Events surrounding the early development of Euglena chloroplasts. 16. Plastid thylakoid polypeptides during greening

Using sulfolipid to locate plastid thylakoid membranes in gradients from dark-grown resting cells it has been possible to study the plastid thylakoid membrane polypeptides of Euglena gracilis var. bacillaris undergoing light-induced chloroplast development. All plastid thylakoid bands seen in dark-growing wild-type cells and in mutant W₃BUL in which plastid DNA is undetectable, are observed to increase in amount during plastid development. Others, which are undetectable in dark-grown wild-type and W₃BUL increase greatly during plastid development and appear to be those associated with pigment-protein complexes. The data obtained from experiments where the polypeptides were labeled with ³⁵S during development, either continuously or in pulses, were consistent with these findings. Cycloheximide strongly inhibited the increases in amount in all bands and chloramphenicol or streptomycin produced a lower level of inhibition in all bands indicating tight control of the formation of each plastid membrane constituent by the others. The formation of a polypeptide band of 25 000 molecular weight, thought to be a part of a pigment-protein complex of the thylakoid, and chlorophyll synthesis were inhibited identically by these antibiotics.     

Events surrounding the early development of Euglena chloroplasts. 15. Origin of plastid thylakoid polypeptides in wild-type and mutant cells.

Techniques are described for the isolation of plastid thylakoid membranes from light-grown and dark-grown cells of Euglena gracilis var. bacillaris, and from mutants affecting plastid development. These membranes, which have minimal contamination with other cell fractions, are localized in sucrose gradients by using the thylakoid membrane sulfolipid as a specific marker. The plastid thylakoid membrane polypeptides isolated from these membranes were separated on SDS polyacrylamide gels and yielded patterns containing 30-40 polypeptides. Light-grown strain Z gave patterns identical with bacillaris. Since the plastid thylakoid polypeptide patterns obtained from dark-grown wild-type cells and from a bleached mutant W3BUL in which plastid DNA is undetectable are identical, it appears that the proplastid thylakoid polypeptides of wild-type cannot be coded in plastid DNA and are probably coded in nuclear DNA. The plastid thylakoid polypeptide patterns obtained from various dark-grown mutants, making large but abnormal chloroplasts, show a correlation between the amount of chlorophyll formed and the amount of a plastid thylakoid polypeptide thought to be associated wtth one of the pigment-protein light-harvesting complexes. Treatment with SAN 9789 (4-chloro-5-(methylamino)-2(alpha, alpha, alpha,-trifluoro-m-tolyl)-3-(2H(pyridazinone) known to block carotenoid synthesis at the level of phytoene, causes a progressive loss of all plastid thylakoid polypeptides during growth in darkness and results in the establishment of a new, lowere steady-state level of sulfolipid. At least ten of the plastid thylakoid polypeptides become labeled when isolated chloroplasts are supplied with radioactive amono acids; of these six are undectable in W3BUL and are, therefore, candidates for coding by plastid DNA.     

Events surrounding the early development of Euglena chloroplasts 13. Photocontrol of protein synthesis

