Inhibitory Effect of Gabaculine on the Biosynthesis of 5-Aminolevulinate in the Tigrina d12 Mutant of Barley

Six-day-old, dark-grown, seedlings of barley homozygous forthe recessive mutation tigrina d¹² accumulated 5-aminolevulinicacid (ALA) and protochlorophyll (ide) in amounts exceeding thewild type level. Transferring the etiolated mutant to lightresulted in the destruction of pigments and the deteriorationof the ALA forming system. Such deleterious effects did notoccurusing light-grown mutant or etiolated and greened wildtype seedlings. Gabaculine (GAB) at 50 µM inhibited ALAsynthesis by about 85% when etiolated wild type seedlings wereexposed to light. In light-grown leaves of either wild typeor mutant strain, ALA production was also sharply (ca. 75%)inhibited by GAB. During dark incubation, however, the inhibitionof ALA accumulation did not exceed 50% in all types of tissues.The results give further evidence for the operation of the C₅pathway in such seedlings since GAB decreased the biosynthesisof ALA to the same extent in both tigrina d¹² mutant and wildtype of barley. (Received July 2, 1990; Accepted May 7, 1991)     

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; )     

The development of structure and function in chloroplasts of greening mutants of Scenedesmus III. Biosynthesis of {delta}-aminolevulinic acid

Cells of the mutant C-2A' of Scenedesmus obliquus which requirelight for chlorophyll formation were assayed for in vivo activityof ALA synthesis. In general, ALA and chlorophyll syntheseswere coupled during the greening process. The action spectrafor ALA and chlorophyll syntheses both show the highest activitiesin the blue region, but were different in details. Under certainconditions, ALA synthesis occurred without a corresponding synthesisof chlorophyll. Reasons for these variances were discussed. The controlling action of light on ALA synthesis may occur throughthree different, but related, mechanisms. The principle mechanismappeared to be linked to lightenhanced respiration since itsinhibition by cycloheximide blocks ALA synthesis. The Hill coefficientof this inhibition is 2. After the light-induced enhancementof respiration had ceased, the Hill-coefficient of inhibitionof ALA synthesis became 1. Thus, in addition to enhanced respiration,ALA formation depends on its sensitizing enzyme having a half-lifetime of less than 1 hr. Finally, the dependence of the synthesisof ALA precursors on light was evident. ¹ On leave from the Institute of Applied Microbiology, Universityof Tokyo, Tokyo, Japan. (Received November 11, 1974; )     

Studies on nucleic acids in plastids of the pigment mutant C-2A{acute} of Scenedesmus obliquus

Pigment mutant C-2A{acute} of Scenedesmus obliquus whose chlorophyllformation and chloroplast development are light dependent, wasstudied for the nucleic acid content of its plastids. The ribosomalRNA of plastids of the achlorophyllous or greened mutant C-2A{acute},did not show any difference from that of the wild type. Incorporationof [5-³H] uridine into mutant cells was partially inhibitedby rifampicin, indicating this part as being plastidial incorporation.Since there were no significant differences in the ribosomalRNA of plastids between the mutant and the wild type of Scenedesmus,the ribosomal system in the plastids of mutant C-2A' seemednot to be affected by the mutation. C_sCl gradient patterns ofScenedesmus mutant and wild-type DNA were almost identical withthose of Chlorella DNA. A peak at a buoyant density of 1.69g/cm³, the same as that of Chlorella chloroplast DNA, couldbe identified in Scenedesmus also as plastid DNA because itdisappeared after prolonged treatment with myxin and hybridizedwith rifampicin-sensitive pulse-labelled RNA. This peak waspresent to nearly the same degree in the mutant and the wildtype, indicating that a larger deficit of plastid DNA did notoccur in the mutant. Whether or not the mutation might be localizedin the plastid genome is discussed. (Received March 19, 1976; )     

Apical Growth of Protonemata in Adiantum capillus-veneris IV. Phytochrome-Mediated Induction in Non-Growing Cells

