Studies on chlorophyll formation in Chlorella protothecoides III. Effects of chloramphenicol, cycloheximide, and ethionine on chlorophyll formation

Effects of chloramphenicol, cycloheximide, puromycin and ethionineon the light-independent and subsequent light-dependent processesof chlorophyll formation in "glucose-bleached" cells of Chlorellaprotothecoides were studied. These substances, except puromycin,strongly suppressed different phases of chlorophyll formation.Ethionine most strongly suppressed the light-independent phaseand chloramphenicol an early, relatively short process in thelight-dependent phase of chlorophyll formation. Cycloheximideseverely suppressed all phases of chlorophyll formation. Possibleimplications of these results for the biosynthesis of chlorophyllin algal cells are discussed. ¹ Present address: National Food Research Institute, Ministryof Agriculture and Forestry, Koto-ku, Tokyo 135, Japan. ² Laboratory of Entomology, Faculty of Agriculture, TamagawaUniversity, Machida-shi, Tokyo, Japan (Received October 5, 1972; )     

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; )     

Induced formation of ribulose 1,5-diphosphate carboxylase in Rhodopseudomonas spheroides with particular concern to its relation with chromatophore formation

A comparative study was made on features of the induced synthesisof RuDP carboxylase in three strains of R. spheroides with differentbiochemical properties. In strains Sb and Sa, which were able to grow under either light-anaerobicor dark-aerobic conditions, activities of RuDP carboxylase inthe light-grown cells were much higher than those in dark-growncells. The level of RuDP carboxylase activity in dark-growncells of the Sb strain (wild type strain) increased two to threetimes in the dark by incubating the heavy cell suspension underlow aeration, but, for a further increase in enzyme activity,a light-anaerobic condition was required. This is in contrastto the induced formation of bacteriochlorophyll which has beenshown to proceed actively in the dark as well as in the light.On the other hand, with dark-grown cells of the Sa strain, whichhad possible partial defects in the chlorophyll synthesis system,the induced synthesis of RuDP carboxylase under the light-anaerobiccondition was markedly retarded as compared to that with theSb strain. RuDP carboxylase formation was not induced in L-57(a colorless mutant) under any of these conditions. The induced formation of RuDP carboxylase, as well as of bacteriochlorophyll,under the light-anaerobic condition was considerably suppressedby hydroxyurea and mitomycin C. This suggests that the geneticcontrol systems of RuDP carboxylase synthesis may be closelyrelated with those for the formation of the photosynthetic apparatus. ¹This work was supported in part by Public Health Research GrantAM 08016 from the National Institute of Arthritis and MetabolicDiseases, U.S.A. (G. K.). ²Present address: Laboratory of Radioisotope Experiment, TohokuUniversity School of Medicine, Sendai, Japan. (Received September 6, 1968; )     

EFFECTS OF LIGHT ON THE DEOXYRIBONUCLEIC ACID FORMATION AND CELLULAR DIVISION IN CHLORELLA PROTOTHECOIDES

1. It has been demonstrated previously that when Chlorella protothecoidesis grown in a medium rich in glucose and poor in nitrogen source(urea), chlorophyll-less cells with markedly degenerated plastids—called "glucose-bleached" cells—are produced eitherin the light or in darkness. When the glucose-bleached cellsare incubated in a medium enriched with the nitrogen sourcebut without added glucose, normal green cells with fully organizedchloroplasts are obtained in the light, and pale green cellswith partially organized chloroplasts in darkness. During theseprocesses of chloroplast development in the glucose-bleachedcells, there occurs, after a certain lag period, an active DNAformation followed by a more or less synchronous cellular division.In the present study the effects of light on the DNA formationand cellular division were investigated in the presence of CMUor under aeration of CO²-free air to exclude the interveninginfluence of photosynthetic process.
2. It was revealed thatlight severely suppresses the DNA formationand cellular divisionof the glucose-bleached cells while enhancingremarkably theirgreening. The suppression was saturated atthe light intensityof about 1,000 lux. Blue light was mosteffective, being followedby green, yellow and red light inthe order of decreasing effectiveness.
3. Further experiments unveiled that light exerts two apparentlyopposing effects on the DNA formation depending upon the timeof application during the incubation of algal cells. When thealgal cells were illuminated only during the lag period beforethe active DNA synthesis, there occurred an enhancement of theDNA synthesis occurring during the subsequent dark incubation.When, on the other hand, the cells were transferred to the lightfrom darkness at or after the start of the DNA synthesis, itcaused an almost complete abolition of the subsequent synthesisof DNA in the algal cells. No such effects of light were observedwith RNA and protein (total)
4. These findings were discussedin relation to the process ofchlorophyll formation occurringconcurrently in the algal cells.