Protein synthesis measured as leucine incorporation was followedduring the early hours of light exposure of dark-grown cellsof wild type cells of Euglena gratilis var. bacillaris and ofbleached mutants W₃BUL and W₁₀SmL which lack detectable plastidDNA. In all strains, linear rates of leucine incorporation wereobserved in dark-grown resting cells and on exposure to light,this rate increased. After about 3 hr light exposure in wildtype cells and somewhat later in the mutants, the rate of proteinsynthesis sharply declined below that of the dark-grown anddark-incubated cells. Experiments in wild type cells showedthat leucine uptake was not rate limiting for protein synthesisalthough light exposure decreased the rate of uptake. The changesin rate found during continuous labeling of wild type cellswere verified by pulse-labeling experiments in continuous light.Exposure of dark-grown wild type cells to a two hour pulse oflight produced a transient increase in the rate of leucine incorporationwhich subsequently returned in darkness to the level of thedark-grown cells which received no light; thus the changes inrate of leucine incorporation are light-dependent. Since theeffects of light on leucine incorporation can be reproducedin mutants lacking detectable plastid DNA, the photoreceptormachinery involved cannot be coded in plastid DNA, and probablyoriginates in nuclear DNA. The role of light in programmingprotein synthesis and turnover in early chloroplast developmentis discussed. ¹Supported by Grant Number GM-14595 from the National Institutesof Health. ²Microbiology trainee of the National Institutes of Health,Grant Number GM1586. Portions of the material in this paperwere taken from a dissertation submitted by S. D. S. to theGraduate Faculty of Brandeis University in partial fulfillmentof the requirements for the Ph.D. degree. Present address: Schoolof Life Sciences, University of Nebraska-Lincoln, Lincoln, Nebraska68588, U. S. A. ³Abraham and Etta Goodman Professor of Biology and Director,Institute for Photobiology of Cells and Organdies, BrandeisUniversity, Waltham, MA, U. S. A. 02154, to whom reprint requestsshould be sent. (Received February 8, 1979; )     

Events surrounding the early development of Euglena chloroplasts. 15. Origin of plastid thylakoid polypeptides in wild-type and mutant cells

Techniques are described for the isolation of plastid thylakoid membranes from light-grown and dark-grown cells of Euglena gracilis var. bacillaris, and from mutants affecting plastid development. These membranes, which have minimal contamination with other cell fractions, are localized in sucrose gradients by using the thylakoid membrane sulfolipid as a specific marker. The plastid thylakoid membrane polypeptides isolated from these membranes were separated on SDS polyacrylamide gels and yielded patterns containing 30–40 polypeptides. Light-grown strain Z gave patterns identical with bacillaris. Since the plastid thylakoid polypeptide patterns obtained from dark-grown wild-type cells and from a bleached mutant W₃BUL in which plastid DNA is undetectable are identical, it appears that the proplastid thylakoid polypeptides of wild-type cannot be coded in plastid DNA and are probably coded in nuclear DNA. The plastid thylakoid polypeptide patterns obtained from various dark-grown mutants are identical to those obtained from dark-grown wild-type cells. Light-grown mutants, making large but abnormal chloroplasts, show a correlation between the amount of chlorophyll formed and the amount of a plastid thylakoid polypeptide thought to be associated with one of the pigment-protein light-harvesting complexes. Treatment with SAN 9789 (4-chloro-5-(methyl-amino)-2-(α,α,α,-trifluoro-m-tolyl)-3-(2H(pyridazinone) known to block carotenoid synthesis at the level of phytoene, causes a progressive loss of all plastid thylakoid polypeptides during growth in darkness and results in the establishment of a new, lower steady-state level of sulfolipid. At least ten of the plastid thylakoid polypeptides become labeled when isolated chloroplasts are supplied with radioactive amino acids; of these six are undectable in W₃BUL and are, therefore, candidates for coding by plastid DNA.     

Events surrounding the early development of euglena chloroplasts: v. Control of paramylum degradation

The degradation of the storage carbohydrate, paramylum, is induced by light in wild-type Euglena gracilis Klebs var. bacillaris Pringsheim and in a mutant, W₃BUL, which lacks detectable plastid DNA. Treatment of wild type with cycloheximide in the dark produces 60% as much paramylum breakdown as light, whereas treatment with levulinic acid in the dark yields a slightly greater response than light. Both cycloheximide and levulinic acid produce a greater paramylum breakdown in the light than they do in the dark. Treatment of W₃BUL with levulinic acid in darkness produces a larger paramylum degradation than light, with values similar to wild type in the light. Treatment of W₃BUL with cycloheximide induces paramylum degradation in darkness, and as with wild type, light is slightly stimulatory in the presence of both cycloheximide or levulinic acid. Streptomycin brings about only a very small amount of paramylum breakdown in the dark and only slightly inhibits breakdown in the light. Thus paramylum breakdown induced by light does not require the synthesis of proteins on cytoplasmic or plastid ribosomes. A model which explains these results postulates the existence of a protein which inhibits paramylum breakdown. When the synthesis of this protein is prevented either by light, cycloheximide, or by levulinic acid acting as a regulatory analog of delta amino levulinic acid, paramylum breakdown takes place. Because levulinic acid is a better inducer than light in W₃BUL, W₃BUL may not be able to form as much delta amino levulinic acid in light as wild type. The small amount of induction by streptomycin is viewed as a secondary regulatory effect attributable to interference with plastid protein synthesis which affects regulatory signals from the plastid to the rest of the cell.     

