Nucleic acid synthesis accompanying the recovery of cell division and chloroplast development in "giant" cells of the Emerson strain of Chlorella

The light-induced recovery of cell division and chloroplastdevelopment in "giant", "bleached", cells of the Emerson strainof Chlorella takes place without any increase in DNA and isrelatively insensitive to mitomycin C and 5-bromouracil. 5-Fluorouracilinhibits cell division only when it is supplied during the earlystages of recovery, perhaps by interfering with that phase ofRNA synthesis which occurs during the first 6 hr of recovery.This early burst of RNA synthesis is more sensitive to chloramphenicolthan is the second phase of RNA synthesis, suggesting that asignificant proportion of it may originate in the chloroplast.Evidence is presented which suggests that 5-fluorouracil interfereswith chloroplast development primarily through an effect onchlorophyll synthesis. The possible significance of these observationsin relation to nuclearchloroplastic interractions is discussed. (Received December 15, 1972; )     

The DNA-compacting protein DCP68 from soybean chloroplasts is ferredoxin:sulfite reductase and co-localizes with the organellar nucleoid

The multiple copies of the chloroplast genome (plastome) are condensed and organized into nucleoids by a set of proteins. One of these, the DNA-binding protein DCP68 from soybean, has previously been shown to compact DNA and to inhibit DNA synthesis in vitro. N-terminal amino acid analysis and the absorption spectrum of the purified protein suggest that DCP68 is the siroheme protein sulfite reductase, a ferredoxin-dependent enzyme that participates in sulfur assimilation for cysteine and methionine biosynthesis. The in vivoassociation of this protein with chloroplast nucleoids was confirmed by immuno-colocalization with antibodies against sulfite reductase from Arabidopsis thaliana. These results suggest that DCP68 is a bifunctional chloroplast protein that participates in reductive sulfur assimilation and plays a role in organellar nucleoid organization. The fact that dephosphorylation by alkaline phosphatase affects the binding of purified DCP68 to DNA in vitro might be indicative of the way the interaction of the protein with the nucleoid is regulated in vivo.     

Ferredoxin and ferredoxin-NADP-oxidoreductase in leaves ofPhaseolus vulgaris L.

During light-induced greening of 10-dayold etiolated bean seedlings a strong increase is observed of ferredoxin (Fd) and of ferredoxin-NADP-oxidoreductase (FNR; E.C. 1.6.99.4) activity, both known to reside in chloroplasts. The production of Fd starts immediately upon illumination and proceeds almost linearly for at least the next 72 h. It is inhibited by chloramphenicol (CAP) but not by cycloheximide (CHI), beit that in the presence of the latter Fd synthesis was impaired after 48 h of illumination. We conclude that for the elaboration of functional Fd in greening chloroplasts protein synthesis on chloroplast ribosomes is required. The increase of FNR activity shows a lag of about 24 h and is blocked by both CAP and CHI. When CAP is applied at 24 h after the illumination started it has no effect. We suggest that the synthesis of FNR on cytoplasmic ribosomes requires prior synthesis of protein(s) on chloroplast ribosomes.The nature of possible interactions between chloroplasts and cytoplasm is discussed.Abbreviations CAP D-threo-chloramphenicol - CHI cycloheximide - DCIP dichlorophenol-indophenol - DEAE diethylaminoethyl - Fd Ferredoxin - FNR ferredoxin-NADP-oxidoreductase - NAR nitrate reductase - NIR nitrite reductase     

A 43 kDa DNA binding protein from the pea chloroplast interacts with and stimulates the cognate DNA polymerase.

A DNA binding protein with DNA polymerase 'accessory activity' has been identified and purified to apparent homogeneity from pea chloroplasts. This protein consists of a single subunit of 43 kDa and binds to DNA regardless of its base sequence and topology. It increases cognate DNA polymerase-primase activity in a dose dependent manner. Using solid phase protein-protein interaction trapping and co-immunoprecipitation techniques, the purified protein was found to associate with the chloroplast DNA polymerase. The chloroplast DNA polymerase also binds directly to the radioiodinated 43 kDa protein. The specific interaction between 43 kDa protein and chloroplast DNA polymerase results in the synthesis of longer DNA chains. The 43 kDa protein, present abundantly in the pea chloroplast, appears to increase processivity of the chloroplast DNA polymerase and may play an important role in the replication of pea chloroplast DNA.     

