Events Surrounding the Early Development of Euglena Chloroplasts: I. Induction by Preillumination 1

Preillumination, followed by a dark period prior to exposure of dark-grown nondividing cells of Euglena gracilis var. bacillaris to normal lighting conditions for chloroplast development, results in potentiation, or abolishment of the usual lag in chlorophyll accumulation. The degree of potentiation is a function of the length of the preillumination period, the intensity of preilluminating light, and the length of the dark period interposed before re-exposure to continuous light for development. The optimal conditions are found to be: 90 minutes of preillumination with white light at an intensity greater than 30 microwatts per square centimeter (14 foot candles) followed by a dark period of at least 12 hours. Reciprocity is not found between duration and intensity of preilluminating light. Preillumination with blue light and red light was found to be the most effective in promoting potentiation, and the ratio of effectiveness of blue to green to red is consistent with protochlorophyll-(ide) being the photoreceptor. Although red light is effective, there is no reversal by far red light, and these facts, taken together with the effectiveness of blue light, suggest that the phytochrome system is not involved. The amount of chlorophyll formed at the end of preillumination is proportional to the resulting potentiation, suggesting that the amount of protochlorophyll(ide) removed or chlorophyll(ide) formed regulates this phenomenon. Potentiated and nonpotentiated cells show comparable rates of protochlorophyll(ide) resynthesis, suggesting that this is not the limiting factor in nonpotentiated cells. Although light is required for protochlorophyll(ide) conversion in chlorophyll synthesis, a brief preillumination seems also to initiate the production of components in the subsequent dark period which, in nonpotentiated cells, are ordinarily synthesized during the lag period under continuous illumination. These components are necessary to sustain maximal rates of subsequent chlorophyll accumulation.     

Events Surrounding the Early Development of Euglena Chloroplasts: VI. Action Spectra for the Formation of Chlorophyll, Lag Elimination in Chlorophyll Synthesis, and Appearance of TPN-dependent Triose Phosphate Dehydrogenase and Alkaline DNase Activities

Action spectra derived from dose-response curves measured for various processes associated with chloroplast development in Euglena gracilis var. bacillaris are presented. The action spectrum for chlorophyll synthesis during the first 36 hours of continuous illumination of dark-grown resting cells resembles the absorption spectrum of protochlorophyll(ide). The action spectrum for the preillumination phase of potentiation, during which preillumination followed by a dark period brings about lag elimination in chlorophyll synthesis when the cells are subsequently exposed to postilluminating light, shows a high peak in the blue region (at about 433 nm) with a small peak in the yellow-orange region (at about 597 nm); the postillumination phase yields an action spectrum very similar to that obtained for chlorophyll synthesis in continuous light in normal, unpotentiated cells, with peaks at 433 and 631 nm. Alkaline DNase and TPN-linked triose phosphate dehydrogenase, two plastid enzymes which are synthesized outside the chloroplast, yield action spectra which are consistent with protochlorophyll(ide) being the major light receptor. The action spectra which implicate pigments resembling protochlorophyll(ide) holochrome have blue to red peak ratios in the vicinity of 5:1 as does the absorption spectrum of the protochlorophyllide holochrome from beans; the action spectrum is not identical with the holochrome spectrum indicating that the Euglena holochrome may differ from the bean pigment in details of its absorption spectrum. The action spectrum for preillumination, shows a ratio of the blue peak to the red effectiveness of about 24:1. This suggests that preillumination is controlled by a photoreceptor different from the protochlorophyll(ide) holochrome.     

Control of delta-Aminolevulinic Acid and Chlorophyll Accumulation in Greening Maize Leaves upon Light-Dark Transitions

The accumulation of δ-aminolevulinic acid (ALA) was studied in greening maize (Zea mays) leaves which were transferred to darkness and reilluminated after various periods of time. The system synthesizing ALA decays in the dark with a half-life of about 80 minutes. The onset of enzyme decay after transfer to darkness shows a 40-minute lag. The accumulation of ALA in the presence of levulinic acid in leaves transferred to darkness corresponds to that expected from the estimated half-life of the enzyme synthesizing ALA. On the other hand, the accumulation of protochlorophyll upon transfer to darkness in the absence of levulinic acid stops much earlier. It is suggested that a control point exists in the pathway between ALA and protochlorophyll, preventing utilization of the accumulated ALA upon transfer of greening leaves to darkness. This is supported by the observed effects of low intensities of monochromatic light (648 nm) on ALA and chlorophyll accumulation.     