Plastid development in primary leaves of Phaseolus vulgaris. Development of plastid adenosine triphosphatase activity during greening.

The etioplasts of dark-grown bean leaves showed ATPase (adenosine triphosphatase) activity which had a pH optimum of 8.5, was stimulated by dithiothreitol and unaffected by light-triggering. Bean chloroplasts showed a low activity of dark-induced ATPase with a pH optimum of 8.5 and a substantial amount of light-triggered activity with a pH optimum of 8.0. The light-triggered activity depended on dithiothreitol and Mg2+ and was promoted by phenazine methosulphate. Light-triggered ATPase activity was completely inhibited by 20mum-dicyclohexylcarbodi-imide. Etioplasts developed light-triggered ATPase activity in response to 30 min illumination of the etiolated leaves. During the 48 h of light-induced greening of dark-grown leaves there was a 70% increase of the chloroplast ATPase activity found after light-triggering and a 30% fall in the dark-induced activity, both expressed on a per leaf basis. As the larger part of these changes occurred during the first 30 min of illumination, it is concluded that most or all of the chloroplast ATPase was present in the etioplast, a conclusion identical with that of Lockshin et al. (1971) for maize. During 48 h of greening there was a tenfold increase in the amount of thylakoid membrane in the leaf together with an 83% fall in the ATPase activity per m2 of thylakoid membrane, measured after light-triggering.     

Azide-sensitive thylakoid membrane insertion of chimeric cytochrome f polypeptides imported by isolated pea chloroplasts

Post-translational integration of cytochrome f into thylakoid membranes was observed after import by isolated pea chloroplasts of a chimeric protein consisting of the presequence of the small subunit of ribulose 1,5-bisphosphate carboxylase fused to the cytochrome f precursor. Import of a similar chimeric protein lacking the C-terminal 33 amino acid residues resulted in a soluble cytochrome f protein in the thylakoid lumen, indicating that the C-terminal region contains a stop-transfer sequence for membrane integration. Azide inhibited the insertion of cytochrome f into the thylakoid membrane, whereas the ionophores nigericin and valinomycin had little effect on membrane insertion. The precursor of the 33 kDa protein, but not the 23 kDa protein, of the photosystem II oxygen-evolving complex inhibited the thylakoid insertion of cytochrome f , suggesting competition for a component of the transport pathway. These experiments suggest that the post-translational insertion of cytochrome f into the thylakoid membrane uses a SecA-dependent pathway.     

Light-dependent phosphorylation of thylakoid membrane polypeptides.

The phosphorylation of thylakoid membrane proteins was studied using isolated chloroplasts from $\text{Euglena gracilis}$. We have found, using [³²P] labelling, that this phenomenon was light-driven, reversible in the dark, and completely inhibited by Carbonyl cyanide m-chlorophenyl-hydrazone (CCCP). Polyacrylamide gel electrophoresis containing SDS has revealed five main bands which have been found to be proteins. Amino acid analysis of the bands has shown that [³²P] is incorporated into phosphothreonine.     

