Cell size and chloroplast size in relation to chloroplast replication in light-grown wheat leaves

As part of an investigation into the control of chloroplast replication the number and size of chloroplasts in mesophyll cells was examined in relation to the size of the cells. In first leaves of Triticum aestivum L. and T. monococcum L. the number of chloroplasts in fully expanded mesophyll cells is positively correlated with the plan area of the cells. The linear relationship between chloroplast number per cell and cell plan area is also consistent over a fivefold range of cell size in isogenic diploid and tetraploid T. monococcum. In T. aestivum the chloroplast number per unit cell plan area varies among cells in relation to the size of the chloroplasts. Those cells containing chloroplasts with a relatively small face area have a correspondingly higher density of chloroplasts, and consequently, the total chloroplast area per unit cell plan area is very similar in all the cells. The results indicate that the proportion of the cell surface area covered by chloroplasts is precisely regulated, and that this is achieved during cell development by growth and replication of the chloroplasts.     

Constancy of organellar genome copy numbers during leaf development and senescence in higher plants

In higher plants, plastid and mitochondrial genomes occur at high copy numbers per cell. Several recent publications have suggested that, in higher plants like Arabidopsis and maize, chloroplast DNA is virtually absent in mature and old leaves. This conclusion was mainly based on DAPI staining of isolated chloroplasts. If correct, the finding that chloroplasts in mature leaves lack DNA would change dramatically our understanding of gene expression, mRNA stability and protein stability in chloroplasts. In view of the wide implications that the disposal of chloroplast DNA during leaf development would have, we have reinvestigated the age dependency of genome copy numbers in chloroplasts and, in addition, tested for possible changes in mitochondrial genome copy number during plant development. Analyzing chloroplast and mitochondrial DNA amounts in Arabidopsis and tobacco plants, we find that organellar genome copy numbers remain remarkably constant during leaf development and are present in essentially unchanged numbers even in the senescing leaves. We conclude that, during leaf development, organellar gene expression in higher plants is not significantly regulated at the level of genome copy number and we discuss possible explanations for the failure to detect DNA in isolated chloroplasts stained with DAPI.     

The control of chloroplast number in wheat mesophyll cells

Chloroplast number per cell and mesophyll cell plan area were determined in populations of separated cells from the primary leaves of different wheat species representing three levels of ploidy. Mean chloroplast number per cell increases with ploidy level as mean cell size increases. But in addition the analysis of individual cells clearly shows that cells of a similar size but from species of different ploidies have similar numbers of chloroplasts. We conclude that the number of chloroplasts within a cell is closely correlated (P<0.001) with the size of the cell and this relationship is consistent for species of different ploidies over a wide range of cell sizes. These results are discussed in relation to the hypothesis that chloroplast number in leaf mesophyll cells is determined by the size of the cell.     

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     

Changes in mitochondrial DNA levels during development of pea (Pisum sativum L.)

The percentage of mitochondrial DNA (mtDNA) present in total DNA isolated from pea tissues was determined using labeled mtDNA in reassociation kinetics reactions. Embryos contained the highest level of mtDNA, equal to 1.5% of total DNA. This value decreased in light- and dark-grown shoots and leaves, and roots. The lowest value found was in dark-grown shoots; their total DNA contained only 0.3% mtDNA. This may be a reflection of increased nuclear ploidy levels without concomitant mtDNA synthesis. It was possible to compare the mtDNA values directly with previous estimates of the amount of chloroplast DNA (ctDNA) per cell because the same preparations of total DNA were used for both analyses. The embryo contained 1.5% of both mtDNA and ctDNA; this equals 410 copies of mtDNA and 1200 copies of ctDNA per diploid cell. Whereas mtDNA levels decreased to 260 copies in leaf cells of pea, the number of copies of ctDNA increased to 10300. In addition, the levels of ctDNA in first leaves of dark-grown and light-transferred pea were determined, and it was found that leaves of plants maintained in the dark had the same percentage of ctDNA as those transferred to the light.Abbreviations ctDNA chloroplast DNA - mtDNA mitochondrial DNA     

Degradation of chloroplast DNA in second leaves of rice (Oryza sativa) before leaf yellowing