(Received August 10, 1967; )     

Ribulose-1, 5-diphosphate carboxylase of Chromatium strain D

RuDP carboxylase isolated from autotrophically grown cells ofphotosynthetic sulfur bacterium, Chromatium strain D, was partiallypurified by (NH₄)₂SO₄ precipitation and Sephadex G-200 gel filtration.The molecular size of the bacterial RuDP carboxylase was foundto be large, analogous to that of the plant enzyme, in agreementwith results of previous workers. Sucrose density gradient centrifugationshowed the S_rel to be approximately 18; the omission of Mg⁺⁺caused no dissociation of the enzyme molecule in its subunits.Chromatium RuDP carboxylase showed similarities to the plantenzyme in some of its kinetic properties; (a) a shift of pHoptimum to the neutral side from the alkaline side on the additionof Mg⁺⁺, (b) deviation of the substrate concentration (NaHCO₃)-activityrelationship from the MICHAELIS formula and (c) a marked stimulativeeffect of Mg⁺⁺. A unique sigmoidal saturation curve of the enzymeto RuDP, which had been detected in Rhodospirillum rubrum andRhodopseudomonas spheroides RuDP carboxylase in the absenceof Mg⁺⁺, was not found. Another characteristic feature of ChromatiumRuDP carboxylase is its partial immunological response to therabbit anti-spinach RuDP carboxylase serum as detected by theinhibition of the carboxylation reaction due to the antibody-antigenreaction. ¹Part X, Structure and Function of Chloroplast Proteins. Supportedin part by research grants from the Ministry of Education ofJapan (No. 8719) and USPHS (AM-10792-03) (Received July 4, 1969; )     

Effect of abscisic acid on differentiation and ribulose diphosphate carboxylase of chloroplasts

Daucus carota tissues were grown on Murashige-Skoog medium (MS)at different concentrations with abscisic acid (ABA). Sevenbands of chloroplast fractions were obtained on a sucrose gradient.At 10^–5M, ABA highly increased chlorophyll and proteinnitrogen content of medium density chloroplasts. With increasingage of the tissues, the most active chloroplasts according totheir ¹⁴CO₂ fixation were found in smaller numbers. When treatedwith 10^–5 M ABA, 34 day-old tissues cultivated in vitroshowed the chloroplast pattern of 110 day-old tissues. The effectof ABA—given to the tissues during a short pretreatmentor continuously present in the culture medium—on the ribulosediphosphate carboxylase activity was analysed. It was foundthat ABA at 10^–5 M strongly inhibited ¹⁴CO₂ fixation. (Received December 20, 1977; )     

Studies on ribonucleic acids from Chlorella protothecoides with special reference to the degradation of chloroplast RNA during the process of "glucose-bleaching"

By growing Chlorella protothecoides under certain nutritionaland light conditions the following three different types ofalgal cells were obtained: (i) normal "green" cells grown ina medium rich in a nitrogen source (urea) and poor in glucoseunder illumination, (ii) "etiolated" cells cultivated in thesame medium in darkness, and (iii) "glucose-bleached" cellsgrown, in the light or in darkness, in a medium rich in glucoseand poor in the nitrogen source. The "glucose-bleached" cellscontain profoundly degenerated plastids, and the "etiolated"cells have only partially organized plastids. From these algalcells RNA was extracted by the cold phenol method, and fractionatedby MAK column chromatography and sucrose density gradient centrifugation,making use of ³²P-labelled E. coli RNA as the internal marker.It was found that in comparison with the green cells that arerich in chloroplast ribosomal RNA as well as in nonchloroplastic("cytoplasmic") ribosomal RNA, the etiolated cells possess acomparable amount of "cytoplasmic" rRNA but a significantlylesser amount of chloroplast rRNA. Both types of rRNA existat extremely low levels in the glucose-bleached cells. During the process of bleaching (chloroplast degeneration) ofthe green cells induced by the addition of a high concentrationof glucose, marked changes were observed in the patterns offractionation of RNA as followed by the above procedures. Itwas disclosed that the chloroplast rRNA is rapidly degradedduring an early phase of the bleaching process, while the quantityof "cytoplasmic" rRNA remained almost unaltered. ¹Part of this work was reported at the Symposium on Cell Differentiationsponsored by the Institute of Applied Microbiology, Universityof Tokyo, in November 1965, and at the Symposium on Biogenesisof Subcellular Particles, the 7th Internatl. Congress of Biochemistry,Tokyo, 1967. ²Present address: Faculty of Pharmaceutical Sciences, Universityof Hokkaido, Sapporo.     