Plastid changes during the conversion of chloroplasts to chromoplasts in ripening tomatoes

Methods were developed for the isolation of plastids from mature green and ripening tomatoes (Lycopersicon esculentum Mill.) and purification by sucrose or Percoll density-gradient centrifugation. Assessment of the purity of preparations involved phase-contrast and electron microscopy, assays for marker enzymes and RNA extraction and analysis. Proteins were extracted from isolated plastids at different ripening stages and separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The profiles obtained from chloroplasts and chromoplasts showed many qualitative and quantitative differences. Labelling of proteins with [³⁵S]methionine in vivo showed that there was active protein synthesis throughout ripening, but there was a change in the plastid proteins made as ripening proceeded. The cellular location of synthesis of specific proteins has yet to be established.Abbreviations CS citrate synthase - EDTA ethylenediaminetetraacetic acid,-acetate - GAPDH NADP⁺-glyceraldehyde-3-phosphate dehydrogenase - rRNA ribosomal RNA - SDS sodium dodecyl sulphate - SDS-PAGE SDS-polyacrylamide gel electrophoresis - Tris 2-amino-2(hydroxymethyl)-1,3-propanediol     

Subchloroplast localization of polypeptides synthesized by chloroplasts during senescence

To study the localization of polypeptides synthesized by isolated senescent chloroplasts we have fractionated the chloroplasts into stroma, envelope and thylakoid components. The validity of the fractionation procedure was tested by assaying both chlorophyll and enzyme markers, as well as the polypeptide composition of each fraction. Plastids in the transition of etioplast to chloroplast, senescent chloroplasts and kinetin-treated chloroplasts produced acceptable fractions, although their polypeptide compositions varied considerably during the ontogeny, particularly those of the envelope. Most of the polypeptides synthesized by isolated senescent chloroplasts were incorporated into the thylakoids except for a 58 kDa polypeptide localized in the stroma and some minor polypeptides present in both stroma and envelope. Although most of the polypeptides synthesized by isolated chloroplasts from kinetin-treated leaves were incorporated into the thylakoid membrane, several polypeptides were found in the stroma (90, 80, 65 and 54 kDa) and in the envelope (100, 75, 48 and 28–30 kDa). The results indicate that early in senescence, the polypeptides of the envelope change but, that probably, most of the new polypeptides are synthesized in the cytoplasm.     

Functional and structural organization of chlorophyll in the developing photosynthetic membranes of Euglena gracilis Z. IV. Light-harvesting properties of system II photosynthetic units and thylakoid ultrastructure during greening under intermittent light

Dark-grown, non-dividing Euglena gracilis Z cells were exposed for 100 h to intermittent light (15 s every 15 min darkness) and were then transferred to continuous light. During chloroplast differentiation, the development of light harvesting and trapping properties of Photosystem II was analyzed mainly with fluorescence induction measurements in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea and was associated with observations on ultrastructural organisation of developing thylakoids using thin section and freeze-fracture methods. Results showed that: (a) the synthesis of chlorophyll b and probably that of the light-harvesting chlorophyll a/b-protein complex was more reduced by intermittent light than the formation of active system II reaction centers; (b) the size of the overall photosynthetic units, i.e. the number of chlorophyll molecules per O2 molecule evolved under a regime of repetitive saturating short flashes were reduced by 2-3 compared to those developed under continuous light; (c) the lack of chlorophyll induced by intermittent light affected more specifically the size of light-harvesting antennae of system II units, the optical cross-section of which was reduced by 3-4; (d) energy transfers did not occur between these small system II units in spite of high concentrations of PS II reaction centers and of a high trapping efficiency of the absorbed energy; (e) thylakoids developed under intermittent light were not stacked; (f) particles on exoplasmic fracture faces were significantly smaller than those developed under continuous light; (g) rapid synthesis of chlorophyll (Chl a and Chl b) upon exposure to continuous light of cells first greened under intermittent light are concomittant with rapid recovery of light-harvesting properties and structural characteristics of thylakoids developed under continuous light. These structural and functional observations are consistent with the hypothesis that system II units are organized in the photosynthetic membrane as individual and discrete entities, the morphological expression of which correspond to exoplasmic fracture face particles. They also support the model whereby energy transfers between physically connected system II units could occur across the partition between exoplasmic fracture face particles brought into contact in stacked regions.