In non-growing two-celled protonemata of Adiantum capillus-veneris,apical growth was induced most effectively by red light irradiation;half of the samples were induced to grow by 660 nm light ofca. 1.5 J m^–2 and the maximum number by ca. 70 J m^–2.The reciprocity law was valid in this photoinduction. The growthresumption became detectable 6 hr after the light irradiationand reached a plateau within 24 hr irrespective of given fluences.When non-growing samples were irradiated with red light of 4.6W m^–2 for 4 sec or shorter, the effect was fully reversedby a subsequent irradiation with far-red light to the far-redlight control level. But, when the red light was given for 16sec or longer, photoreversibility became partial. An interveningdark period of 2 min between red and far-red light did not significantlyinfluence the photoreversibility so that the escape reactionin the dark may not be attributed to the above-mentioned lossof photoreversibility. By means of a local irradiation with a narrow red light beam(10 µm in width), the apical cell was found to be photosensitivefor the growth induction, but basal cell was not. Photoreceptivesite was not localized in any particular region of the apicalcell, but was rather dispersed in the entire apical cell. (Received January 26, 1981; Accepted March 10, 1981)     

Effects of Light on Chlorophyll Formation in Cultured Tobacco Cells I. Chlorophyll Accumulation and Phototransformation of Protochlorophyll(ide) in Callus Cells under Blue and Red light

A marked accumulation of chlorophyll was observed in calluscells of Nicotiana glutinosa when they were grown under bluelight, while under strong red light no chlorophyll accumulated.This blue light effect saturated at an intensity of about 500mW.m^–2. The effects of white, blue and red light on the transformationof protochlorophyll (ide) (Pchl) accumulated in dark-grown calluscells were studied by following the changes in the intensityof fluorescence emitted by Pchl and different forms of chlorophyll(ide) (Chi). Pchl with a fluorescence maximum at 633 nm (absorptionmaximum: 630 nm) decreased slowly, concomitant with an increasein Chl having a fluorescence maximum at 677 nm (absorption maximum:675 nm), which was subsequently transformed, independently oflight, to Chi with a fluorescence maximum at 683 nm (absorptionmaximum: 680 nm). Both blue and red light of low intensitieswere effective for the phototransformation, while red light,but not blue light, of high intensities caused significant destructionof Pchl. An action spectrum for this photodestruction showedthat the maximum destruction took place at 630 nm. White lightof high intensities was effective for the photoreduction withonly slight destruction of Pchl, suggesting that blue lightcounteracts the destructive effect of red light. At low temperatures,however, blue light as well as red light of low intensitiescaused photodestruction of Pchl. It was inferred that blue lightenhances a certain step or steps involved in the productionof a reductant required for the photoreduction of Pchl to Chl. (Received July 3, 1981; Accepted November 11, 1981)     

Induction of delta-Aminolevulinic Acid Formation in Etiolated Maize Leaves Controlled by Two Light Systems

A short illumination of etiolated maize (Zea mays) leaves with red light causes a protochlorophyll(ide)-chlorophyll(ide) conversion and induces the synthesis of δ-aminolevulinic acid (ALA) during a subsequent dark period. In leaves treated with levulinic acid, more ALA is formed in the dark than in control leaves. Far red light does not cause a conversion of protochlorophyll(ide) into chlorophyll(ide) and does not induce accumulation of ALA in the dark. Both red and far red preilluminations cause a significant potentiation of ALA synthesis during a period of white light subsequent to the dark period. The results indicate a dual light control of ALA formation. The possible role of phytochrome and protochlorophyllide as photoreceptors in this control system is discussed.     

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; )     

Effects of Light on Chlorophyll Formation in Cultured Tobacco Cells II. Blue Light Effect on 5-Aminolevulinic Acid Formation

5-Aminolevulinic acid (ALA) accumulation in dark-grown tobaccocallus cells in the presence of levulinic acid (LA) was followedunder blue or red light or in continuous darkness. Significantformation of ALA continued in the dark. The protochlorophyll-(ide) (Pchl) content of dark-incubated cells remained low becauseof its turnover. We inferred that the feedback inhibition ofALA synthesis by Pchl would not occur in darkincubated calluscells. ALA formation was enhanced by blue light, and this effectreached saturation at an intensity of about 800 mW.m^–2.Neither weak nor strong red light affected ALA formation. Fullenhancement of ALA formation by blue light was attained afterfairly long continuous illumination of the callus cells. Thisblue lightenhanced activity of ALA synthesis declined very slowlyduring the subsequent dark incubation. The blue light enhancement of ALA formation was observed incallus cells supplied with sucrose over a wide range of concentrations.Pchl regeneration in carbon-starved callus cells, supplied withglutamate at various concentrations, was also markedly enhancedby blue light. Respiration of the callus cells was not enhancedby blue light. A possible role of blue light in regulating ALAformation in callus cells is discussed. ¹Dedicated to the late Professor Joji Ashida. (Received September 3, 1982; Accepted April 5, 1983)     

