Chloroplast DNA of Acetabularia mediterranea: Cell cycle related changes in distribution

Chloroplast DNA (cpDNA) distribution in the giant unicellular, uninucleate alga Acetabularia mediterranea was analyzed with the DNA-specific fluorochrome 4'6-diamidino-2-phenylindole (DAPI) at various stages of the cell cycle. The number of chloroplasts exhibiting DNA/DAPI fluorescence changes during the cell's developmental cycle: (1) all chloroplasts in germlings contain DNA; (2) the number of plastids with DNA declines during polar growth of the vegetative cell; (3) it increases again prior to the transition from the vegetative to the generative phase; (4) several nucleoids of low fluorescence intensity are present in the chloroplasts of the gametes. The temporal distribution of the number of chloroplasts with DNA appears to be linked to the different mode of chloroplast division and growth during the various stages of development. The chloroplast cycle in relation to the cell cycle is discussed.Abbreviations cpDNA chloroplast DNA - DAPI 4,6-diamidino-2-phenylindole     

Heterogeneity of chloroplasts in Acetabularia mediterranea. Heterogeneous distribution and morphology of chloroplast DNA

A high percentage of chloroplasts in the siphonaceous green alga Acetabularia mediterranea lacks DNA: staining with the sensitive DNA-specific fluorochrome 4′-6-diamidino-2-phenylindole (DAPI) revealed that DNA was present only in 47–51% of the total plastid population. The distribution of DNA-containing chloroplasts appeared heterogeneous, exhibiting an apicobasal gradient. DNA could be detected in 64, 46, 35, and 36% of the plastids from the apical, subapical, middle, and basal part of the cell, respectively. DNA morphology also exhibited heterogeneity. Three types of nucleoid were distinguished: (1) round compact nucleoids; (2) long thin nucleoids characteristic of chloroplasts of the cell apex and the whorls; and (3) elaborate nucleoids appearing to consist of several subunits, which were more typical of the middle and basal part of the cell. On the basis of the nucleoid morphology and the decrease in DNA-containing plastids from the apex towards the basis of the cell, we propose a model for the development of plastids lacking DNA in relation to chloroplast replication.     

The role of chloroplast membranes in the location of chloroplast DNA during the greening ofPhaseolus vulgaris etioplasts

Summary The location of DNA containing nucleoids has been studied in greening bean (Phaseolus vulgaris L.) etioplasts using electron microscopy of thin sections and the staining of whole leaf cells with the fluorochrome DAPI. At 0 hours illumination a diffuse sphere of cpDNA surrounds most of the prolamellar body. It appears to be made up of a number of smaller nucleoids and can be asymmetric in location. The DNA appears to be attached to the outside of the prolamellar body and to prothylakoids on its periphery. With illumination the nucleoid takes on a clear ring-like shape around the prolamellar body. The maximum development of the ring-like nucleoid at 5 hours illumination is associated with the outward expansion of the prolamellar body and the outward growth of the prothylakoids. At 5 hours the electron transparent areas lie in between the prothylakoids radiating out from the prolamellar body. Between 5 hours and 15 hours observations are consistent with the growing thylakoids separating the nucleoids as the prolamellar body disappears and the chloroplast becomes more elongate. At 15 hours the fully differentiated chloroplast has discrete nucleoids distributed throughout the chloroplast with evidence of thylakoid attachment. This is the SN (scattered nucleoid) distribution ofKuroiwa et al. (1981) and is also evident in 24 hours and 48 hours chloroplasts which have more thylakoids per granum. The changes in nucleoid location occur without significant changes in DNA levels per plastid, and there is no evidence of DNA or plastid replication.The observations indicate that cpDNA partitioning in dividing SN-type chloroplasts could be achieved by thylakoid growth and effectively accomplish DNA segregation, contrasting with envelope growth segregating nucleoids in PS-type (peripheral scattered nucleoids) chloroplasts. The influence of plastid development on nucleoid location is discussed.     