Effect of the age of tobacco leaves on photosynthesis and photorespiration

Relationships among the activities of enzymes related to photosynthesisand photorespiration, and ¹⁴CO₂ photosynthetic products wereinvestigated with individual tobacco leaves attached to thestalk from the bottom to the top. P-glycolate phosphatase ofthe chloroplasts and glycolate oxidase of the peroxisomes hadtheir maximum activities in the 25th leaf from the dicotyledons.Maximum photorespiration was similarly distributed. The highestratio of serine-¹⁴C to glycine-¹⁴C in the photosynthesates andmaximum glycolate formation were also observed in the 25th leaf.Glutamateglyoxylate aminotransferase, serine hydroxymethyltransferaseand glycine decarboxylase were more active in the upper leaves.RuDP carboxylase had nearly constant activity in all leaves,except for the youngest in which activity decreased. MaximumCO₂ photosynthesis and enzyme activity for the C₄ dicarboxylicacid cycle occurred in the upper, youngest leaf. Distributionof photosynthetic CO² fixation among the leaves did not coincidewith RuDP carboxylase activity. The photosynthetic capacityappeared to be better related to the distribution pattern forenzymes of the C₄ dicarboxylic acid pathway, i.e. PEP carboxylase,pyruvate Pi dikinase and 3-PGA phosphatase in the upper leaves.The results suggest that the C₄ dicarboxylic acid pathway participates,to some extent, in photosynthesis in young leaves of tobacco,a dicotyledonous plant. ¹This work was reported at the Annual Meeting (1970) of theJapanese Plant Physiologists in Kobe. ²The Central Research Institute, Japan Monopoly Corporation1-28-3, Nishishinagawa, Shinagawaku, Tokyo, 141 Japan. (Received November 2, 1972; )     

Changes of Anatomical Features, Photosynthesis and Ribulose Bisphosphate Carboxylase-Oxygenase Content of Mango Leaves

Changes in anatomical and physiological features, includingchanges in amount per unit area of anthocyanin and chlorophyll,in leaves of seedling mango (Mangifera indica L. cv. Irwin)trees were determined to understand what controls the rate ofphotosynthesis (Pn) at various stages of development. The youngleaves of seedling trees contained high concentrations of anthocyanin.During enlargement of leaves, the disappearance of anthocyaninand the accumulation of chlorophyll occurred concomitantly;the anthocyanin content began to decrease markedly once theleaf area had reached a maximum. During the early period ofleaf development, the thickness of mesophyll tissue decreasedtemporarily, but when the length of the leaf reached half thatof a mature leaf, the mesophyll began to thicken again. Smallstarch grains appeared in the chloroplasts of the young leavesand chloroplast nucleoids (ct-nuclei) were distributed throughoutthe chloroplasts. When leaves matured, ct-nuclei were displacedto the periphery of chloroplasts because of the accumulationof large starch grains. Compared with young leaves, green andmature leaves contained greater concentrations of ribulose bisphosphatecarboxylase-oxygenase (RuBisCO) protein. The results of immunocytochemicalexamination of RuBisCO under the light microscope reflectedthe results of electrophoresis measurements of RuBisCO. Pn waslow during the chocolate-coloured stage of early leaf development.In green and mature leaves Pn was higher; the average Pn was7·6 mg CO₂ dm^-2 h^-1 under light at intensities above500 µmol m^-2 s^-1.Copyright 1995, 1999 Academic Press Mangifera indica L., mango leaf, chloroplast nucleoids, chloroplast ultrastructure, starch accumulation, anthocyanin, chlorophyll, DAPI staining, SDS-PAGE, immunocytochemical technique     

DEGRADATION AND FORMATION OF SULFOLIPID OCCURRING CONCURRENTLY WITH DE- AND RE-GENERATION OF CHLOROPLASTS IN THE CELLS OF CHLORELLA PROTOTHECOIDES