A Plasma Membrane Mutation acrA in Escherichia coli

Protein analysis and electron microscopic observation of thefreeze-fractured plane of the plasma membrane were performedwith an acriflavine-sensitive mutant carrying mutation acrA(at min 10) and with the wild type (acrA⁺) strain of Escherichiacoli K-12. The acrA mutant membrane was deficient (or much lower)in one protein when analyzed by the polyacrylamide gel electrophoresistechnique. (Received May 7, 1981; Accepted July 28, 1981)     

Cloning of the Gene Encoding a Protochlorophyllide Reductase: the Physiological Significance of the Co-Existence of Light-Dependent and -Independent Protochlorophyllide Reduction Systems in the Cyanobacterium Plectonema boryanum

Cyanobacteria have two protochlorophyllide (Pchlide) reductasescatalyzing the conversion of Pchlide to chloro-phyllide, a keystep in the biosynthetic pathway of chlorophylls (Chls); a light-dependent(LPOR) and a light-independent (DPOR) reductase. We found anopen reading frame (ORF322) in a 2,131-bp EcoRI fragment fromthe genomic DNA of the cyanobacterium Plectonema boryanum. Becausethe deduced amino acid sequence showed a high similarity tothose of various plant LPORs and the LPOR activity was detectedin the soluble fraction of Esche-richia coli cells over-expressingthe ORF322 protein, ORF322 was defined as the por gene encodingLPOR in P. boryanum. A por-disrupted mutant, YFP12, was isolatedby targeted mutagenesiss to investigate the physiological importanceof LPOR. YFP12 grew as well as wild type under low light conditions(10-25 µE m^–2 S^–1). However, its growth wassignificantly retarded as a result of a significant decreasein its Chl content under higher light conditions (85-130 µEm^–2 s^–1). Furthermore, YFP12 stopped growing andsuffered from photobleaching under the highest light intensity(170 µE m^–2 s^–1). In contrast, a chlL-dis-rupted(DPOR-less) mutant YFC2 grew as well as wild type irrespectiveof light intensity. From these phenotypic characteristics, weconcluded that, although both LPOR and DPOR contribute to Chlsynthesis in the cells growing in the light, the extent of thecontribution by LPOR increases with increasing light intensity;without it, the cells are unable to grow under light intensitiesof more than 130 µ Em^–2s-^–. (Received September 26, 1997; Accepted November 21, 1997)     

Changes in Levels of Heme a, Protoheme and Protochlorophyll(ide) in Submerged Rice Seedlings after Exposure to Air

Rice (Oryza sativa L. cv. Yamabiko) seedlings germinated underwater for 5 days contained small amounts of heme a and protohemebut no protochlorophyll(ide) [Pchl(ide)]. Levels of hemes andPchl(ide) increased rapidly upon transfer to air. When expressedin terms of fresh weight of tissue, hemes reached the levelsin aerobic controls after 24 h of contact with air, but Pchl(ide)did not. A comparison of the increases during 24-h adaptationto air in levels of heme a and Pchl(ide), which are specificto mitochondria and plastids, respectively, suggested that thedevelopment of mitochondria preceded that of plastids. The rateof synthesis of 5-aminolevulinic acid (ALA) was low in submergedseedlings, as compared to the rate in aerobic controls, butit increased during air adaptation. The sum of the amounts ofheme a, protoheme and Pchl(ide) increased in parallel with theamount of porphyrins, equivalent to the amount of ALA synthesizedduring the experimental period. When submerged seedlings thathad been pretreated with levulinic acid were exposed to air,no Pchl(ide) was formed. In contrast, Pchl(ide) accumulatedunder water when submerged seedlings were fed with ALA. Theseresults indicate that the synthesis of ALA, the limiting stepin the synthesis of Pchl(ide), is repressed under hypoxic conditions. ¹ Present address: KRI International, Inc., Kyoto Research Park17, Chudoji Minami-machi, Shimogyo-ku, Kyoto, 600 Japan. ² Present address: Research Institute for Bioresources, OkayamaUniversity, Kurashiki, 710 Japan.     