BEHAVIOR OF CHLOROPLAST NUCLEOIDS DURING THE CELL CYCLE OF CHLAMYDOMONAS REINHARDTII (CHLOROPHYTA) IN SYNCHRONIZED CULTURE1

Cells of Chlamydomonas reinhardtii Dangeard were synchronized under a 12:12 h light: dark regimen. They increased in size during the light period, while nuclear division, chloroplast division and cytokinesis occurred during the dark period. Zoospores were liberated toward the end of the dark period. Changes in profile and distribution of chloroplast nucleoids were followed with a fluorescence Microscope after fixation with 0.1%(w/v) glutaraldehyde followed by staining with 4′.6-diamidino-2-phenylidole (DAPI), a DNA fluorochrome. About ten granular nucleoids were dispersed in the chloroplast at the beginning of the light period (0 h). Within 4 h the nucleoids aggregated around the pyrenoid giving a compact profile. The formation of the compact aggregate of cp-nucleoids around the pyrenoid occurred with maximal frequency twice during the light period. Toward the end of the light period the nucleoids were transformed into the form of threads interconnected with fine fibrils spreading throughout the chloroplast. Initially the thread-like nucleoids fluoresced only faintly. The fluorescence of some parts of the threadlike form became brighter over a period of 6 h; these nucleoids were divided into daughter chloroplasts during chloroplast division. Soon after chloroplast division, these thread-like nucleoids were transformed into about 20 granular forms, which were gradually combined to form about ten larger granular bodies in zoospores immediately prior to liberation from mother cells. Fixation of cells with glutaraldehyde at high concentrations or treatment of cells with protease significantly modified the profiles of DAPI-stained nucleoids. The different morphologies of chloroplast nucleoids are discussed in relation to changes in configuration of their protein components.     

The chloroplast nucleoids of the bundle sheath and mesophyll cells of Zea mays

Dimorphic chloroplasts of Zea mays L. cv. GH5004 from bundle sheath and mesophyll cells contained similar amounts of DNA, while bundle sheath chloroplasts contained twice the number of nucleoids compared to mesophyll chloroplasts. On average bundle sheath nucleoids were half the size of mesophyll nucleoids and contained half as much DNA. Electron microscope autoradiography of the chloroplasts showed that the nucleoid DNA is associated with the thylakoids and in the case of mesophyll chloroplasts preferentially with the grana. These observations suggest that the differences in nucleoid distribution may be due to differences in membrane morphology, with the small nucleoids of agranal bundle sheath chloroplasts being widely dispersed.     

Visualization of plastid nucleoids in situ using the PEND-GFP fusion protein

Plastid DNA is a circular molecule of 120-150 kbp, which is organized into a protein-DNA complex called a nucleoid. Although various plastids other than chloroplasts exist, such as etioplasts, amyloplasts and chromoplasts, it is not easy to observe plastid nucleoids within the cells of many non-green tissues. The PEND (plastid envelope DNA-binding) protein is a DNA-binding protein in the inner envelope membrane of developing chloroplasts, and a DNA-binding domain called cbZIP is present at its N-terminus. We made various PEND-green fluorescent protein (GFP) fusion proteins using the cbZIP domains from various plants, and found that they were localized in the chloroplast nucleoids in transient expression in leaf protoplasts. In stable transformants of Arabidopsis thaliana, PEND-GFP fusion proteins were also localized in the nucleoids of various plastids. We have succeeded in visualizing plastid nucleoids in various intact tissues using this stable transformant. This technique is useful in root, flower and pollen, in which it had been difficult to observe plastid nucleoids. The relative arrangement of nucleoids within a chloroplast was kept unchanged when the chloroplast moved within a cell. During the division of plastid, nucleoids formed a network structure, which made possible equal partition of nucleoids.     

Changes in distribution of nucleoids in developing and dividing chloroplasts and etioplasts ofArena sativa

Summary Nucleoid distribution in chloroplasts and etioplasts at the different developmental stages was examined with the first leaves ofAvena sativa by using a DNA-specific fluorescent probe, 46-diamidino-2-phenylindole (DAPI). In light-grown first leaves, three types of plastid nucleoid distribution were recognized. 1. Peripheral distribution in undeveloped chloroplasts which contain only a few thylakoids in the middle region of the leaf sheath. 2. Ring-like arrangement along the rim of developing and dividing young chloroplasts, of which grana were composed of four to eight layers of thylakoids, at the base of the leaf blade. The plane of the nucleoids' ring is in parallel with the face of the thylakoids. 3. Scattered distribution of 10 to 20 discrete spherular nucleoids in the stroma of fully developed chloroplasts, of which grana were composed of up to 20 thylakoids, in the regions of the middle and the tip of the leaf blade. In dark-grown first leaves two types were recognized. 1. Peripheral distribution in developing and dividing young etioplasts in the leaf sheath and the base of the leaf blade. 2. Scattered distribution of 10 or more discrete spherular nucleoids in fully developed etioplasts, containing extended prothylakoids, in the regions of the middle and the tip of the leaf blade. Ring-like arrangement of nucleoids was not observed in any etioplasts. The results indicates that spatial arrangement of plastid nucleoids dynamically changes in close relationship with the development of the inner membrane systems of plastids.     