1. It has been demonstrated that when the cells of Chlorella protothecoidesare grown mixotrophically under illumination in a medium richin nitrogen source (urea) and poor in glucose, the normal greencells are obtained, while in a medium rich in glucose and poorin the nitrogen source, entirely chlorophyll-less cells withprofoundly degenerated plastids ("glucose-bleached" cells) areproduced, irrespective of whether in the light or in darkness.The "glucose-bleached" cells turn green with regeneration offully organized chloroplasts when incubated in a nitrogen-enrichedmedium in the light ("light-greening"), while in the dark theybecome pale green with formation of only partially organizedchloroplasts ("dark-greening"). When, on the other hand, thegreen cells are transferred into a medium enriched with glucose,they are bleached fairly rapidly with degeneration of chloro-plastsin the light as well as in darkness ("bleaching"). Using ³⁵Sas a tracer, investigations were made on the changes of contentsof the algal cells in sulfolipid and other sulfur compoundsduring the processes of the greening and bleaching.
2. By determiningthe radioactivities of chromatographically separatedsulfur-containingcompounds of the uniformly ³⁵S-labeled green("G") and "glucose-bleached"("W") cells, it was found thatthe concentration of a speciesof sulfolipid (discovered byBENSON et al.) as well as thoseof glutathione, sulfotriosesand most of the other sulfur-containingcompounds were at least5 times higher in the "G" cells thanin the "W" cells, whilesulfoquinovosyl glycerol was presentin approximately equalamounts in the two types of cells.
3. Phospholipidcontents and compositions in the two types of algalcells werefound to be practically identical.
4. The sulfolipid contentof algal cells increased and decreasedalmost in parallel withthe processes of greening and bleaching,respectively.
5. Studyingthe mode of incorporation of radiosulfate into varioussulfurcompounds of algal cells during the processes of "light-anddark-greening" and "bleaching" (lasting about 70 hr), itwasfound that active ³⁵S-incorporation into sulfolipid occurredthroughout the process of "light-greening," while in the "dark-greening"and "bleaching" the active incorporation abruptly ceased afterthe initial 24 hr period of experiments. It was suggested thatthe biosynthesis of the sulfolipid is closely related to theformation of photosynthetic apparatus in chloroplast.
6. Whenthe ³⁵S-labeled green cells were bleached in a medium containingno radiosulfate, the ³⁵S-sulfolipid and most of other ³⁵S-sulfurcompounds decreased markedly but the ³⁵S-sulfoquinovosyl glycerolincreased considerably. It was inferred that the deacylationof the sulfolipid, a surfactant lipid, with formation of watersoluble sulfoquinovosyl glycerol may be a cardinal event ofbleaching process, causing a disintegration of the intact architechtureof photosynthetic apparatus.
7. Based on these observations itwas concluded that the sulfolipidis an integral component ofphotosynthetic structure.

¹This work was partly reported at the Symposium on Biochemistryof Lipids, sponsored by the Agricultural Chemical Society ofJapan, Sapporo, July, 1964.     

Developmental and Varietal Comparisons of Pod Carboxylase Levels in Pisum sativum L.

The activities of phosphoenolpyruvate (PEP) carboxylase andribulose-1, 5-bisphosphate (RuDP) carboxylase have been determinedin the developing pod walls of six genotypes of Pisum sativum.Genotypes were chosen which varied in pod characters such aschlorophyll content and tissue morphology, which it was hopedwould be associated with variation in carboxylase levels. Whilst both enzymes were detected in all genotypes, the levelsof activity varied considerably with pod type and with age.In general RuDP carboxylase activity correlated with chlorophyllconcentration, and yellow podded types had considerably lessactivity than green types. The yellow podded genotypes, however,contained significantly higher levels of PEP carboxylase which,in terms of total carboxylase activity, compensated for thelower RuDP carboxylase levels. The activities of both enzymes were determined within the endocarpand within the mesocarp plus exocarp, using 16-day-old pods.All genotypes showed an enrichment for PEP carboxylase in theendocarp and all but one genotype showed a similar enrichmentfor RuDP carboxylase activity in this layer. The role of the carboxylase enzymes within the pod wall is discussedand it is suggested that their main function may be to maintainan appropriate level of CO₂ within the pod cavity as well asrecycling carbon to the developing seeds. Pisum savitum L., pea, pods, carboxylase levels, genetic variation     