ROLE OF MULTIPLE FTSZ RINGS IN CHLOROPLAST DIVISION UNDER OLIGOTROPHIC AND EUTROPHIC CONDITIONS IN THE UNICELLULAR GREEN ALGA NANNOCHLORIS BACILLARIS (CHLOROPHYTA,TREBOUXIOPHYCEAE)1

Chloroplasts of the unicellular green alga Nannochloris bacillaris Naumann cultured under nutrient‐enriched conditions have multiple rings of FtsZ, a prokaryote‐derived chloroplast division protein. We previously reported that synthesis of excess chloroplast DNA and formation of multiple FtsZ rings occur simultaneously. To clarify the role of multiple FtsZ rings in chloroplast division, we investigated chloroplast DNA synthesis and ring formation in cells cultured under various culture conditions. Cells transferred from a nutrient‐enriched medium to an inorganic medium in the light showed a drop in cell division rate, a reduction in chloroplast DNA content, and changes in the shape of chloroplast nucleoids as cells divided. We then examined DNA synthesis by immunodetecting BrdU incorporated into DNA strands using the anti‐BrdU antibody. BrdU‐labeled nuclei were clearly observed in cells 48 h after transfer into the inorganic medium, while only weak punctate signals were visible in the chloroplasts. In parallel, the number of FtsZ rings decreased from 6 to only 1. When the cells were transferred from an inorganic medium to a nutrient‐enriched medium, the number of cells increased only slightly in the first 12 h after transfer; after this time, however, they started to divide more quickly and increased exponentially. Chloroplast nucleoids changed from punctate to rod‐like structures, and active chloroplast DNA synthesis and FtsZ ring formation were observed. On the basis of our results, we conclude that multiple FtsZ ring assembly and chloroplast DNA duplication under nutrient‐rich conditions facilitate chloroplast division after transfer to oligotrophic conditions without further duplication of chloroplast DNA and formation of new FtsZ rings.     

The Chloroplast and Cytoplasmic Ribosomes of Euglena: II. Characterization of Ribosomal Proteins

Cytoplasmic and chloroplast ribosomal proteins were isolated from Euglena gracilis and analyzed on polyacrylamide gels. Cytoplasmic ribosomes appear to contain 75 to 100 proteins ranging in molecular weight from 10,200 to 104,000, while chloroplast ribosomes appear to contain 35 to 42 proteins with molecular weights ranging from 9,700 to 57,900. This indicates that the cytoplasmic ribosomes are similar in composition to other eucaryotic ribosomes, while chloroplast ribosomes have a protein composition similar to the 70S procaryotic ribosome. The kinetics of light-induced labeling of cytoplasmic ribosomal proteins during chloroplast development has been determined, and the results are compared with the kinetics of ribosomal RNA synthesis.     

DNA Products in In Vitro DNA Synthesis Using Bacteriophage ϕX174 Single-stranded DNA

We described product analysis of DNA synthesized in chloroplast lysate from liverwort Marchantia polymorpha L. cell suspension cultures. Characteristics of in vitro DNA synthesis by chloroplast lysate using bacteriophage ?X174 single-stranded DNA were very similar to those in the case of double-stranded calf thymus DNA reported previously. Autoradiographic analysis clearly showed the incorporation of radioactive [α-³²P]-dCTP into DNA molecules associated with bacteriophage ?X174 single-stranded template DNA, indicating conversion of bacteriophage ?X174 single-stranded DNA to double-stranded DNA (RF III, double-stranded linear molecule). Experiments on the fate of [³²P]-labeled single-stranded DNA also showed a clear conversion of the single-stranded DNA to double-stranded DNA. Furthermore, patterns of sucrose density gradient centrifugations (neutral and alkaline) showed the production of two major components in in vitro DNA synthesis by chloroplast lysate. This also indicated conversion of bacteriophage ?X174 single-stranded DNA to double-stranded DNA (RF III form). Our results suggest that the mechanism of chloroplast DNA replication could be the mode of strand-displacement DNA synthesis as seen in animal mitochondrial DNA synthesis.     

Cellular content of chloroplast DNA and chloroplast ribosomal RNA genes in Euglena gracilis during chloroplast development.

