Spectral effectiveness in chlorophyll and 5-aminolevulinic acid formation during regreening of glucose-bleached cells of Chlorella protothecoides

Regreening of glucose-bleached cells of Chlorella protothecoidesis stimulated by light. Spectral effectiveness in the processshowed maxima around 370, 440 and 480 nm, suggesting a flavoproteinas primary photoreceptor. Action spectra of ALA synthesis provedto be similar to those of chlorophyll formation, indicatingthat light stimulation of greening in this alga is regulatedat the first step of chlorophyll biosynthesis. ¹ Present address: Institute of Applied Microbiology, Universityof Tokyo, Tokyo 113, Japan. (Received March 27, 1978; )     

Studies on chlorophyll formation in Chlorella protothecoides II. Enhancing effects of light and suppressive effects of glucose on the development of porphyrin-synthesizing activity during light-induced greening of etiolated algal cells

Frozen and thawed cells, as well as sonicated cell preparationsof Chlorella protothecoides, were assayed for activity to synthesizeporphyrins from added ALA or PBG. Activity was very low in etiolatedcells, and markedly developed during the process of light-inducedgreening. The development of activity was strongly suppressedby glucose. Activity for the synthesis of URO(gen) from ALAwas initially developed, then the formation of COPRO(gen)-synthesizingactivity ensued. In glucose-suppressed cells as in cells incubatedin continuous darkness, URO was the main porphyrin producedand COPRO was virtually missing in the reaction products withadded ALA, indicating that development of activity for the conversionof URO(gen) to COPRO(gen) is greatly enhanced by light and isrepressed by added glucose. Suppressive effects of CP and CHon the development of porphyrin-synthesizing activity were alsostudied. From these and other results, a tentative scheme ispresented for the enhancing effects of light and the suppressiveeffects of glucose on the development of porphyrin-synthesizingactivity in etiolated algal cells, in correlation with the effectson other processes of chlorophyll biosynthesis. ¹ Present address: National Food Research Institute, Ministryof Agriculture and Forestry, Koto-ku, Tokyo 135, Japan. (Received April 6, 1972; )     

Role of Light in 5-Aminolevulinic Acid Formation in Wild Strain and Mutant C-2A' Cells of Scenedesmus obliquus

In dark-grown wild strain cells of Scenedesmus obliquus, 5-aminolevulinicacid (ALA) formation was induced by irradiation with a weakblue light, as in its mutant C-2A' cells. The induction wasinhibited by distamycin A, 6-methylpurine, cycloheximide andchloramphenicol. After the light induction, the ALA formationcould proceed in the dark as well as in the light, in such heterotrophicallygrown wild type cells, but not in the greening mutant C-2A'cells. In the latter, ALA formation was dependent on red light,as well as on blue light, in the presence of CMU. The amountsof protochlorophyll in the mutant cells increased upon cessationof illumination and decreased with subsequent irradiation withblue and red light. The possible role of protochlorophyll asa photoreceptor in regulation of ALA formation in the mutantcells is discussed. ¹Present address: Laboratory of Chemistry, Faculty of Medicine,Teikyo University, Otuka, Hachioji, Tokyo 192-03, Japan. (Received January 17, 1981; Accepted April 30, 1981)     

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; )     

RIBONUCLEIC ACIDS APPEARING DURING THE PROCESS OF CHLOROPLAST REGENERATION IN THE "GLUCOSE-BLEACHED" CELLS OF CHLORELLA PROTOTHECOIDES