The enzyme system for the entrance of 14CO2 in the dark CO2-fixation of brown algae

High activity of phosphoenolpyruvate (PEP)-carboxykinase, orADP: oxalacetate (OAA) carboxy-lyase activity (a kind of EC4. 1. 1. 32) was discovered in enzyme extracts or partiallypurified preparations obtained from the brown algae, Eiseniabicyclis, Dictyota dichotoma, Spatoglossum pacificum; and Hizikiafusiformis. Enzyme activities were determined by measuring theradioactivity incorporated in the products of dark ¹⁴CO₂-fixationand by spectrophotometric determinations. Except for the lowactivity of "malic enzyme" (EC 1. 1. 1.40), no activities ofother carboxylases, i.e. PEP-carboxylase, PEP-carboxytransphosphorylase,and pyruvate carboxylase could be detected in algal extractsprepared under various conditions. Malate dehydrogenase (EC1. 1. 1. 37), fumarase (EC 4. 2. 1. 2), and glutamic: oxalacetictransaminase (EC 2. 6. 1. 1) were also detected. The algal PEP-carboxykinase required ADP and Mn²⁺ for maximumactivity in the carboxylation reaction; and ATP and Mn²⁺, butnot GTP, for maximum activity in both the decarboxylation andOAA-¹⁴CO₂-exchange reactions. The optimum pH of purified PEP-carboxykinase was in the regionof 7.0 to 7.3 in both the carboxylation and decarboxylationreactions, and its Km values for HCO₃^–, PEP, and ADP were10 mM, 0.3 mM, and 0.07 mM, respectively, in the carboxylationreaction, and values for OAA and ATP were 0.05 mM and 0.4 mM,respectively, in the decarboxylation reaction. Furthermore,the decarboxylation reaction was markedly inhibited by 20 mMHCO₃^–. The physiological role of PEP-carboxykinase as the enzyme responsiblefor the entrance reaction of the dark CO₂-fixation is discussed. ¹ Contributions from the Shimoda Marine Biological Station ofTokyo Kyoiku University, No. 236. This work was supported inpart by a Grant-in-Aid for Co-operative Research from the Ministryof Education, Japan and Matsunaga Science Foundation (to T.Ikawa). ² Present address: Department of Antibiotics, the National Instituteof Health, Shinagawa, Tokyo, Japan. (Received February 22, 1972; )     

Development of ribulose 1,5-diphosphate carboxylase in nonphotosynthetic endosperms of germinating castor beans

Ribulose 1,5-diphosphate (RuDP) carboxylase has been partially purified from dark-grown nonphotosynthetic endosperms of germinating castor beans (Ricinus communis var. Hale). The Km values for RuDP, HCO(3) (-), and Mg(2+) are 0.51, 33, and 1.78 mm, respectively. The pH optimum for the carboxylation reaction is pH 7.5. Germination is required for the development of the carboxylase in the endosperms. The enzyme reaches a maximal activity in 4- to 5-day-old dark-grown seedlings (which have an endosperm weight of approximately 0.75 g fresh weight/bean) and then declines. Total endosperm carboxylase activity is 1230 nmoles/min.g fresh weight which is 25 and 50% of the total activity developed in soybean and maize leaves, respectively. Specific activity of the carboxylase in crude soluble endosperm preparations (which contain enzymic and storage protein) is 0.05 mumole/min.mg protein. This is 5 times greater than the specific activity of RuDP carboxylase in soluble preparations from etiolated leaves. During germination the V(max) of the endosperm carboxylase for RuDP increases 10-fold. Development of the enzyme is inhibited 90% by the exposure of the endosperm to 2 mug/ml cycloheximide or 50 mug/ml chloramphenicol. Light (or phytochrome Pfr) is not required for the synthesis of the enzyme. Electron photomicrographs of dark-grown endosperm cells (with peak RuDP carboxylase activity) show proplastids with several invaginations of the inner membrane but no prolamellar-like structures.     

