyanide m-chlorophenylhydrazone.From these data we concluded that the fluorescence quencherQ and C550 are not identical. ¹Present address: Department of Biology, Kyushu Dental College,Kitakyushu 803, Japan. (Received June 20, 1974; )     

Bisulphite-induced Inactivation of Growth and Chlorophyll Formation in Chlorella pyrenoidosa

Treatment of S-sufficient or S-deficient Chlorella pyrenoidosacells with NaHSO₃, during an 8-h period in the light, significantlydecreased their chlorophyll and dry matter contents when thecells were incubated in the presence or absence of SO₄²⁺. Incontrols lacking HSO₃^–, when the starting pH was 7.5,dry matter and chlorophyll contents increased slightly, whereasno significant changes in either occurred at a starting pH of3.0 when the cells and medium contained SO₄^–. In the dark,at both pH 3.0 and 7.5, dry matter and chlorophyll contentsdecreased slightly. Bisulphite treatment in the dark causedlittle decrease of either dry matter or chlorophyll when cellsand medium contained SO₄^2–. However, in its absence, drymatter decreased markedly, but there was little change of chlorophyllcontent in the dark. The interactions between HSO₃^– asa source of S and as an inhibitor of growth and chlorophyllformation are discussed in the context of the changes inducedby light and alternative sources of S. Overall, the harmfuleffects of HSO₃^– outweigh any role it has as a sourceof S, since its effects are ameliorated by SO₄^2–.     

Factors Controlling Induction of External Carbonic Anhydrase and Change in K?(CO2) of Photosynthesis in Chlorella regularis

Transfer of algal cells of Chlorella regularis from 3% CO₂ inair into ordinary air in the light increased external carbonicanhydrase (CA) activity as well as photosynthetic affinity forCO₂ by several-fold within 2 h. Since no noticeable differencewas observed in CA activity between intact cells and cell homogenates,CA seemed to be mainly localized on the cell surface. Changesin CA activity and K_?(CO₂) of photosynthesis were not observedin the dark. CA induction was 50%-inhibited by incubation with10 µM DCMU during adaptation of high-CO₂ cells to air,whereas it was considerably suppressed when high-CO₂ cells preincubatedwith DCMU in the light for 6 h or without DCMU in the dark for24 h were used. The change in K_?(CO₂) of photosynthesis wasonly slightly affected by DCMU. Uncoupler like carbonylcyanide-m-chlorophenyl-hydrazone(CCCP) and inhibitors of mitochondrial respiration (KCN plussalicylhydroxamic acid) suppressed CA induction during adaptationof high-CO₂ cells to low CO₂ conditions. These results suggest that photosynthesis is not essential forCA induction in Chlorella regularis when some amounts of photosyntheticproducts are previously stored in the cells and respirationis active. A decrease in K_?(CO₂) of photosynthesis during adaptationfrom high to low CO₂ was mostly independent on photosynthesis.However, light is essential for both phenomena. (Received July 16, 1990; Accepted January 21, 1991)     

The Effect of Hydroxymethanesulphonate on Photosynthesis in Chlorella pyrenoidosa

Photosynthesis under conditions known to favour glycollate excretionby algae did not result in glycollate excretion in a strainof Chlorella pyrenoidosa unless an inhibitor of glycollate oxidase,-hydroxypyridin-2yl-methane sulphonate (-HPMS), was present.This inhibitor increased the total amount of glycollate presentin the supernatant from the cells during photosynthetic carbondioxide fixation and gave accumulation of ¹⁴C in glycollateduring ¹⁴CO₂ fixation under conditions favouring glycollatesynthesis. At pH 8.3 -HPMS did not stimulate photosynthetic¹⁴CO₂ fixation in C. pyrenoidosa as occurs with some algae.Photoassimilation of acetate was inhibited by -HPMS, and thiswas shown to result from acetyl-CoA synthetase inhibition by-HPMS.