Studies on chloroplast development in Chlamydomonas reinhardtii IV. Control of rapid chlorophyll formation in greening y-1 cells

Effects of protein synthesis inhibitors, CAP and CHI, on diegreening of Chlamydomonas reinhardtii y-1 cells, particularlyon die P-factor formation (19) in the early phase, were studied.Chlorophyll synthesis in the normal greening process, whichis divided into three phases, was strongly inhibited by bothantibiotics, although the inhibition by CAP was weaker in themiddle and late phases. The development of potential for rapidchlorophyll formation (P-factor formation) that takes placein dark-grown cells during dark incubation following brief illuminationwas completely blocked by CHI, but not by CAP. A "CHI-sensitive"period for the P-factor formation was restricted to the initial30 min during the dark incubation following brief illumination(10 min). This initial 30-min period appeared to correspondto the time of protochlorophyll(ide) formation which was inhibitedby CHI. Light-dependent conversion of protochlorophyll(ide) to chlorophylland also the subsequent protochlorophyll(ide) synthesis, whichis "CHI-sensitive" seem to be prerequisite for the inductionof P-factor synthesis. A possible control mechanism involvedin the early phase of the greening process in y-1 cells is discussed. (Received February 12, 1976; )     

Oak seedlings grown in different light qualities

Oak seedlings (Quercus robur L.) were germinated in darkness for 3 weeks and then given continuous long wavelength far-red light (LFR; wavelengths longer than 700 nm). A control group of seedlings was kept in darkness. After 2 additional weeks the chlorophyll formation ability in red light was examined in the different seedlings. The stability of the protochlorophyll(ide) and chlorophyll(ide) forms to high intensity red irradiation was also measured. Oak seedlings grown in darkness accumulated protochlorophyll(ide) (6 μg per g fresh matter). Absorption spectra and fluorescence spectra indicated the presence of more protochlorophyll(ide)_628–632 than protochlorophyllide_650–657. The level of protochlorophyll(ide) was higher in leaves of plants cultivated in LFR light (13 μg per g fresh matter) than in leaves of dark grown plants. 12% of the protochlorophyll(ide) was esterified in both cases. The level of protochlorophyll(ide)_628–632 in LFR grown oaks varied with the age of the leaves, being higher in the older (basal) leaves, but also in the very youngest (top-most) leaves. The ability of the leaves to form photostable chlorophyll in red light showed a similar age dependence, being low in rather young and in older leaves. A low ability to form photostable chlorophyll thus appears to be correlated with a high content of protochlorophyll(ide)_628–632. Upon irradiation only the protochlorophyllide_650–657 was transformed to chlorophyllide. After this phototransformation the chlorophyllide peak at 684 nm shifted to 671 nm within about 30 min in darkness. This shift took place without any accompanying change in photostability of the chlorophyll(ide). Upon irradiation with strong red light a similar shift took place within one minute. This indicates that the chlorophyllide after phototransformation was rather loosely bound to the photoreducing enzyme. The development towards photostable chlorophyll forms consists of three phases and is discussed.     

The effect of haem on chlorophyll synthesis in barley leaves

Exogenously supplied bovine haemin, fed to etiolated barley leaves, inhibited chlorophyll synthesis in leaves exposed to light. Haemin inhibited the regeneration of protochlorophyllide (P650) and the conversion of exogenously supplied δ-aminolaevulinate (ALA) to protochlorophyll (P630). The effect of haemin on chlorophyll production was overcome by incubating the leaves in water in the dark before light treatment, suggesting the operation of a rapid haem destruction mechanism in leaves. Protohaem turnover in dark-grown leaves was between 8 and 9 hr, based on the rate of degradation of erogenous haemin and the rate of protohaem breakdown in laevulinic acid (LA) treated leaves. The rate constant for haem destruction was 85 pmol/nmol/hr in the dark and 45 pmol/nmol/hr after 4 hr light. There was no evidence that light affects the synthesis of protohaem. It appears that the regulation of endogenous levels of protohaem is by breakdown and it is this mechanism which is under light control. Haem considerably decreased the incorporation of radioactivity from glycollate-[¹⁴C], glycine-[¹⁴C] and glutamate-[¹⁴C] into accumulated ALA in the presence of LA.     