Correlation of Activity and Amount of Ribulose 1,5-bisphosphate Carboxylase with Chloroplast Stroma Crystals in Water-Stressed Willow Leaves

Changes in the activity and amount of ribulose 1,5-bisphosphate(RuBP)carboxylase (E.C. 4.1.1.39 [EC] ) were studied in well-watered plantsof Salix ‘aquatica gigantea’ and in similar plantsduring three different water stress treatments and after rewatering.The chloroplast ultrastructure of these plants was examinedby electron microscopy. The amounts of crystallized proteinin the chloroplast stroma were assessed according to the areaof crystal structure seen in the thin sections. RuBP carboxylase activity decreased with decreasing leaf waterpotentials but recovered upon rewatering, except when leaveshad been exposed to severe water stress. The percentage of totalchloroplast area made up of crystal inclusions decreased withdecreasing leaf water potentials. After rewatering, the crystalseither disappeared or the amount decreased markedly. Both RuBPcarboxylase activity and the area of crystal inclusions increasedinitially with increased extractable RuBP carboxylase proteinbut decreased with further increases above 6700–7000 µgRuBP carboxylase protein mg^–1 chlorophyll. In well-wateredand water-stressed plants the activity of RuBP carboxylase,based on amount of chlorophyll, increased with an increasingamount of crystal inclusions in the chloroplast stroma. In rewateredplants no such correlation was observed, and the low percentageof crystal inclusions in the chloroplast area was independentof RuBP carboxylase activity. Key words: Chloroplast stroma crystals, ribulose 1,5-bisphosphate carboxylase, Salix, water stress     

Cellular Levels of Ribulose 1,5 Bisphosphate Carboxylase and Chloroplast Compartment Size in Wheat Mesophyll Cells

Pyke, K. A. and Leech, R. M. 1987. Cellular levels of ribulose1,5 bisphosphate carboxylase and chloroplast compartment sizein wheat mesophyll cells.—J. exp. Bot. 38: 1949–1956. The amount of the photosynthetic enzyme ribulose 1,5 bisphosphatecarboxylase (RUBISCO),as determined in mesophyll cells in primarywheat leaves was related to the size of the chloroplast compartmentwithin the cell for wheat species of three ploidy levels. Asimilar comparison was made for several genotypes of the hexaploidbreadwheat Triticum aestivum. Estimation of total chloroplastvolume per mesophyll cell was made assuming chloroplasts tobe oblate spheroid in shape. A significant correlation was found between the amount of RUBISCOper cell and the total chloroplast volume per cell for diploid,tetraploid and hexaploid wheat species. A significant correlationbetween cellular RUBISCO level and total chloroplast volumeper cell was also observed for a range of genotypes of the hexaploidT. aestivum but these genotypes of T. aestivutn accumulate agreater amount of RUBISCO per unit chloroplast volume than doany other wheat species. For these genotypes of T. aestivumthe stromal concentration of RUBISCO was estimated at 0·5mol m^–3 with a ribulose Msphosphate binding site concentrationof 4·0 mol m^–3. These results are discussed with respect to a gene dosage hypothesisto explain the accumulation of RUBISCO in leaf mesophyll cells. Key words: Ribulose, bisphosphate carboxylase, wheat chloroplasts, mesophyll cells     

Enhancing effects of CO2 on chloroplast regeneration in glucose-bleached cells of Chlorella protothecoides I. Role of non-photosynthetic CO2-fixation in chloroplast regeneration

Carbon dioxide enhanced chloroplast regeneration in glucose-bleachedcells of Chlorella protothecoides in the presence of CMU inthe light. Both the formation of chlorophyll and the synthesesof RNA and protein were considerably enhanced. The CO₂ metabolism of algal cells during greening was investigatedusing ¹⁴C-bicarbonate as the tracer. Radiocarbon was largelyincorporated into purine and pyrimidine bases in nucleic acidand the arginine in protein, specifically at the crabon atomsderived from carbamylphosphate. ¹Part of this investigation was reported at the conference onthe "Autonomy and biogenesis of mitochondria and chloroplasts"held at Canberra in 1969 (4). (Received August 19, 1975; )     

Studies on {partial}-amino levulinic acid deydratase in radish cotyledons during chloroplast development

The subcellular localization and biosynthetic site of 8-aminolevulinic acid dehydratase [EC 4.2.1.24 [EC] , ALAD] were investigatedin relation to chloroplast development in radish cotyledons. ALAD was mainly located in the chloroplasts and cytoplasm. Mostof the ALAD in the chloroplasts was readily released by hypotonicshock. The enzyme was also found in the proplastids of etiolatedcotyledons. The normal increase in the activity of ALAD in the chloroplastsas well as the cytoplasm was inhibited by cycloheximide butunaffected by D-threo chloramphenicol and kanamycin during thegreening of radish cotyledons. We concluded that the ALAD inboth the cytoplasm and chloroplasts was synthesized on the cytoplasmic80S-ribosomes. This suggests that the ALAD formed on the 80S-ribosomesmight be incorporated into chloroplasts during their development. When etiolated radish seedlings were illuminated, ALAD in boththe cytoplasm and chloroplasts increased up to the point ofthe full development of the chloroplasts, and thereafter itdecreased. (Received August 20, 1975; )     