1. Investigations were made on the modes of synthesis of differentspecies of RNA which appear during the greening (chloroplastregeneration) of the "glucose-bleached" cells of Chlorella protothecoidescontaining profoundly degenerated plastids.
2. RNAs were extractedfrom the algal cells which had been labelledwith ³²P for 1hr before harvesting at different stages of thegreening inthe light and in darkness, and subjected to columnchromatographywith methylated albumin-coated kieselguhr. Itwas found that,during the greening process, the elution profilesof RNAs, interms of the optical density at 260 mµ and³²P-radioactivity,changed profoundly.
3. Based on these and other results, it wasconcluded that duringan early phase of the chloroplast regenerationin the glucosebleachedalgal cells, there occurs an active formationof both ribosomalRNAs (rRNAs) and the RNAs corresponding tosoluble RNA (sRNA),the formation coming, however, later toa standstill when thesynthesis of chlorophyll has proceededto a certain level. Thequantity ratio of sRNA to rRNA was foundto be constant (30:70)at different stages of the greening (bothin the light and indarkness), with a few exceptions. The synthesisof the chloroplastribosomal RNA is markedly accelerated bylight, and its maximumrate is observed sometime later thanthat of the non-chloroplast("cytoplasmic") ribosomal RNA. Itwas suggested that there areat least two different sites ofsynthesis of ribosomal RNAs,one in the plastid and the otheroutside of it (most probablyin the nucleus).

¹A part of this work was reported at the Symposium on Cell Differentiationsponsored by the Institute of Applied Microbiology, Universityof Tokyo, in November 1965. ² Present address: Institute for Plant Virus Research, Ministryof Agriculture and Forestry, Aoba-cho, Chiba.     

Effects of Podolactone-Type Inhibitors and Abscisic Acid on Chlorophyll Biosynthesis in Barley Leaves

The effects of podolactone-type plant-growth inhibitors on thebiosynthesis of chlorophyll and its precursor -aminolevulinicacid (ALA) in etiolated barley have been studied and comparedwith those of abscisic acid (ABA). Podolactone E was one ofthe most potent inhibitors and it significantly inhibited chlorophyllformation at 0.1 µM after exposing barley leaves to lightfor 12 h. A lag phase of 4 to 6 hours in the inhibition of synthesisof ALA and chlorophyll by podolactone-type inhibitors occurredin light, but disappeared after preincubation in darkness for15 hours. ABA was the most potent inhibitor of synthesis ofALA but not of chlorophyll. We postulate that the effect ofthe inhibitors is to suppress de novo protein synthesis, possiblyat the translational level. This view is supported by the effectof the compound on -amylase production induced in barley embryosby GA₃. ¹Biology Department, Utah State University, Logan, Utah; sabbatical1981 at University of Melbourne. ²Biology Department, Humboldt State University; Visiting Professor,Utah State University, August 1982, Summer 1983. (Received November 1, 1983; Accepted March 26, 1984)     

Regeneration of photosystem II and phycobilin pigments in photoorganotrophically grown Anabaena variabilis

Regeneration of photosynthetic activity and phycobilin pigmentswas studied with cells of Anabaena variabilis lacking photosystemII activity and phycobilin pigments. Regeneration was achievedonly when the cells were incubated in the presence of nitrateor nitrite. The addition of ammonium salts or urea was far lesseffective. Nitrate-directed regeneration was independent oflight and inhibited by chlorate. Dark-regenerated cells, however,differed from light-regenerated ones in that the former wereincapable of excitation transfer from phycocyanin to pigmentsystemII chlorophyll a, although they emitted fluorescence of pigmentsystem II chlorophyll a origin, if illuminated by the lightabsorbed by chlorophyll. The regeneration process inAnabaenacells is assumed to consist of two steps: [1] light-independent,nitratesupported synthesis of phycobilin pigments and photosystemII integrity, followed by [2] light-directed formation of excitationtransfer from phycocyanin to pigment system II chlorophyll a.An antibiotic study revealed that the former is associated withprotein synthesis, while the latter isnot. ¹ Present address: Ocean Research Institute, University of Tokyo,Nakano, Tokyo 164, Japan. (Received November 19, 1975; )     

Enzymatic Activities for the Synthesis of Chlorophyll in Pigment-Deficient Variegated Leaves of Euonymus japonicus