Correlation between 5-aminolaevulinate accumulation and protochlorophyll photoconversion

A 1-min light pulse delivered to mustard seedlings (Sinapis alba L.) 60 h after sowing initiates the release of cotyledonary 5-aminolaevulinate (ALA) accumulation which continues for at least 2 h in the dark. Phytochrome (P _fr) increases the rate of ALA accumulation after a 24-h red light pretreatment but is not the trigger for this release. It is shown that the rate of ALA accumulation varies with the wave-length and fluence rate of the 1-min light pulse and can be predicted from the degree of protochlorophyll-(ide) photoconversion. There is a linear correlation between the rate of ALA accumulation and the degree of protochlorophyll(ide) (PChl)chlorophyll(ide) a (Chl a) photoconversion in etiolated seedlings. In seedlings pretreated with red light this correlation is non-linear and the rate increases more rapidly with increasing degrees of PChlChl a photoconversion. It is suggested that there may exist an interaction between P _fr and PChlChl a photoconversion in controlling ALA accumulation.Abbreviations ALA 5-aminolaevulinate - Chl chlorophyll(ide) - PChl protochlorophyll(ide) - cp cotyledon pair - LA laevulinate     

Biosynthetic events required for lag elimination in chlorophyll synthesis in Euglena

Summary Levulinic acid, a competitive inhibitor of aminolevulinic acid dehydratase, cycloheximide, an inhibitor of translation on 89s cytoplasmic ribosomes, and chloramphenicol, an inhibitor of translation on 68s chloroplast ribosomes, are reversible inhibitors of light induced chlorophyll synthesis in resting Euglena gracilis Klebs. When dark grown resting cells are preilluminated for 2 h followed by darkness for 12 h prior to exposure to continuous light, the usual lag period in chlorophyll formation is eliminated. If cycloheximide, chloramphenicol, or levulinic acid are present during either the preillumination period or the subsequent dark period, the lag is reestablished. Only the very beginning of the dark period is sensitive to cycloheximide but the dark period is less sensitive to levulinic acid than is the light period. Exposure of preilluminated cells to cycloheximide or levulinic acid at the time of exposure to continuous illumination completely inhibits chlorophyll synthesis indicating that the potential for rapid chlorophyll synthesis generated by preillumination and a dark period does not result simply from the accumulation of porphyrin precursors. Preillumination has little effect on the development of the capacity to fix CO₂ photosynthetically. These results indicate that the control of chlorophyll formation is more complex than in higher plants and a model based on the formation of certain crucial enzymes in the porphyrin pathway, rather than simply upon the accumulation of aminolevulinic acid is presented to explain the experimental findings.Abbreviations ALA delta amino levulinic acid - CAM chloramphenicol - CEX cycloheximide - chl (ide) chlorophyll (ide) - LEV levulinic acid - pchl (ide) protochlorophyll (ide) Supported by GM14595 from the National Institutes of Health. This paper is No. 9 in the series, Events Surrounding the Early Development of Euglena ChloroplastsMicrobiology Trainee of the National Institutes of Health, Grant No. GM1586. The material in this paper is part of a dissertation submitted by S.D.S. to the Graduate Faculty of Brandeis University in partial fulfillment of the requirements for the Ph.D. Degree.     

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)     

Involvement of photobleaching and inhibition of protochlorophyll(ide) accumulation in tentoxin effects on greening of mung bean seedlings

Several types of evidence indicate that tentoxin-caused reduction of chlorophyll accumulation in greening primary leaves of mung bean [ Vigna radiata (L.) Wilczek cv. Berken] is due to both photobleaching and decreased protochlorophyll(ide) synthesis. Greening was greater under dim (2.5 μmol m_-2 s_-1) far-red or white light than under bright (180 to 200 μmol m_-2 s_-1) white light in tentoxin-treated tissues, whereas there was a positive correlation between fluence rate and greening in control tissues. Under continuous white light (100 μmol m_-2 s_-1) chorophyll(ide) accumulation was slower in tentoxin-treated than in control tissues. This was caused by greater photobleaching of newly formed chlorophyll(ide), as well as by decreased protochlorophyll(ide) synthesis. Photobleaching did not affect protochlorophyll(ide) synthesis in control or tentoxin-treated tissues. Chlorophyll(ide) was less stable in tentoxin-treated than in control tissues during a 24 h period of darkness. Plastids of tentoxin-treated tissues had all of the chlorophyll-proteins of control plants. Etioplasts of tentoxin-treated plants contained normal galactolipid contents, but galactolipids in these plants were greatly reduced in white light. Reduced chlorophyll accumulation caused by tentoxin is apparently the result of both photodestruction and of reduced synthesis of chlorophyll.     