Chloroplast nucleoids are highly dynamic in ploidy,number, and structure during angiosperm leaf development

Chloroplast nucleoids are large, compact nucleoprotein structures containing multiple copies of the plastid genome. Studies on structural and quantitative changes of plastid DNA (ptDNA) during leaf development are scarce and have produced controversial data. We have systematically investigated nucleoid dynamics and ptDNA quantities in the mesophyll of Arabidopsis, tobacco, sugar beet, and maize from the early post‐meristematic stage until necrosis. DNA of individual nucleoids was quantified by DAPI‐based supersensitive epifluorescence microscopy. Nucleoids occurred in scattered, stacked, or ring‐shaped arrangements and in recurring patterns during leaf development that was remarkably similar between the species studied. Nucleoids per organelle varied from a few in meristematic plastids to >30 in mature chloroplasts (corresponding to about 20–750 nucleoids per cell). Nucleoid ploidies ranged from haploid to >20‐fold even within individual organelles, with average values between 2.6‐fold and 6.7‐fold and little changes during leaf development. DNA quantities per organelle increased gradually from about a dozen plastome copies in tiny plastids of apex cells to 70–130 copies in chloroplasts of about 7 μm diameter in mature mesophyll tissue, and from about 80 plastome copies in meristematic cells to 2600–3300 copies in mature diploid mesophyll cells without conspicuous decline during leaf development. Pulsed‐field electrophoresis, restriction of high‐molecular‐weight DNA from chloroplasts and gerontoplasts, and CsCl equilibrium centrifugation of single‐stranded and double‐stranded ptDNA revealed no noticeable fragmentation of the organelle DNA during leaf development, implying that plastid genomes in mesophyll tissues are remarkably stable until senescence.     

MORPHOLOGICAL CHANGES IN MITOCHONDRIAL AND CHLOROPLAST NUCLEOIDS AND MITOCHONDRIA DURING THE CHLAMYDOMONAS REINHARDTII (CHLOROPHYCEAE) CELL CYCLE1

Morphological changes in the organellar nucleoids and mitochondria of living Chlamydomonas reinhardtii Dang were examined during the cell cycle under conditions of 12:12 light:dark. The nucleoids were stained with SYBR‐Green I, and the mitochondria were stained with 3,3‐dihexyloxacarbocyanine iodide. An mocG33 mutant, which contains one large chloroplast nucleoid throughout the cell cycle, was used to distinguish between the mitochondrial and chloroplast nucleoids. Changes in the total levels of organellar DNA levels were assessed by real‐time PCR. Each of the G₁, S, M, and Smt,cp phases was estimated. At the start of the light period, the new daughter cells were in G₁ and contained about 30 mitochondrial and 10 chloroplast nucleoids, which were dispersed and had diameters of 0.1 and 0.2 μm, respectively. During the G₁ phase of the light period, and at the start of the S phase, both nucleoids formed short thread‐like or bead‐like structures, probably divided, and increased continuously in number, concomitantly with DNA synthesis. The nucleoids probably became smaller due to the decrease in DNA of each particle and were indistinguishable. The cells in the S and M phases contained extremely high numbers of scattered nucleoids. However, in the G₁ phase of the dark period, the nucleoids again formed short thread‐like or bead‐like structures, probably fused, and decreased in number. The mitochondria appeared as tangled sinuous structures that extended throughout the cytoplasm and resembled a single large mitochondrion. During the cell cycle, the numbers of mitochondrial nucleoids and sinuous structures varied relative to one another.     