The enzymes involved in the biosynthesis of chlorophyll (Chl)in pigment-deficient variegated leaves of Euonymus japonicuswere investigated. Each variegated leaf was composed of clearlydelineated green and white sectors. The white sectors containedalmost no Chls. The rate of synthesis of 5-aminolevulinic acid(ALA) in the white sectors in vivo was twice that in the greensectors. The level of glutamate 1-semialdehyde aminotransferasein the white sectors was much higher than that in the greensectors. Plastidic tRNA^Glu was also present at substantial levelsin the white sectors, indicating that the system for synthesisof ALA was very active in the white sectors. The activity of porphobilinogen (PBG) synthase in the whitesectors in vitro was twice that in the green sectors. In thewhite sectors the rate of porphyrin synthesis from PBG was 4-to 6-fold higher than in the green sectors. We measured Mg-chelataseactivity indirectly in both sectors by monitoring the accumulationof Mg-protoporphyrin IX in the presence of 2,2'-dipyridyl, whichinhibits isocyclic ring formation with the resultant accumulationof Mg-protoporphyrin IX. When sectors were incubated in darknesswith 2,2'-dipyridyl, large amounts of protoporphyrin IX accumulatedin the white sectors, whereas Mg-protoporphyrin IX mainly accumulatedin the green sectors. These results suggest that the enzymesfor the synthesis of porphyrin that catalyze conversion of ALAto protoporphyrin IX were very active and that the Mg-insertionstep might be blocked in the white sectors, with the resultantfailure to synthesize Chl. The deficiency is discussed in acomparison with that in other Chl-deficient plants. (Received November 15, 1995; Accepted March 21, 1996)     

Studies of pesticides effects on Chlorella metabolism II. Effect of DCMU on galactolipid metabolism

DCMU (N'-(3,4-dichlorophenyl)-N, N-dimethylurea) was testedfor effects on the metabolism of galactolipids in Chlorellaand chloroplasts isolated from higher plants. In Chlorella,DCMU affected galactolipid synthesis in the light more thanthat of other lipids, but it showed no effect on lipid synthesisin the dark. DCMU did not affect the turnover of galactolipidsin the light. In vitro studies using ¹⁴C-acetate or ¹⁴C-UDP-galactoseas a precursor showed that DCMU had no effect on the synthesisof gross lipid or galactolipids in chloroplasts isolated fromhigher plants. The significance of these observations are discussed. (Received September 21, 1974; )     

Physiological evaluation of temperature effect on the growth processes of the mysid, Neomysis intermedia Czerniawsky

Ingestion, respiration, and molting loss rates were measuredover the 3 – 29°C range in Neomysis intermedia. Weightspecific rates of these physiological processes ranged from2 to 140% body C day^–1 for ingestion, from 2 to 15% bodyC day^–1 for respiration, and from 0.1 to 5% body C day^–1for molting loss. All weight-specific rates showed a logarithmicdecrease with a logarithmic increase in body weight, and a logarithmicincrease with a linear increase in temperature below 20 or 25°C.The effect of temperature, however, was different between thephysiological rates, with a large temperature dependency foringestion (Q₁₀ = 2.6 –3.9) and molting loss (Q¹⁰ = 2.9– 3.6) and a moderate temperature dependency for respiration(Q₁₀ = 1.9 – 2.1). Calculated assimilation efficiencychanged with body size, but was constant over the temperaturerange examined. Allocation of assimilated materials varied witha change in temperature, reflecting the different temperaturedependence between physiological processes. It was deduced thatthe strong temperature dependency of the growth rate in N. intermediaobserved in the previous studies resulted from the large temperatureeffect on ingestion and assimilation rates, superimposed bythe different allocation of assimilated materials. ¹Present address: Department of Botany, University of Tokyo,Hongo, Tokyo 113, Japan     

Effects of Light on Degradation of Chlorophyll and Proteins during Senescence of Detached Rice Leaves