Effect of cycloheximide on the process of "glucose-bleaching" in Chlorella protothecoides

The process of bleaching of Chlorella protothecoides inducedby the addition of glucose was strongly inhibited by cycloheximide,an inhibitor of protein synthesis, whereas it was suppressedonly weakly by chloramphenicol, puromycin and ethionine. Whencycloheximide was added simultaneously with glucose at the beginningof die bleaching experiment, no bleaching of algal cells occurredduring the subsequent incubation. When it was added after glucose,the bleaching of algal cells proceeded for a period of timeas actively as in the control, then gradually ceased. Cycloheximidewas found to suppress the uptake of glucose by algal cells,and to severely inhibit the assimilation of glucose into lipidswhen added at the beginning of the bleaching experiment. Theseinhibitory effects of cycloheximide are discussed in relationto the induction of "glucose-bleaching" in algal cells. (Received December 16, 1968; )     

Correlation of ribulose 1,5-diphosphate carboxylase activity with chlorophyll content and ultrastructure in induced mutants of Hordeum vulgare

Ribulose 1,5-diphosphate (RuDP) carboxylase activity was examined in barley mutants deficient in chlorophyll, and the results were correlated with chlorophyll content and ultrastructure of these mutants. The mutants were induced by diethyl sulfate (dES) or ethyl methane sulfonate (EMS) in the inbred barley variety Himalaya. Essentially no RuDP carboxylase activity was found in 15 albino mutants tested, but mutants with reduced chlorophyll content show large variations in RuDP carboxylase activity. Three general groups of mutants can be recognized. One group has reduced chlorophyll content, but no reduction in RuDP carboxylase activity (dES 7, dES 19, and 28-3398). A second group shows reduced chlorophyll content and proportionally reduced RuDP carboxylase activity (EMS 11, dES 18, and yv), and a third group shows RuDP carboxylase activity reduced more than chlorophyll content (Unk 3, dES 1, Coast V, dES 17, and dES 9). Thus, no strict correlation between RuDP carboxylase activity and chlorophyll content was found in the mutants tested. A reduction in stroma density was observed in the mutants having greatly reduced RuDP carboxylase activity.Scientific Paper No. 3256, College of Agriculture, Washington State University, Pullman, Projects 1920 and 1916. Supported in part by funds provided for medical and biological research by Washington State Initiative Measure 171.     

The Effect of Antibiotics on the Ultrastructure and Photochemical Activity of a Developing Chloroplast

The effects of the antibiotics chloramphenicol and cycloheximideon the ultrastructure of the chloroplast in greening cells ofEuglena gracilis strain Z have been investigated. The rate ofchloroplaat development in the presence of either antibioticwas closely related to that of chlorophyll production. Chloramphenicol,which at 10 mg/ml inhibits chlorophyll synthesis but not celldivision, caused a marked inhibition of the development of chloroplaststructure. The chloroplasts were smaller than those of untreatedcells and contained a smaller number of internal lamellae. Mostof these lamellae were not appressed and the results supportthe suggestion that chloramphenicol inhibits the synthesis ofa protein responsible for the fusion of individual lamellaein the chloroplast. Measurement of the photochemical activityof chloroplasts isolated from chloramphenicol-treated cellsshowed that the photoreduction of NADP from water (photosystemI+II), photosystem II activity, and photosystem I activity weregreatly inhibited when compared with chloroplasts from untreatedcells. In contrast, cycloheximide at 2.5 to 5.0 µg/mlinhibited cell division but allowed the chloroplasts to developafter a lag phase, the length of which was related to the concentrationof antibiotic employed. The number of lamellae per chloroplastand the degree of appression of the lamellae in chloroplastsof cycloheximide-treated cells and untreated cells were comparable.After 48-h illumination the photochemical activities of chloroplastsisolated from cycloheximide-treated cells were about 50 percent of those of the untreated cells.