Use of the fluorochrome 4''6-diamidino-2-phenylindole in genetic and developmental studies of chloroplast DNA

Use of the DNA-specific fluorochrome 4'6-diamidino-2-phenylindole (DAPI) makes it possible to examine in situ the structure of chloroplast DNA (chDNA) with the fluorescence microscope. This simplifies the study of genetic and developmental changes in chloroplast DNA. Three examples are presented. (a) Wild-type Euglena gracilis B contains several chloroplast DNA nucleoids per chloroplast. A yellow mutant lacking functional chloroplasts is similar, but such nucleoids are absent in an aplastidic mutant strain known from biochemical studies to have lost its chDNA. (b) In vegetative cells of the giant-celled marine algae Acetabularia and Batophora, only about a quarter of the chloroplasts have even one discernible chloroplast DNA particle, and such particles vary in size, showing a 30-fold variation in the amount of DNA-bound DAPI fluorescence detected per chloroplast. By contrast, 98% of chloroplasts in developing Acetabularia cysts contain chDNA, with as many as nine nucleoids per chloroplast. (c) DAPI-stained chloroplasts of chromophyte algae display the peripheral ring of DNA expected from electron microscope studies. However, these rings are not uniform in thickness, but are necklace-like, with the appearance of beads on a string. Since the multiple nucleoids in plastids of chlorophyte algae also appear to be interconnected throughout the chloroplast, a common structural plan may underlie chDNA morphology in both groups of algae.     

Isolation and phenotypic characterization ofChlamydomonas reinhardtii mutants defective in chloroplast DNA segregation

Summary Each wild-typeChlamydomonas reinhardtii cell has one large chloroplast containing several nuclei (nucleoids). We used DNA insertional mutagenesis to isolate Chlamydomonas mutants which contain a single, large chloroplast (cp) nucleus and which we namedmoc (monokaryotic chloroplast). DAPI-fluorescence microscopy and microphotometry observations revealed thatmoc mutant cells only contain one cp-nucleus throughout the cell division cycle, and that unequal segregation of cpDNA occurred during cell division in themoc mutant. One cell with a large amount of cpDNA and another with a small amount of cpDNA were produced after the first cell division. Unequal segregation also occurred in the second cell division, producing one cell with a large amount (about 70 copies) of cpDNA and three other cells with a small amount (only 2–8 copies) of cpDNA. However, most individualmoc cells contained several dozen cpDNA copies 12 h after the completion of cell division, suggesting that cpDNA synthesis was activated immediately after chloroplast division. In contrast to the cpDNA, the mitochondrial (mt) DNA of themoc mutants was observed as tiny granules scattered throughout the entire cell. These segregated to each daughter cell equally during cell division. Electron-microscopic observation of the ultrastructure ofmoc mutants showed that a low-electron-density area, which was identified as the cp-nucleus by immunoelectron microscopy with anti-DNA antibody, existed near the pyrenoid. However, there were no other structural differences between the chloroplasts of wild-type cells andmoc mutants. The thylakoid membranes and pyrenoid were identical. Therefore, we propose that the novelmoc mutants are only defective in the dispersion and segregation of cpDNA. This strain should be useful to elucidate the mechanism for the segregation of cpDNA.Abbreviations DAPI 4,6-diamidino-2-phenylindole - VIMPCS video-intensified microscope photon-counting system     

Division of chloroplast nucleoids and replication of chloroplast DNA during the cell cycle ofDunaliella salina grown under blue and red light

Summary Synchronous cultures of the algaDunaliella salina were grown in blue or red light. The relationships between replication of chloroplast DNA, cell size, cell age and the number of chloroplast nucleoids were studied. The replication of chloroplast DNA and the division of chloroplast nucleoids occurred in two separate periods of the chloroplast cycle. DNA replication was concomitant with that in the nucleocytoplasmic compartment but nucleoid division occurred several hours earlier than nuclear division. Red-light-grown cells were bigger and grew more rapidly than those grown in blue light. In newly formed daughter cells, the chloroplast nucleoids were small and spherical and they were localized around the pyrenoid. During the cell cycle they spread to other parts of the chloroplast. The number of DNA molecules per nucleoid doubled during DNA replication in the first third of the cell cycle but decreased several hours later when the nucleoids divided. Their number was fairly constant independent of the different light quality. Cells grown in red light replicated their chl-DNA and divided their nucleoids before those grown in blue light and their daughter cells possessed about 25 nucleoids as opposed to 15.Abbreviations DAPI 4,6-diamidino-2-phenylindole - chl-DNA chloroplast DNA - PAR photosynthetically active radiation     

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.     