Regulatory effects of light on senescence of rice leaves wereinvestigated by measuring degradation of chlorophyll and proteinsin leaf segments which had been kept in the dark or under illuminationwith light of different intensities and colors. When leaveshad been left in total darkness for three days at 30°C,there was an initial long lag that lasted for one whole dayand then chlorophyll was rapidly degraded in the second andthird days. Breakdown of chlorophyll was strongly retarded bycontinuous illumination with white light of intensity as lowas 0.5 µmol photons m^–2 s^–1 but the effectof light decreased at intensities above 10 µmol photonsm^–2 s^–2. The initial lag and subsequent degradationof chlorophyll in the dark were little affected by illuminationwith red or far red light at the beginning of dark treatment.However, a brief illumination with red light at the end of thefirst and/or second day significantly suppressed degradationof chlorophyll during subsequent dark periods and the effectof red light was nullified by a short irradiation with far redlight. Thus, degradation of chlorophyll is regulated by phytochrome.Thylakoid membrane proteins and soluble proteins were also largelydegraded during three days in the dark. Degradation of membraneproteins such as the apoproteins of light-harvesting chlorophylla/b proteins of photosystem II and chlorophyll a-binding proteinsof reaction center complexes showed a long lag and was stronglysuppressed by illumination with weak white light. Thus, theloss of chlorophyll can be correlated with degradation of chlorophyll-carryingmembrane proteins. By contrast, light had only a weak protectingeffect on soluble proteins and ribulose-1,5-bisphosphate carboxylase/oxygenaserapidly disappeared under illumination with weak white light.Thus, breakdown of thylakoid membrane and soluble proteins aredifferently regulated by light. Artifacts which would be introducedby detachment of leaves were also discussed. ¹ Present address: Department of Applied Biology, Faculty ofScience and Technology, Science University of Tokyo, Yamazaki,Noda-shi, Chiba, 278 Japan. ² Present address: Department of Life Science, Faculty of Science,Himeji Institute of Technology, Harima Science Park City, Hyogo,678-12 Japan.     

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; )     

Studies on chlorophyll formation in Chlorella protothecoides I. Enhancing effects of light and added {delta}-aminoIevulinic acid, and suppressive effect of glucose on chlorophyll formation

Light-induced formation of chlorophyll in "etiolated" cellsof Chlorella protothecoides was studied under various experimentalconditions, (i) Two different types of enhancing effect of lightwere demonstrated: a "long-term" effect lasting for many hoursafter a relatively short illumination of etiolated cells anda "short-term" effect disappearing in a few hours after illumination,(ii) Addition of ALA caused enhancement of chlorophyll synthesisin etiolated cells in darkness as well as in light; the ALA-enhancedrate of dark chlorophyll synthesis, however, was much lowerthan the rate in light without added ALA. ALA was replaceablewith succinic acid plus glycine in light, but not in the dark,for enhancement of chlorophyll formation, (iii) Adding glucose,fructose, galactose, glycerol or acetate—at concentrationsmuch lower than those previously shown to induce "bleaching"of green algal cells-caused a more or less marked suppressionof light-induced greening in etiolated cells, (iv) Added glucosealmost instantaneously and completely stopped chlorophyll synthesisin light as well as in darkness either with or without addedALA. On the basis of these and other results, a tentative schemeis presented for the enhancing effects of light and the suppressiveeffects of glucose on chlorophyll formation in algal cells. (Received April 1, 1970; )     

Photoinhibition of 5-aminolevulinic acid formation under GO2-free condition

5-Aminolevulinate accumulation in the presence of levulinatewas followed in greening Chlorella protothecoides cells. Underthe CO₂-free condition, ALA formation was severely inhibitedby 20 W/m² white light. The inhibition was removed by CMU. Combinedaddition of CMU with N, N'-tetramethyl phenylenediamine plusascorbate again caused photoinhibition of ALA formation, whilethe addition of CMU with dithiothreitol caused severe inhibitionof ALA formation in both light and darkness. Exogenous glucose enhanced ALA formation in darkened algal celb,but not in photo- and DTT-inhibited cells. In either case, glucoseseemed to be metabolized mainly by the algal cells through theglycolysis-citric acid system. It was inferred that ALA formationwas suppressed at the site of, or related to, an enzyme reactionforming ALA. (Received June 27, 1979; )     

Studies on chloroplast development in Chlamydomonas reinhardtii I. Effect of brief illumination on chlorophyll synthesis