Summary The second leaf ofOryza sativa develops, grows and ages within the 10 days that follow imbibition under our controlled continuous-light conditions. Proplastids in the leaf cells develop, mature to become chloroplasts and then age and disintegrate. In an examination of this life process, we studied first the behavior and the number of copies of plastid DNA and levels of chlorophyll by epifluorescence microscopy after staining with 4,6-diamidino-2-phenylindole (DAPI), and by fluorimetry with a video-intensified microscope photon-counting system (VIMPCS). The results indicated that the number of copies of the plastid DNA per plastid increased and reached to plateau value of approximately 100 at the time when the elongation of the mesophyll cells and the enlargement of chloroplasts ceased 96 h after imbibition. However, 24 h later, the number of copies of plastid DNA per chloroplast began to decrease and fell rapidly to approximately 30 copies within 168 h after imbibition. Our examination of the number of chloroplasts per mesophyll cell indicated that no division of chloroplasts occurred more than 72 h after imbibition. The results suggest that the decrease in number of copies of plastid DNA per chloroplast was not due to an increase in the number of chloroplasts, but that this decrease was caused by degradation by unidentified enzymes. Since visible senescence of leaves, which was characterized by development of a yellowish color, began 168 h after imbibition, the degradation of plastid DNA seemed to occur 48 h before the visible leaf senescence. When we tested the nucleolytic activities in the second leaves after imbibition by digestion of plasmids in vitro and DNA-SDS polyacrylamide gel electrophoresis, five Ca²⁺–, four Zn²⁺–, and four Mn²⁺–dependent nucleases were detected in the leaf blades, and one of the Ca²⁺–, two of the Zn²⁺–, and two of the Mn²⁺–dependent nucleases were also identified in a purified preparation of intact chloroplasts. When the activity of the Zn²⁺–dependent nucleases (51 kDa and 13 kDa) increased markedly, degradation of the plastid DNA occurred. These results suggest that the destruction of chloroplast DNA, which occurs approximately 48 h before leaf yellowing, could be due to the activation of some metallo-nucleases and, furthermore, this enzymatic degradation propels the leaf towards senescence.     

Preferential digestion of chloroplast nuclei (nucleoids) during senescence of the coleoptile ofOryza sativa

Summary The coleoptile ofOryza sativa develops, grows and ages within 4 days that follow imbibition. It is, thus, a very useful system for experimental analysis of the life cycle of organelles, for example, the development, growth and aging of plastids in higher plants. We examined the behavior and levels of DNA and chlorophyll in the plastid by epifluorescence microscopy after staining with 4-6-diamidino-2-phenylindole (DAPI), and by fluorimetry with a video-intensified-photon counting system (VIMPCS). The whitish yellow coleoptile appeared soon after imbibition and, between the first 24 and 60 h that followed imbibition, it grew markedly in a longitudinal direction, with concomitant elongation of the cells, and an increase in the volume of plastids and in the amount of DNA in the plastids. The chlorophyll content per plastid began to increase when the coleoptile turned green, 48 h after imbibition, and reached a plateau value when the coleoptile was 3.5 mm in length, 72 h after imbibition. More than 12 h later, the chlorophyll disappeared just before the breakdown of chloroplasts was initiated. Proplastids in young coleoptiles, contained a plastid nucleus which was located in the central area of the plastids and each nucleus consisted of approximately 6 copies of plastid DNA (ptDNA). The number of copies of ptDNA per plastid increased gradually, with a concomitant increase in the volume of the plastids after imbibition, and reached approximately 130 times the value in the young proplastids, 60 h after imbibition, when the plastid developed into a chloroplast. However, each plastid nucleus did not scatter throughout the entire interior region of each chloroplast. The disappearance of each plastid nucleus occurred more than 12 h before the degeneration of the chloroplasts. The number of plastids per cell increased from 10 to 15 in young coleoptiles within 12 h after imbibition. Yet the number remained constant throughout subsequent growth and aging of the coleoptile. Thus the preferential reduction in the amount of chloroplast DNA was not due to the division of the plastid but could, perhaps, be associated directly with the aging of the cells of the coleoptile which precedes senescence of the coleoptiles.     

DNA Content of Beta vulgaris Chloroplasts during Leaf Cell Expansion

During the growth of beet leaves from 2 to 3 to 25 to 30 centimeters, the leaf cells increase in size, the average number of chloroplasts per cell increases from 11 to 65 and the amount of chloroplast DNA per cell increases from 1100 to 1900 plastome copies. The average number of copies of the plastome per chloroplast decreases from 104 in 2 to 3-centimeter leaves to 29 in 25 to 30-centimeter leaves during a period when the chloroplasts undergo two to three rounds of division and increase diameter from 1.5 to 4.9 micrometers. This result is at variance with previously published studies of beet chloroplasts but agrees with the conclusions reached in more recent studies of pea and spinach and wheat leaf cell expansion.     