Chloroplast DNA from three archegoniates

1. DNA from female and male Sphaerocarpos donnellii (liverwort) plants exhibits at least two species with buoyant densities of 1.703 (main band) and 1.691 (satellite) g cm^-3 in CsCl equilibrium gradients. At least part, if not all, of the satellite DNA is localized in plastids. It consists of up to 90% of uniformly sized circular molecules of an average circumference of 38.5 m. Compared to other Chlorophyta, the liverwort's cpDNA is unusually low both in diensity and contour length. — 2. On the hand, cpDNA from the ferns Asplenium nidus and Pteris vittata resembles those of higher plants in buoyant density (1.697 g cm^-3) and circumference (about 44.8 m). — 3. Analysis of DNA from the archegoniate chloroplasts with restriction endonucleases indicates chat the cyclic molecules are monomers. — 4. The results show that the circular molecules found in cpDNA of higher plants do not represent the functionally required minimum size of DNA in plastids.Abbreviations cpDNA chloroplast - DNA nucDNA=nuclear - DNA Sal I=restriction endonuclease from Streptomyces albus S - Eco RI restriction endonuclease from Escherichia coli, carrying resistance factor 1 - DTT dithiothreitol (Cleland's reagent) - Saline-EDTA 0.15 M NaCl, 0.1 M ethylene diamine tetraacetic acid, pH 8.0 - SSC 0.15 M NaCl, 0.015 M Na citrate, pH 7.2 - DNAase deoxyribonuclease - Md Megadalton Dedicated to the memory of Prof. Dr. Edgar Knapp     

Multiplication and Differentiation of Plastid Nucleoids during Development of Chloroplasts and Etioplasts from Proplastids in Triticum aestivum

The morphological changes of plastid nucleoids (pt nucleoids)in the shoot apex and along the axis of the leaf blade in Triticumaestivum L. cv. Asakaze were followed with fluorescence microscopyafter staining with 4'6-diamidino-2-phenylindole (DAPI) andquantified with supersensitive microspectrophotometry. Proplastidsin the shoot apex contained 1–10 spherical pt nucleoids.These pt nucleoids changed to a row of spherical and cup-shapedpt nucleoids in sausage-shaped plastids at the leaf base inboth dark and light conditions, in which active cell divisionwas observed. These structures have a higher copy number ofplastid DNA (pt DNA) (72–78 copies) compared to proplastidsin the shoot apex (32–45 copies) and, therefore, may reflectthat active pt DNA synthesis is in progression. In the dark,the cup-shaped pt nucleoids in the spherical etioplasts, whichoriginated from the sausage-shaped plastids, grew to form ring-shapedpt nucleoids. Each ring-shaped pt nucleoid is sub-divided intosmaller pt nucleoids. Under continuous illumination, similarmorphological changes of pt nucleoids occurred except for distributionof small pt nucleoids into young chloroplasts as well as inmature chloroplasts. However, pt nucleotids of leucoplasts inepidermal and vascular bundle sheath cells did not show conspicuouschanges along the axis of the leaf blade. The significance ofthese observations is discussed in relation to plastid differentiationand to the plastid division cycle. ⁴ Present address: Faculty of Science, University of Tokyo,Hongo, Bunkyo-ku, Tokyo, 113 (Received August 15, 1989; Accepted April 13, 1990)     

STRUCTURAL ORGANIZATION OF PLASTID DNA IN TWO ANOMALOUSLY PIGMENTED DINOFLAGELLATES1

The structural organization of DNA in the plastids of two anomalously pigmented dinoflagellates, Glenodinium foliaceum Stein and Gyrodinium aureolum Hulburt, was determined using the DNA-specific fluorochrome DAPI and correlated with TEM observations. The plastids of G. foliaceum were found to possess both a peripheral DNA ring and isolated point nucleoids. This arrangement was shown to be similar to that of the diatom Asterionella formosa Hass. and may be characteristic of the Bacillariophyceae. G. aureolum exhibited a novel distribution of plastid. DNA as one or two beaded bands, whereas the plastids of the similarly pigmented haptophyte, Emiliania huxleyi (Lohm.) Hay & Mohler, possessed scattered point nucleoids. These findings support the idea that G. foliaceum harbours an endosymbiotic diatom, but suggest that the plastids of G. aureolum and E. huxleyi are unrelated. The use of plastid DNA configuration as a phylogenetic marker is considered.     