The cellular content of chloroplast DNA in Euglena gracilis has been quantitatively determined. DNA was extracted from Euglena cells at various stages of chloroplast development and renatured in the presence of trace amounts of 3H-labeled chloroplast DNA. From the kinetics of renaturation of the 3H-labeled chloroplast DNA, compared with the kinetics of renaturation of excess nonradioactive chloroplast DNA, the fraction of cellular DNA represented by chloroplast DNA was calculated. The content of chloroplast DNA was found to increase from 4.9 to 14.6% of cellular DNA during light-induced chloroplast development. Correcting for the change in DNA mass per cell, the number of copies of chloroplast DNA is found to vary from 1400 to 2900 per cell. During this developmental transition, the cellular content of the chloroplast ribosomal RNA genes varies from 1900 to 5200 copies per cell. The ratio of the number of copies of rRNA genes to chloroplast genomes per cell remains in the range of 1-2 throughout chloroplast development, ruling out selective amplification of chloroplast rRNA genes as a means of regulation of rRNA gene expression. Direct measurement of the number of rRNA cistrons per 9.2 X 10(7) dalton genome yields a value of 1 or 2.     

EFFECTS OF CHLORAMPHENICOL ON CHLOROPLAST AND MITOCHONDRIAL ULTRASTRUCTURE IN OCHROMONAS DANICA

The effect of chloramphenicol (CAP) on cell division and organelle ultrastructure was studied during light-induced chloroplast development in the Chrysophyte alga, Ochromonas danica. Since the growth rate of the CAP-treated cells is the same as that of the control cells for the first 12 hr in the light, CAP is presumed to be acting during that interval solely by inhibiting protein synthesis on chloroplast and mitochondrial ribosomes. CAP markedly inhibits chloroplast growth and differentiation. During the first 12 hr in the light, chlorophyll synthesis is inhibited by 93%, the formation of new thylakoid membranes is reduced by 91%, and the synthesis of chloroplast ribosomes is inhibited by 81%. Other chloroplast-associated abnormalities which occur during the first 12 hr and become more pronounced with extended CAP treatment are the presence of prolamellar bodies and of abnormal stacks of thylakoids, the proliferation of the perinuclear reticulum, and the accumulation of dense granular material between the chloroplast envelope and the chloroplast endoplasmic reticulum. CAP also causes a progressive loss of the mitochondrial cristae, which is paralleled by a decline in the growth rate of the cells, but it has no effect on the synthesis of mitochondrial ribosomes. We postulate that one or more chloroplast ribosomal proteins are synthesized on chloroplast ribosomes, whereas mitochondrial ribosomal proteins are synthesized on cytoplasmic ribosomes.     

Effects of two TMV strains on the synthesis and stability of chloroplast ribosomal RNA in tobacco leaves

Summary Multiplication of TMV-strains vulgare (light-green/dark-green mosaic symptoms) and flavum (severe yellow/green mosaic) had different effects on the ribosomal RNA of tobacco leaf chloroplasts. Vulgare inhibited chloroplast ribosomal RNA synthesis while having no effect on cytoplasmic ribosomal RNA synthesis (Fig. 2). Flavum inhibited chloroplast ribosomal RNA synthesis more severely than vulgare, and caused an earlier degradation of chloroplast ribosomal RNA than in control or vulgare-infected leaves (Fig. 1). Flavum also inhibited cytoplasmic ribosomal RNA synthesis. A connection between these differing effects on chloroplast ribosomal RNA metabolism and severity of visible symptoms is suggested, and discussed in relation to a possible influence on symptoms of denatured virus coat protein.Abbreviations TMV Tobacco Mosaic Virus - RNA Ribonucleic acid - DNA Deoxyribonucleic acid - m millions (in molecular weight values)     