Dismantling of Arabidopsis thaliana mesophyll cell chloroplasts during natural leaf senescence

One of the earliest events in the process of leaf senescence is dismantling of chloroplasts. Mesophyll cell chloroplasts from rosette leaves were studied in Arabidopsis thaliana undergoing natural senescence. The number of chloroplasts decreased by only 17% in fully yellow leaves, and chloroplasts were found to undergo progressive photosynthetic and ultrastructural changes as senescence proceeded. In ultrastructural studies, an intact tonoplast could not be visualized, thus, a 35S-GFP::δ-TIP line with a GFP-labeled tonoplast was used to demonstrate that chloroplasts remain outside of the tonoplast even at late stages of senescence. Chloroplast DNA was measured by real-time PCR at four different chloroplast loci, and a fourfold decrease in chloroplast DNA per chloroplast was noted in yellow senescent leaves when compared to green leaves from plants of the same age. Although chloroplast DNA did decrease, the chloroplast/nuclear gene copy ratio was still 31:1 in yellow leaves. Interestingly, mRNA levels for the four loci differed: psbA and ndhB mRNAs remained abundant late into senescence, while rpoC1 and rbcL mRNAs decreased in parallel to chloroplast DNA. Together, these data demonstrate that, during senescence, chloroplasts remain outside of the vacuole as distinct organelles while the thylakoid membranes are dismantled internally. As thylakoids were dismantled, Rubisco large subunit, Lhcb1, and chloroplast DNA levels declined, but variable levels of mRNA persisted.     

Chloroplast division in cultured cells of the hornwortAnthoceros punctatus

Using cultured cells of the hornwortAnthoceros punctatus, the change in the relative chloroplast DNA content in each stage of chloroplast division was investigated to clarify the relationship between the division cycle of a chloroplast and a cell nucleus. Samples of cultured cells were stained with 4′,6-diamidino-2-phenylindole (DAPI) and then observed with an epifluorescence microscope and a chromosome image analyzing system (CHIAS). A chloropiast in cultured cells duplicated DNA with an increase in size. When a chloroplast began to divide, it was constricted in the middle, taking a dumbbell shape, and then divided into two daughter chloroplasts. In cultured cells of this species, the pattern of quantitative change of chloroplast DNA, that is, the DNA replication pattern of chloroplasts, corresponded to that of cell nuclear DNA in mitosis.     

Chloroplast DNA in Expanding Spinach Leaves

The proportion of chloroplast DNA in total DNA from spinachleaves has been measured using the second order reassociationkinetics of a ³H-labelled chloroplast DNA probe in total DNAextracts. There was no significant difference between the proportionof chloroplast DNA in the basal and distal halves of 2 cm leavesand in the distal halves of 5, 8, and 10 cm leaves. The meanof all the observations was 21.1 ± 0.7%. There was littlechange in the average total DNA content of cells from any ofthe leaves but cells from larger leaves contained 130–170chloroplasts while cells from the basal half of 2 cm leavescontained about 20 chloroplasts which were smaller than thosefrom the larger leaves. Consequently the average number of copiesof the plastome per chloroplast in large leaves was about 30(5 x 10^–15 g DNA) and in the smaller chloroplasts in thebase of 2 cm leaves was 200 (32 x 10^–15 g DNA). Stainingwith the DNA fluorochrome 4, 6-diamidino-2 phenyl indole (DAPI)showed 10–15 plastid nucleoid areas in chloroplasts oflarger leaves, suggesting there are 2–3 copies of theplastome per plastid nucleoid.     