MORPHOLOGY OF DNA CONTAINING STRUCTURES (NUCLEOIDS) AS A PROSPECTIVE CHARACTER IN CYANOPHYTE TAXONOMY1

DNA containing structures (nucleoids) were visualized by 4′, 6-diamidino-2-phenylindole (DAPI) fluorescent staining in two groups of cyanophytes (59 filamentous oscillatorialean species and 12 coccal Synechococcus-like organisms) to test the possibility of using nucleoid morphology in cyanophyte taxonomy. The morphology of nucleoids (size, shape, and structure) in oscillatorialean species is specific for individual families. The morphology of the nucleoid in Synechococcus-like species agrees from the proposed separation of the genus Cyanothece from Synechococcus. A much different nucleoid morphology in three species of Cyanothece suggests that these species should be separated into a new genus. On the basis of other characters, the species could be returned to the genus Cyanobacterium. My results indicate that the morphology of nucleoids is a valuable character in the classification of the cyanophytes examined; thus, it is a prospective feature that could be used in the taxonomy of other groups of cyanophytes. Additionally, DAPI staining is not a complicated procedure. The new character is easy to see in samples taken from nature, both living and preserved.     

The 68 kDa DNA compacting nucleoid protein from soybean chloroplasts inhibits DNA synthesis in vitro

Nucleoids were purified from chloroplasts of dividing soybean cells and their polypeptide composition analyzed by SDS-polyacrylamide gel electrophoresis. Of the 15–20 nucleoid-associated polypeptides, several demonstrated DNA binding activity. Upon disruption of the nucleoids with high concentrations of NaCl, a subset of these proteins and the majority of chloroplast DNA were recovered in the supernatant after centrifugation. Removal of the salt by dialysis resulted in formation of nucleoprotein complexes resembling genuine nucleoids. Purification of these structures revealed three major proteins of 68, 35 and 18 kDa. After purification of the 68 kDa protein to homogeneity, this protein was able to compact purified chloroplast DNA into a nucleoid-like structure in a protein concentration-dependent fashion. Addition of the 68 kDa protein to an in vitro chloroplast DNA replication system resulted in complete inhibition of nucleotide incorporation at concentrations above 300 ng of 68 kDa protein per g of template DNA. These results led to in situ immunofluorescence studies of chloroplasts replicating DNA which suggested that newly synthesized DNA is not co-localized with nucleoids. Presumably, either the plastid replication machinery has means of removing nucleoid proteins prior to replication or the concentration of nucleoid proteins is tightly regulated and the proteins turned over in order to allow replication to proceed.     

CYANOPHYTE AND CYANELLE DNA: A SEARCH FOR THE ORIGINS OF PLASTIDS1

Cyanophyte-like prokaryotes are widely presumed to be the progenitors of eukaryote plastids. A few rare protistan species bearing cyanophyte-like cyanelles may represent intermediate stages in the evolution of true organelles. Cyanophyte DNA disposition in the cell, so far as is known from electron microscopy, seems uniform within the group and distinctly different from the several known arrangements of DNA in plastids. Therefore a survey of representative cyanophytes and protistan cyanelles was undertaken to determine whether forms reminiscent of plastids could be found. DNA-specific fluorochromes were utilized, along with epifluorescent microscopy, to study the DNA arrangement in situ in whole cells. Only the endospore (baeocyte)-forming Cyanophyta contained more than one, centrally located DNA skein per cell, and then only for the period just preceding visible baeocyte formation. Such forms might, with modification, presage the “scattered nucleoid” DNA disposition found in plastids of several groups, including Rhodophytes, Cryptophytes, Chlorophytes and higher plants. The DNA arrangement in cyanelles of two protists, Cyanophora and Glaucocystis, appear different from each other and possibly related to, respectively, the cyanophytes Gloeobacter and Synechococcus. Cyanelles of the third protist, Glaucosphaera, like the cells of the unique prokaryote Prochloron, appear to have multiple sites of DNA, somewhat similar to those of the “scattered nucleoid” line of plastid evolution. No obvious precursor of the “ring nucleoid” or other types of plastid DNA conformation was found.