Analysis and characterization of DCMU-resistant Euglena gracilis

Dark-grown, DCMU-adapted Euglena gracilis Z (ZR) are able to undergo light-induced chloroplast development in the presence or absence of DCMU. The differentiated chloroplasts are photosynthetically active and are resistant not only to DCMU, but also to an analog, o-phenanthrolene. When DCMU overdoses are added to ZR cells or to chloroplasts isolated from these cells, photosynthesis is partially inhibited. A brief period of darkness removes this inhibition. This recovery phenomenon is related to DCMU resistance, since it is not exhibited by non-resistant control cells. The chloroplast protein synthesis apparatus is not involved in DCMU resistance. Rather, this phenomenon is apparently related to new characteristics of thylakoids. It is shown that photosynthetic recovery by ZR cells depends on the accessibility and fluid properties of membranes. The analysis of fluorescence induction kinetics shows that changes in the environmental conformation of photosystem II units occur during recovery.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - ZR DCMU-adapted Euglena gracilis Z I and II=Calvayrac et al., in press (a, b)     

Plastid and nuclear DNA synthesis are not coupled in suspension cells ofNicotiana tabacum

The relationship between nuclear and plastid DNA synthesis in cultured tobacco cells was measured by following³H-thymidine incorporation into total cellular DNA in the absence or presence of specific inhibitors. Plastid DNA synthesis was determined by hybridization of total radiolabeled cellular DNA to cloned chloroplast DNA. Cycloheximide, an inhibitor of nuclear encoded cytoplasmic protein synthesis, caused a rapid and severe inhibition of nuclear DNA synthesis and a delayed inhibition of plastid DNA synthesis. By contrast, chloramphenicol which only inhibits plastid and mitochondrial protein production, shows little inhibition of either nuclear or plastid DNA synthesis even after 24 h of exposure to the cells. The inhibition of nuclear DNA synthesis by aphidicolin, which specifically blocks the nuclear DNA polymeraseα, has no significant effect on plastid DNA formation. Conversely, the restraint of plastid DNA synthesis exerted by low levels of ethidium bromide has no effect on nuclear DNA synthesis. These results show that the synthesis of plastid and nuclear DNA are not coupled to one another. However, both genomes require the formation of cytoplasmic proteins for their replication, though our data suggest that different proteins regulate the biosynthesis of nuclear and plastid DNA.     

Mapping of genes on the chloroplast DNA of Spirodela oligorhiza

With the use of spinach chloroplast RNAs as probes, we have mapped the rRNA genes and a number of protein genes on the chloroplast DNA (cpDNA) of the duckweed Spirodela oligorhiz. For a more precise mapping of these genes we had to extend the previously determined [14] restriction endonuclease map of the duckweed cpDNA with the cleavage sites for the restriction endonucleases Sma I and Bgl I. The physical map indicates that duckweed cpDNA contains two inverted repeat regions (18 Md) separated by two single copy regions with a size of 19 Md and 67 Md, respectively.By hybridization with spinach chloroplast rRNAs it could be shown that each of the two repeat units contains one set of rRNA genes in the order: 16S rRNA gene — spacer — 23S rRNA gene — 5S rRNA gene.A spinach chloroplast mRNA preparation (14S RNA), which is predominantly translated into a 32 Kilodalton (Kd) protein [9], hybridized strongly to a DNA fragment in the large single copy region, immediately outside one of the inverted repeats. With another mRNA preparation (18S), which mainly directs the in vitro synthesis of a 55 Kd protein [9], hybridization was observed with two DNA regions, located between 211° and 233° and between 137° and 170°, respectively. Finally, with a spinach chloroplast genomic probe for the large subunit of ribulose 1,5-bisphosphate carboxylase [17], hybridization was found with a DNA fragment located between 137° and 158° on the map.     

Chloroplast signalling in the light induction of nuclear HSP70 genes requires the accumulation of chlorophyll precursors and their accessibility to cytoplasm/nucleus

Chlorophyll precursors Mg-protoporphyrin IX and its monomethylester are candidates for plastid-derived molecules involved in light signalling from the chloroplast to the nucleus. The pool sizes of these two Mg2+-containing porphyrins and of protoporphyrin IX transiently increased upon a shift of Chlamydomonas cultures from dark to light. This increase coincided with the accumulation of mRNAs encoded by the nuclear genes HSP70A and HSP70B. Analysis of a mutant (brs-1), previously shown to be defective in the light induction of these genes, revealed high levels of protoporphyrin IX but no light-induced increase in the levels of Mg2+-containing porphyrins. Inhibitors of cytoplasmic protein synthesis prevented both the light-induced rise in pool levels and induction of the HSP70 genes. Similarly, pre-gametes, intermediates of sexual differentiation, lacked both responses to light. The block in light induction of the HSP70 genes in inhibitor-treated cells and in pre-gametes could be circumvented by the exogenous addition of Mg-protoporphyrin IX in the dark. This suggests an essential role for light-induced Mg-protoporphyrin IX accumulation in this chloroplast-to-nucleus signalling pathway. However, accumulation of this porphyrin in the dark - presumably in the chloroplast - did not result in induction. A second crucial role for light in this signalling pathway is postulated which makes this plastidic compound accessible to the cytoplasm/nucleus where the downstream signalling pathway may be activated.     