When dark grown cells of Chlamydomonas reinhardtii y-1 mutantwere exposed to continuous light, an immediate transformationof small amounts of protochlorophyll(ide), which had been presentin the dark grown cells, to chlorophyll was observed. Afterthis, there was a slow accumulation of chlorophyll lasting for2.5-3 hr before the start of exponential synthesis. Initialaccumulation of chlorophyll was distinctly slower at a highlight intensity (13,000 lux) than it was at moderate intensitiesof light (2,000–5,000 lux). However, the exponential synthesisof chlorophyll started after the same 2.5–3 hr of illumination. A brief pre-illumination of cells followed by incubation indarkness was effective in promoting chlorophyll synthesis undersubsequent continuous illumination at high, as well as moderatelight intensities. Pretreatment alleviated retardation of theinitial chlorophyll accumulation by light of high intensity.The promoting effect of preillumination on chlorophyll synthesiswas sufficient, even when a light impulse as short as 10 secwas given. However, the effect was dependent on length of thedark period after the short pre-illumination. The full extentof this effect was observed when the dark period was about 2.5–3hr long. Further dark incubation gradually decreased the effect. On the basis of these findings, it is assumed that a factor(s)responsible for promotion of chlorophyll (or chloroplast) synthesisin the process of greening of dark grown cells is produced duringthe dark period after a brief pre-illumination, and that thefactor is turned over at a relatively fast rate. The possiblenature of the presumed factor is discussed in relation to chloroplastdevelopment. ¹Present address: Department of Biology, Faculty of Science,Kobe University, Nada-ku, Kobe, Japan. (Received August 18, 1970; )     

Regulation of Synthesis of PSI in the Cyanophytes Synechocystis PCC6714 and Plectonema boryanum during the Acclimation of the Photosystem Stoichiometry to the Light Quality

The effects of light quality on the formation of the PSI complexwere examined in Synechocystis PCC6714 and in Plectonema boryanum.The rate of increase in levels of core polypeptides of PSI,PsaA/B, doubled upon shift from Chl a-absorbed light (PSI light)to phycobilisome-ab-sorbed light (PSII light). The elevatedrate was decreased upon the reverse shift. Half time of theacceleration was approximately 10 min, and that of the decreasewas approximately 4 min. The rate of degradation of the polypeptideswas far lower than the rate of the increase under either lightregime. Neither synthesis nor degradation of the PsbA and PsbCpolypeptides of PSII was significantly altered by the lightquality. We conclude that synthesis of the PSI complex is chromaticallyregulated to allow adjustments in photosystem stoichiometry.The level of mRNA for PsaA/B was not altered by the light regime.Anomalous inhibition by chloramphenicol suggested that the regulationoccurs at a step(s) other than the peptide elongation step,perhaps at the initiation of the ribosome cycle or at the insertionof Chl a for the stabilization of the polypeptides. The pho-toreductionof protochlorophyllide (Pchlide) was compared with the synthesisof the polypeptides in a mutant of Plectonema boryanum thatlacked Pchlide dark reductase (YFC1004). The results indicatedthat the synthesis of stable PsaA/B polypeptides was not limitedby the reduction of Pchlide, although the synthesis did dependon a supply of Chl a. ¹Present address: Department of Plant Biology, University ofMaryland at College Park, MD 20742, U.S.A. ²Present address: Department of Marine Bioscience, Fukui Pre-fecturalUniversity, Obama, Fukui, 917 Japan     

Comparison of Four Methods Calculating the Seasonal Pattern of Plant Growth Efficiency of a Kiwifruit Berry