Effect of Daylength on Phenol Metabolism in the Leaves of Salvia occidentalis

A method of phenol determination in plant leaves has been developed which is based on the in situ oxidation of these compounds in an atmosphere containing ammonia, followed by difference spectrophotometry. The development of the phenol pattern has been studied in each separate leaf of a Salvia occidentalis plant grown in short and in long days. During the light period the phenol content (mainly chlorogenic acid and isochlorogenic acids) increases in proportion to the length of this period, whereas during the subsequent dark period the phenol content decreases. This decrease does not continue during the second part of a dark period if that period is interrupted by a light break with red light. Instead a small increase is observed. This effect of red light can be reversed with far red light. It is argued that a correlation with flower induction in this short day plant can be construed if it is assumed that the continuous presence of certain o-dihydroxyphenols in the cytoplasm of leaf cells inhibits the synthesis or the transport of a flowering hormone.     

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)     

Kinetics and quantum yield of photoconversion of protochlorophyll(ide) to chlorophyll(ide) a

The kinetics of photoconversion of protochlorophyll(ide) to chlorophyll(ide) a were investigated in dark-grown barley leaves and in a preparation of protochlorophyll holochrome subunits. In the subunits the conversion obeyed first-order kinetics. This indicates that the excitation of protochlorophyll(ide), energy loss through deexcitation, and the reduction of excited protochlorophyll(ide) are all reactions that follow first-order kinetics with respect to protochlorophyll(ide) in protochlorophyll holochrome subunits.In contrast, photoconversion in leaves obeyed neither first- nor second-order kinetics. This prompted the postulation of an additional route within macromolecular units of protochlorophyll holochrome, whereby energy is lost from excited protochlorophyll(ide) by a reaction that is not first order. Such a process might be energy transfer from excited protochlorophyll(ide) to newly-formed chlorophyll(ide) a.A dynamic model describing photoconversion in macromolecular units was derived. The model is consistent with the observed progress of photoconversion in barley leaves and in protochlorophyll holochrome subunits from barley.Determinations of the quantum yield of photoconversion in protochlorophyll holochrome subunits gave values of 0.4–0.5 molecules · quantum^?1. Estimates of the initial quantum yield of the photoconversion process in leaves fell into the same range. The dynamic model allows predictions on the progressively decreasing quantum yield as the photoconversion proceeds in macromolecular units.     

A Reversible Conversion of Phototransformable Protochlorophyll(ide)(656) to Photoinactive Protochlorophyll(ide)(656) by Hydrogen Sulfide in Etiolated Bean Leaves

The relationship of phototransformable protochlorophyll-(ide) to photoinactive protochlorophyll(ide) has been studied in the primary leaves of 7- to 9-day-old dark-grown bean (Phaseolus vulgaris L. var. Red Kidney) seedlings. Subjecting the leaves to an atmosphere of H₂S causes an immediate loss of phototransformable protochlorophyll(ide)₆₅₀ and a simultaneous increase in photoinactive protochlorophyll(ide)₆₃₃. When such leaves are returned to air or N₂, the absorbance at 650 nm increases, whereas the absorbance at 633 nm decreases and photoactivity is restored. The reversion of protochlorophyll-(ide)₆₃₃ to protochlorophyll(ide)₆₅₀ is one-half complete in 3 minutes at 22 C in 8-day-old leaves. Ninety-five per cent recovery of protochlorophyll(ide)₆₅₀ is obtained when exposure to H₂S is less than 3 minutes in duration; longer periods reduce the reversion capacity proportionately. The leaves are relatively undamaged by brief exposures to H₂S, as judged by electron microscopy and by their ability to synthesize chlorophyll under continuous illumination. Hydrogen sulfide has no immediate effect upon the absorption properties of a partially purified preparation of the protochlorophyll(ide) holochrome, an etioplast suspension, or leaves subjected to freezing and thawing. Compounds such as HCN and HN₃ cause an irreversible conversion of protochlorophyll(ide)₆₅₀ to protochlorophyll(ide)₆₃₃ with total loss of photoactivity. Sulfhydryl agents, such as β-mercaptoethanol and cysteine, cause a slow, irreversible transformation of the photoactive pigment to the photoinactive form and inhibit the ability of the leaves to synthesize chlorophyll under continuous illumination. The results obtained suggest that H₂S may alter the interaction between the source of hydrogens on the protein moiety of the holochrome and the chromophore in vivo by reducing a disulfide bond in the protein, thereby causing a reversible conformational change in the complex.     