Light regulation of protein synthesis factor EF-G in pea chloroplasts

The activity of pea chloroplast elongation factor G (EF-G), a nuclear-coded protein required for the elongation cycle of chloroplast protein synthesis, is regulated in response to light. In pea seedlings germinated and grown under continuous white or red light, EF-G specific activity reaches a maximum between days 10 to 15, and then decreases. EF-G activity is almost undetectable in extracts from dark-grown seedlings. When 13-day dark-grown pea seedlings are transferred to light, EF-G specific activity reaches a higher value after 2 to 3 days than observed in seedlings grown under continuous light. The small and large subunits of ribulose bisphosphate carboxylase continue to accumulate after EF-G specific activity has reached maximum levels. Cytoplasmically synthesized components of the chloroplast protein synthetic apparatus, such as EF-G, may help coordinate cytoplasmic and nuclear events with chloroplast gene expression during light-induced chloroplast differentiation.     

Regulation of synthesis of the photosystem I reaction center

The in vivo biosynthesis of the P700 chlorophyll a-apoprotein was examined to determine whether this process is light regulated and to determine its relationship to chlorophyll accumulation during light- induced chloroplast development in barley (Hordeum vulgare L.). Rabbit antibodies to the 58,000-62,000-mol-wt apoprotein were used to measure relative synthesis rates by immunoprecipitation of in vivo labeled leaf proteins and to detect apoprotein accumulation on nitrocellulose protein blots. 5-d-old, dark-grown barley seedlings did not contain, or show net synthesis of, the 58,000-62,000-mol-wt polypeptide. When dark- grown barley seedlings were illuminated, net synthesis of the apoprotein was observed within the first 15 min of illumination and accumulated apoprotein was measurable after 1 h. After 4 h, P700 chlorophyll a-apoprotein biosynthesis accounted for up to 10% of the total cellular membrane protein synthesis. Changes in the rate of synthesis during chloroplast development suggest coordination between production of the 58,000-62,000-mol-wt polypeptide and the accumulation of chlorophyll. However, when plants were returned to darkness after a period of illumination (4 h) P700 chlorophyll a-apoprotein synthesis continued for a period of hours though at a reduced rate. Thus we found that neither illumination nor the rate of chlorophyll synthesis directly control the rate of apoprotein synthesis. The rapidity of the light-induced change in net synthesis of the apoprotein indicates that this response is tightly coupled to the primary events of light-induced chloroplast development. The data also demonstrate that de novo synthesis of the apoprotein is required for the onset of photosystem I activity in greening seedlings.     

Chloroplast elongation factor Tu: Evidence that it is the product of a chloroplast gene in Euglena

The chloroplast protein synthesizing factor responsible for the binding of aminoacyl-tRNA to ribosomes (EF-Tu_chl) has been identified in extracts of Euglena gracilis. This factor is present in low levels when Euglena is grown in the dark and can be induced more than 10-fold when the organism is exposed to light. The induction of the chloroplast EF-Tu by light is inhibited by streptomycin, an inhibitor of protein synthesis on chloroplast ribosomes, indicating that protein synthesis within the chloroplast itself is required for the induction of this factor. The induction of the chloroplast EF-Tu by light is also inhibited by cycloheximide, a specific inhibitor of protein synthesis on cytoplasmic ribosomes. The effect of cycloheximide probably results from the inhibition of chloroplast ribosome synthesis which requires the synthesis of many proteins by the cytoplasmic translational system. Chloroplast EF-Tu cannot be induced by light in an aplastidic mutant (strain W₃BUL) of Euglena which has neither significant plastid structure nor detectable chloroplast DNA. These data strongly suggest that the genetic information for chloroplast EF-Tu resides in the chloroplast genome and that this protein is synthesized within the organelle itself.