THE LACK OF CHLOROPLAST DNA IN ACETABULARIA MEDITERRANEA (ACETABULUM) (CHLOROPHYCEAE): A REINVESTIGATION1

Three features of chloroplast DNA (cpDNA) in plastids isolated from Acetabularia mediterranea (acetabulum) were analyzed after staining the organelles with the fluorochrome 4′6-diamidino-2-phenyl indole (DAPI): (1) number of chloroplasts exhibiting DNA fluorescence, (2) number of nucleoids per plastid, and (3) nucleoid morphology. In vegetative Acetabularia cells only half of the total chloroplast population comprising several millions displayed the whitish-blue fluorescence of the DNA/DAPI complex. This percentage remained stable independent of whether cells were grown in supplemented natural sea water or enriched synthetic sea water. A single nucleoid, widely differing in size and morphology among the organelles, was characteristic of 76–81% of chloroplasts with DNA. Less than 20% contained two nucleoids, and in rare cases three or four nucleoids were present. The pattern of nucleoid numbers followed a Poisson distribution in one experiment, if calculated with the intrinsic mean of the observed data. In two other experiments, however, a significant difference existed between observed and expected values for a Poisson distribution according to the Chisquared test. After secondary enlargement of portions of the negatives, the nucleoids’substructure was disclosed and found to consist of brightly fluorescent spots interspersed by unstained regions The lack of cpDNA in Acetabularia cells appears to be brought about by (1) the polarized pattern of growth and translation confined to the apical region of the single cell and (2) the cpDNA arrangement in a single nucleoid acentrically located in the organelle. A scheme for the evolution of a chloroplast population having plastids without DNA is proposed. In theory the lack of cpDNA could arise in each plant, since chloroplasts never evolved a mitotic-like spindle to ensure the equal distribution of genetic material. The different nucleoid arrangement in most other plants, however, efficiently counteracts this ‘carelessness of nature’     

Changes in chloroplast DNA during development in tobacco, Medicago truncatula, pea, and maize

We examined the DNA from chloroplasts obtained from young and fully expanded leaves of tobacco (Nicotiana tabacum L.), Medicago truncatula, pea (Pisum sativum L.), and maize (Zea mays L.). The changes in plastid DNA content and structure were monitored by four independent methods: 4′,6-diamidino-2-phenylindole (DAPI) staining with intact chloroplasts, in situ DAPI staining of cytological sections, ethidium bromide staining at the single-molecule level after exhaustive deproteinization of lysed chloroplasts, and pulsed-field gel electrophoresis. During leaf development, we found a decline of chloroplast DNA (cpDNA) in all four plants. For tobacco, for which plants can readily be regenerated from somatic cells, cpDNA persisted longer than in the other three plants. We also found a striking progression from complex multigenomic DNA molecules to simple subgenomic molecules during plastid development. Although the decrease in molecular size and complexity paralleled the decrease in DNA content per plastid, 6% of the chloroplasts in a fully expanded tobacco leaf still contained DNA in complex branched structure, whereas no such complex structures were found in mature leaves for the hard-to-regenerate maize.     

Chloroplast proliferation based on their distribution and arrangement inAdiantum protonemata growing under red light

Chloroplast proliferation was investigated inAdiantum protonemata growing under continuous red light. Cell division is absent when cells are grown under red light. The chloroplast number increases as the cell length increases, therefore the chloroplasts divide in the absence of cell division. Chloroplasts in the basal part of the filamentous protonemal cell migrate gradually toward the cell apex, but there is no large net migration from the tip to the base or vice versa, indicating that chloroplast division takes place in the apical part of the protonemata. Chloroplast number in the apical 100 μm was maintained at about 200 during cell growth at least over eight days. The chloroplasts were either dumbbell- or ellipsoid-shaped. Dumbbell-shaped chloroplasts are abundant everywhere in a protonema, ranging from 30 to 50% of the total chloroplasts. The dumbbell-shaped chloroplasts attached to or very close to the plasma membrane seem to be the ones that are dividing but the dumbbell-shaped ones in the other regions do not divide. These data support the hypothesis that a signal from the plasma membrane induces the dumbbell-shaped chloroplasts to divide.     

Some factors affecting the chloroplast replication in the mossPlagiomnium trichomanes

Summary Some factors affecting the chloroplast replication were studied using the leaf cells of the mossPlagiomnium trichomanes. There was a significant positive correlation between chloroplast number per cell and cell volume in leaves of any developmental stage. However, when the detached leaves were cultured on nutrient agar, it was observed that the chloroplast replication occurred without cell enlargement regardless of the developmental stage of leaves. This implies that cell enlargement is not an essential factor for the chloroplast replication, but one of the environmental factors affecting it. Light is essential for the chloroplast replication which response to the light intensity. In the dark, there was little increase in chloroplast number per cell. With a light intensity of 50 lux, the increase rate of chloroplast number per cell was about half of that with 3,000 lux. Day length also affected significantly the chloroplast replication.     