Effect of 2,2′-bipyridyl on porphyrin synthesis in etiolated and light-treated barley leaves

The effects of 2,2′-bipyridyl on porphyrin formation differed in illuminated and dark-treated barley leaves. In the dark, bipyridyl treatment increased photoconvertible protochlorophyllide (Pchlide, P650) and decreased the protohaem content. The increase in Pchlide could not be wholly accounted for by a diversion of ‘substrate’ from protohaem synthesis. The rate of Pchlide regeneration was slightly higher in chelator treated leaves which suggests increased δ-aminolaevulinic acid (ALA) synthesis. Only small quantities of Mg-protoporphyrinmonomethylester (Mg-protoME) were detected in etiolated leaves treated with bipyridyl in the dark. Protochlorophyll (P630) synthesis from exogenously supplied ALA was lower in the chelator treatments. The results suggest that only when substantial quantities of ALA are being utilized in dark-grown leaves does a ‘metal’ become limiting in the bipyridyl treated leaves. In the light, bipyridyl inhibited chlorophyll synthesis, again suggesting that when substantial amounts of ALA were being utilized a ‘metal’ becomes rate limiting. Bipyridyl treatment also inhibited ALA production in light-treated leaves. The incorporation of glycine-[¹⁴C] into ALA in the presence of bipyridyl was severely restricted compared to the incorporation of glutamate-[¹⁴C]. The data suggest two pathways for ALA synthesis; the classical ALA-synthetase which utilizes glycine and is operative in dark-grown leaves and a second enzyme system, which uses glutamate, and is of quantitative importance in the light.     

The Correlated Appearance of Prolamellar Bodies, Protochlorophyll(ide) Species, and the Shibata Shift during Development of Bean Etioplasts in the Dark

The structure and physiology of the etioplast was investigated in developing primary leaves of 3- to 9-day-old dark-grown bean (Phaseolus vulgaris L. var. Red Kidney) seedlings. Increase in total protochlorophyll(ide) content followed that of leaf fresh weight. In 3- to 4-day-old bean leaves more than 50% of the protochlorophyll(ide) is in the form of protochlorophyll(ide) 628, which is nontransformable by light. Most of the transformable pigment is protochlorophyll(ide) 635, with smaller amounts of protochlorophyll(ide) 650. During leaf development from the 3rd to the 7th day phototransformable protochlorophyll(ide) with an absorbance maximum at 650 nm accumulates faster than nontransformable protochlorophyll(ide) or protochlorophyll(ide) 635. This increase in protochlorophyll(ide) 650 is correlated with the formation and enlargement of prolamellar bodies.     

Circadian expression of the light-harvesting protein of Photosystem II in etiolated bean leaves following a single red light pulse: Coordination with the capacity of the plant to form chlorophyll and the thylakoid-bound protease

The appearance of the light harvesting II (LHC II) protein in etiolated bean leaves, as monitored by immunodetection in LDS-solubilized leaf protein extracts, is under phytochrome control. A single red light pulse induces accumulation of the protein, in leaves kept in the dark thereafter, which follows circadian oscillations similar to those earlier found for Lhcb mRNA (Tavladoraki et al. (1989) Plant Physiol 90: 665–672). These oscillations are closely followed by oscillations in the capacity of the leaf to form Chlorophyll (Chl) in the light, suggesting that the synthesis of the LHC II protein and its chromophore are in close coordination. Experiments with levulinic acid showed that PChl(ide) resynthesis does not affect the LHC II level nor its oscillations, but new Chl a synthesis affects LHC II stabilization in thylakoids, implicating a proteolytic mechanism. A proteolytic activity against exogenously added LHC II was detected in thylakoids of etiolated bean leaves, which was enhanced by the light pulse. The activity, also under phytochrome control, was found to follow circadian oscillations in verse to those in the stabilization of LHC II protein in thylakoids. Such a proteolytic mechanism therefore, may account for the circadian changes observed in LHC II protein level, being implicated in pigment-protein complex assembly/stabilization during thylakoid biogenesis.Abbreviations Chl chlorophyll - CL continuous light - D dark - FR far-red light - LA levulinic acid - LHC II light-harvesting complex serving Photosystem II - PChl(ide) protochlorophyllide - PCR protochlorophyllide oxidoreductase - R red light     