Four methods of determining the substrate requirements for synthesisof a kiwifruit [Actinidia deliciosa (A. Chev.) C. F. Liang etA. R. Ferguson var. deliciosa cv. Hayward] berry were comparedusing data derived from common kiwifruit berry samples collectedfrom anthesis to fruit maturity. The four methods were basedon fruit proximal analysis, elemental analysis, heats of combustion,or tissue carbon content. All methods gave similar patternsof seasonal costs and values of final cost to the plant (mean1.21 g glucose g^–1 season^–1) but there was lessagreement for growth respiration (mean 0.147 g glucose g^–1season^–1). This is the first time that a continuous recordof growth cost over the course of development has been presented,and the trends in seasonal cost reflect the uptake into andsynthesis of the different biochemical constituents in the fruit.The differences between the results of each method reflect theunderlying assumptions used in their development. It appearsfrom this work that the method of McDermitt and Loomis (1981),utilizing elemental analyses, is most preferred. Actinidia deliciosa (A. Chev.) C. F. Liang et A. R. Ferguson var deliciosa cv Haywood, kiwifruit, true growth yield, plant growth efficiency, production value, glucose value, bioenergetic cost     

Influence of light intensity on diel variations in rates of growth, respiration and organic release of a marine diatom: comparison of diurnally constant and fluctuating light

Effects of variations in light intensity on diel patterns ofgrowth, respiration and organic release of Skeletonema costatum(Grev.) Cleve in a cyclostat were evaluated. Light intensitywas either constant during the tight period at levels from 1500to 15 µEm^–2 s^–1 or fluctuated throughout thelight period from 500 to 10 µEm^–2 s^–1 at ratesof either 1 or 12 cycles day^–1. Periodicity in cell divisionwas observed only at light intensities of 130 Em^–2 s^–1and was decreased under diurnally varying tight. Under all lightconditions carbon and pigment growth were maximal during thelight period but well coupled throughout the 24 h period. Carbonassimilation during the dark period varied from 19 to 34% oftotal daily production and was a linear function of growth rate.Respiratory activity during the light period increased relativeto total daily respiration as growth rate increased. The increasein night-time carbon assimilation with growth rate interactedwith night-time respiration through the refixation of respiredcarbon, thus, influencing the pattern of respiratory loss ofcarbon. Rates of organic release (E^c) were maximal during thelight period and did variations consistently increased withtight intensity. Fluctuating light increased E^c relative toconstant light. Net growth efficiency was maximal at 130 µEm^–2s^–1 when cell division periodicity was greatest. Underother light conditions relatively higher rates of cell divisionoccorred at night and cell division periodicity was reducedas well as net growth efficiency. Cellular chemical fractionationindicated that under high or variable light conditions fixedcarbon was stored during the tight period for subsequent synthesisof protein and pigments, and division at night. Such an uncouplingof photosynthesis and other growth parameters resulted in greatermetabolic costs to the cell. ¹Present address: Marine Biology, Lamont Doherty GeologicalObservatory, Palisades, NY 10964, USA     

Formation of protochlorophyll(ide) in wild type and mutant C-2A' cells of Scenedesmus obliquus

Protochlorophyll(ide) was isolated from dark-grown wild typeand mutant C-2A' cells of Scenedesmus obliquus after dark incubationwith 5-aminolevulinate. Proto-chlorophyll(ide) was detectedin mutant cells grown heterotrophically at 29°C or at 21°C.At the latter temperature chlorophyll synthesis was significant.Regulation of chlorophyll synthesis in algae is discussed. ¹Present address: Laboratory of Chemistry, Faculty of Medicine,Teikyo University, Otsuka, Hachioji, Tokyo 192-03, Japan. (Received July 14, 1980; )     

Photoconversion of protochlorophyll to chlorophyll a in a mutant of Chlorella regularis

Dark-grown cells of a mutant strain of Chlorella regularis containedchlorophyll a and protochlorophyll, phytyl ester of protochlorophyllide.Under illumination, protochlorophyll was quantitatively anddirectly converted into chlorophyll a. The photoconversion wasdependent on light intensity and temperature and proceeded ina cell-free preparation. The pathway of chlorophyll formation found in the mutant cellsis entirely different from that from protochlorophyllide byway of chlorophyllide a, which is generally observed in greenplants. ¹Present address: Division of Biology, Medical College of Miyazaki,Miyazaki 889-16, Japan. ²Present address: Division of Environmental Biology, The NationalInstitute for Environmental Studies, Ibaragi 300-21, Japan. (Received October 24, 1975; )