Copy numbers of chloroplast and nuclear genomes are proportional in mature mesophyll cells of Triticum and Aegilops species

The possibility of estimating the proportion of chloroplast DNA (ctDNA) and nuclear DNA (nDNA) in nucleic-acid extracts by selective digestion with the methylation-sensitive restriction enzyme PstI, was tested using leaf extracts from Spinacia oleracea and Triticum aestivum. Values of ctDNA as percentage nDNA were estimated to be 14.58%±0.56 (SE) in S. oleracea leaves and 4.97%±0.36 (SE) in T. aestivum leaves. These estimates agree well with those already reported for the same type of leaf material. Selective digestion and quantitative dot-blot hybridisation were used to determine ctDNA as percentage nDNA in expanded leaf tissue from species of Triticum and Aegilops representing three levels of nuclear ploidy and six types of cytoplasm. No significant differences in leaf ctDNA content were detected: in the diploids the leaf ctDNA percentage ranged between 3.8% and 5.1%, and in the polyploids between 3.5% and 4.9%. Consequently, nuclear ploidy and nDNA amount were proportional to ctDNA amount (r₍₁₉₎=0.935, P>0.01) and hence to ctDNA copy number in the mature mesophyll cells of these species. There was a slight increase in ctDNA copy numbers per chloroplast at higher ploidy levels. The balance between numbers of nuclear and chloroplast genomes is discussed in relation to polyploidisation and to the nuclear control of ctDNA replication.Abbreviations ctDNA chloroplast DNA - nDNA nuclear DNA - RuBPCase ribulose-1,5-bisphosphate carboxylase - DAPI 4,6-diamidine-2-phenylindole     

Nuclear DNA content and the control of chloroplast replication in wheat leaves

During development of the first leaf of breadwheat (Triticum aestivum L.) the number of chloroplasts per mesophyll cell increases between three- and four-fold. To establish if chloroplast replication is accompanied by endoreduplication, the nuclear DNA content of the cells was determined by chemical assay of isolated nuclei from mesophyll protoplasts and by microdensitometry of nuclei in mesophyll tissue. The DNA content of the nuclei was constant (27 to 32 pg) at each phase of chloroplast replication. Approximately 93% of the cells had a nuclear DNA content close to the 2C value of 32 pg. It is concluded that chloroplast replication is not dependent on nuclear endoreduplication in seedling leaves of wheat.     

Tobacco-mosaic-virus-induced increase in abscisic-acid concentration in tobacco leaves:

The concentrations of free and bound abscisic acid (ABA and the presumed ABA glucose ester) increased three- to fourfold in leaves of White Burley tobacco (Nicotiana tabacum L.) systemically infected with tobacco mosaic virus. Infected leaves developed a distinct mosaic of light-green and dark-green areas. The largest increases in both free and bound ABA occurred in dark-green areas. In contrast, virus accumulated to a much higher concentration in light-green tissue. Free ABA in healthy leaves was contained predominantly within the chloroplasts while the majority of bound ABA was present in non-chloroplastic fractions. Chloroplasts from light-green or dark-green tissues were able to increase stromal pH on illumination by an amount similar to chloroplasts from healthy leaf. It is unlikely therefore that any virus-induced diminution of pH gradient is responsible for increased ABA accumulation. Tobacco mosaic virus infection had little effect on free ABA concentration in chloroplasts; the virus-induced increase in free ABA occurred predominantly out-side the chloroplast. The proportional distribution of bound ABA in the cell was not changed by infection. Treatment of healthy plants with ABA or water stress increased chlorophyll concentration by an amount similar to that induced by infection in dark-green areas of leaf. A role for increased ABA concentration in the development of mosaic symptoms is suggested.Abbreviations ABA abscisic acid - TMV tobacco mosaic virus     

Loss or retention of chloroplast DNA in maize seedlings is affected by both light and genotype

We examined the chloroplast DNA (cpDNA) from plastids obtained from wild type maize (Zea mays L.) seedlings grown under different light conditions and from photosynthetic mutants grown under white light. The cpDNA was evaluated by real-time quantitative PCR, quantitative DNA fluorescence, and blot-hybridization following pulsed-field gel electrophoresis. The amount of DNA per plastid in light-grown seedlings declines greatly from stalk to leaf blade during proplastid-to-chloroplast development, and this decline is due to cpDNA degradation. In contrast, during proplastid-to-etioplast development in the dark, the cpDNA levels increase from the stalk to the blade. Our results suggest that DNA replication continues in the etioplasts of the upper regions of the stalk and in the leaves. The cpDNA level decreases rapidly, however, after dark-grown seedlings are transferred to light and the etioplasts develop into photosynthetically active chloroplasts. Light, therefore, triggers the degradation of DNA in maize chloroplasts. The cpDNA is retained in the leaf blade of seedlings grown under red, but not blue light. We suggest that light signaling pathways are involved in mediating cpDNA levels, and that red light promotes replication and inhibits degradation and blue light promotes degradation. For five of nine photosynthetic mutants, cpDNA levels in expanded leaves are higher than in wild type, indicating that nuclear genotype can affect the loss or retention of cpDNA.