The greening process in cress seedlings. I. Pigment accumulation and ultrastructure after application of 5-aminolevulinate and complexing agents

A reduced rate of greening after continuous illumination was observed in dark-grown cress seedlings ( Lepidium sativum L.) incubated with 5-aminolevulinate (ALA) or the complexing agents 2,2'-bipyridyl, 8-hydroxyquinoline or 1,10-phenanthroline. This effect cannot be explained merely by photodynamic damage caused by chlorophyll precursors which are accumulated in the dark under these conditions. Flash light experiments revealed that photoconversion of protochlorophyll(ide) to chlorophyllide was not influenced by chelator treatment. The next step in the chlorophyll pathway, the esterification of chlorophyllide, however, was inhibited. Simultaneously applicated ALA and complexing agents did not result in a synergistic reponse; on the contrary, ALA seemed to render cress plants less susceptible to the treatment with complexing agents upon subsequent irradiation. Ultrastructural studies demonstrated that grana formation in light was inhibited after pretreatment with ALA or complexing agents.     

Chloroplast Biogenesis: XXII. Contribution of Short Wavelength and Long Wavelength Protochlorophyll Species to the Greening of Higher Plants

The contribution of short and long wavelength membrane-bound fluorescing protochlorophyll species to the over-all process of chlorophyll formation was assessed during photoperiodic growth. Protochlorophyll forms were monitored spectrofluorometrically at 77 K during the first six light and dark cycles in homogenates of cucumber (Cucumis sativus L.) cotyledons grown under a 14-hour light/10-hour dark photoperiodic regime, and in cotyledons developing in complete darkness. In the etiolated tissue, short wavelength protochlorophyll having a broad emission maximum between 630 and 640 nm appeared within 24 hours after sowing. Subsequently, the long wavelength species fluorescing at 657 nm appeared, and accumulated rapidly. This resulted in the preponderance of the long wavelength species which characterizes the protochlorophyll profile of etiolated tissues. The forms of protochlorophyll present in etiolated cucumber cotyledons resembled those in etiolated bean leaves in their absorption, fluorescence, and phototransformability. A different pattern of protochlorophyll accumulation was observed during the dark cycles of photoperiodic greening. The short wavelength species appeared within 24 hours after sowing. Subsequently, the long wavelength form accumulated and disappeared. The long wavelength to short wavelength protochlorophyll emission intensity ratio reached a maximum (~3:1) during the second dark cycle, then declined during subsequent dark cycles. Short wavelength species were continuously present in the light and dark. Primary corn and bean leaves exhibited a similar pattern of protochlorophyll accumulation. In cucumber cotyledons, both the short and long wavelengths species appeared to be directly phototransformable at all stages of photoperiodic development. It thus appears that whereas the long wavelength protochlorophyll species is the major chlorophyll precursor during primary photoconversion in older etiolated tissues, both long wavelength and short wavelength species seem to contribute to chlorophyll formation during greening under natural photoperiodic conditions.     

Capacity for chlorophyll synthesis in heat-bleached 70S ribosome-deficient rye leaves

The leaves of young rye plants (Secale cereale L.) grown at 32° were deficient in chlorophyll and in chloroplastic rRNA as compared to those grown at 22°, which developed normally. Both chlorophyll accumulation and the formation of plastidic rRNA were largely restored at 32° when the plants were transfered several times for 1 h per day to 22°. In the chlorotic 32°-grown rye leaves the in vivo activity of -aminolevulinate synthetase was very low. Aminolevulinate dehydratase however, exhibited high activity in extracts from 32°-grown leaves and was localized in the plastid fraction isolated from the chlorotic leaf tissue. After application of -aminolevulinic acid to chlorotic parts of leaves growing at 32°, protochlorophyll(ide) was formed and accumulated in the dark. In the light, the protochlorophyll(ide) was photooxidized at 32°. The results suggest a cytoplasmic site of synthesis for the series of enzymes converting -aminolevulinate to protochlorophyll(ide). It is concluded that an inhibition of -aminolevulinate synthetase and the photooxidation of protochlorophyll(ide) or chlorophyll are responsible for the chlorosis of the leaves at 32°.Abbreviations ALA -aminolevulinic acid - ALAD -aminolevulinate dehydratase - ALAS -aminolevulinate synthetase