Carbonic Anhydrase in Chlamydomonas reinhardtii II. Requirements for Carbonic Anhydrase Induction

Carbonic anhydrase (CA) activity in wild type cells of Chlamydomonasreinhardtii was low when cells were cultured under 2% CO₃ inthe light. When the gas phase was changed to air, CA activityincresaed as much as 20 fold over the next 24 hours. In contrast,CA activity did not change markedly in cells of the mutantspet 20-8 (PS II-negative), lip 10-2 (photophosphorylation-negative),and F60 (phosphoribulokinase-negative), when they were subjectedto the same induction regimen. DCMU (10^–5 M) and cydoheximide(3 µg/ml) severely inhibited the induction in wild typecells. No induction occured when CO₂ concentration was loweredin darkness. ³Present adress: Photoconversion Research Branch, Solar EnergyResearch Institute, Golden, Colorado 80401, USA. (Received June 7, 1982; Accepted December 25, 1982)     

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; )     

Calcium-calmodulin signalling is involved in light-induced acidification by epidermal leaf cells of pea, Pisum sativum L.

Pathways of signal transduction of red and blue light-dependentacidification by leaf epidermal cells were studied using epidermalstrips of the Argenteum mutant of Pisum sativum. In these preparationsthe contribution of guard cells to the acidification is minimal.The hydroxypyridine nifedipine, a Ca²⁺-channel blocker, partlyinhibited the response to both blue and red light, while thephenylalkylamine, verapamil, a Ca²⁺-channel blocker that hasbeen shown in plant cells also to block K⁺-channels, causednearly complete inhibition. The Ca²⁺-channel activator S(–)BayK 8644 induced acidification when added in the dark and diminishedthe light-induced lowering of the extracellular pH. The Ca²⁺-ionophores,ionomycin and A23187 [GenBank] , also reduced the light response. Furthermore,the light-induced acidification was inhibited by the calmodulinantagonists W-7 and trifluoperazine, but not by W-5. These calmodulininhibitors completely inhibited the red light-induced acidification,but inhibited the response to blue light by only 60–70%.In general, inhibition by compounds affecting Ca-calmodulinsignalling was always stronger on the red light response thanthat on the blue light response (with the exception of verapamilthat blocked both the red and blue light responses equally well).This differential effect on red and blue light-induced responsesindicates a role for Ca²⁺-CaM signalling in both the red andblue light responses, while a second process, independent ofCa²⁺ is activated by blue light. Key words: Signal transduction, light-induced acidification, epidermal cells, pea     

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; )     

Effects of Light Quality on Formation of 5-Aminolevulinic Acid, Phycoerythrin and Chlorophyll in Cryptomonas sp. Cells Collected from the Subsurface Chlorophyll Layer

Phycoerythrin obtained from the cells of Cryptomonas sp. (Cryptophyceae)which had been isolated from the subsurface chlorophyll layerin the western Pacific Ocean showed peaks in absorption andfluorescence spectra at 545 and 586 nm, respectively. The rateof photosynthetic O₂ evolution under green light was higherthan those under blue and red light. The rate of 5-aminolevulinic acid (ALA) accumulation in thepresence of levulinic acid was higher under green light thanunder blue and red light. The effects of light quality on therates of O₂ evolution and ALA formation closely resembled eachother. On the other hand, the formation of phycoerythrin andALA was suppressed during growth under blue light. Possible effects of light quality on the formation of photosyntheticpigments in Cryptomonas sp. were discussed. (Received January 31, 1984; Accepted May 14, 1984)     

Photoinhibition and light-induced cyclic electron transport in ndhB(-) and psaE(-) mutants of Synechocystis sp. PCC 6803

The ndhB^– and psaE^– mutants of the cyanobacteriumSynechocystis sp. PCC 6803 are partly deficient in PSI-drivencyclic electron transport. We compared photoinhibition in thesemutants to the wild type to test the hypothesis that PSI cyclicelectron transport protects against photoinhibition. Photoinhibitorytreatment greatly accelerated PSI cyclic electron transportin the wild type and also in both the mutants. The psaE^–mutant showed rates of PSI cyclic electron transport similarto the wild type under all conditions tested. The ndhB^–mutant showed much lower rates of PSI cyclic electron transportthan the wild type following brief dark adaptation but exceededwild type rates after exposure to photoinhibitory light. Thewild type and both mutants showed similar rates of photoinhibitiondamage and photoinhibition repair at PSII. Photoinhibition atPSI was much slower than at PSII and was also similar betweenthe wild type and both mutants, despite the known instabilityof PSI in the psaE^– mutant. We conclude that photoinhibitorylight induces sufficient PSI-driven cyclic electron transportin both the ndhB^– and psaE^– mutants to fulfill anyrole that cyclic electron transport plays in protection againstphotoinhibition. ⁴ Corresponding author: E-mail, sherbert@uwyo.edu; Fax, +1-307-766-2851;Phone, +1-307-766-4353.     

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; )