Ploidy effects in isogenic populations of alfalfa : I. Ribulose-1,5-bisphosphate carboxylase, soluble protein, chlorophyll, and DNA in leaves

The influence of polyploidization on ribulose-1,5-bisphosphate carboxylase (RuBPCase), buffer-soluble protein (BSP), chlorophyll (Chl), and DNA was examined in fully expanded leaves of isogenic diploid-tetraploid (DDC 2X-4X) and tetraploid-octoploid (IC 4X-8X) sets of alfalfa (Medicago sativa L.). The concentration of RuBPCase in leaf extracts was determined by rocket immunoelectrophoresis. Activities of RuBPCase, expressed per milligram protein or per milligram Chl, and leaf tissue concentrations of RuBPCase, BSP, Chl, and DNA were similar between ploidy levels of the DDC 2X-4X set. Tetraploids and octoploids were similar in RuBPCase activities, expressed per milligram protein or per milligram Chl, and in leaf tissue concentrations of RuBPCase and DNA. Octoploids were significantly lower than tetraploids in concentrations of Chl and BSP.

When compared on a per leaf basis, tetraploids were 80% higher in BSP and essentially double comparable diploids in fresh weight, RuBPCase, Chl, and DNA. The observation that leaves of the DDC tetraploid population contain twice as much DNA as comparable diploids suggests that leaves of both ploidy levels contain similar numbers of cells. Leaves of the octoploid population were 33% to 80% higher than corresponding tetraploids in BSP, fresh weight, RuBPCase, Chl, and DNA. Ratios of RuBPCase to DNA and Chl to DNA were similar across ploidy levels of both isogenic sets suggesting that cellular content of Chl and RuBPCase increases proportionately with the amount of DNA per cell.

     

Ploidy Effects in Isogenic Populations of Alfalfa : III. Chloroplast Thylakoid-Bound Coupling Factor 1 in Protoplasts and Leaves

The influence of polyploidization on chloroplast coupling factor 1 (CF1) was examined in leaves and leaf protoplasts from isogenic diploid-tetraploid (DDC 2X-4X) and tetraploid-octoploid (IC 4X-8X) sets of alfalfa (Medicago sativa L.). Alfalfa CF1 was purified to homogeneity and was found to contain five subunits with molecular weights of 57,900, 54,300, 38,700, 23,100, and 15,200. Rocket immunoelectrophoresis with anti-spinach CF1 gamma immunoglobulins was used to quantify CF1 from protoplasts and leaves. In the DDC 2X-4X set, fresh weight per cell and cellular content of CF1, chlorophyll (Chl), and DNA doubled with ploidy. Ratios of CF1 to Chl of leaf protoplasts and leaves were similar between diploids and tetraploids. In the IC 4X-8X set, octoploid protoplasts were 90% higher in Chl than were comparable tetraploids, whereas octoploids were 50 to 60% higher than tetraploids in fresh weight per cell and cellular content of CF1 and DNA. Concentrations of CF1 and Chl in leaves and ratios of CF1 to DNA in protoplasts were similar across ploidy levels of both isogenic sets. Therefore, cellular content of CF1 increases proportionately with the amount of DNA per cell or gene dosage.     

Effects of Polyploidy on Photosynthetic Rates, Photosynthetic Enzymes, Contents of DNA, Chlorophyll, and Sizes and Numbers of Photosynthetic Cells in the C(4) Dicot Atriplex confertifolia

Photosynthetic rates, chlorophyll content, and activities of several photosynthetic enzymes were determined per cell, per unit DNA, and per unit leaf area in five ploidal levels of the C₄ dicot Atriplex confertifolia. Volumes of bundle sheath and mesophyll protoplasts were measured in enzymatic digestions of leaf tissue. Photosynthetic rates per cell, contents of DNA per cell, and activities of the bundle sheath enzymes ribulose 1,5-bisphosphate carboxylase (RuBPC) and NAD-malic enzyme per cell were correlated with ploidal level at 99% or 95% confidence levels, and the results suggested a near proportional relationship between gene dosage and gene products. There was also a high correlation between volume of mesophyll and bundle sheath cells and the ploidal level. Contents of DNA per cell, activity of RuBPC per cell, and volumes of cells were correlated with photosynthetic rate per cell at the 95% confidence level. The mesophyll cells did not respond to changes in ploidy like the bundle sheath cells. In the mesophyll cells the chlorophyll content per cell was constant at different ploidal levels, there was less increase in cell volume than in bundle sheath cells with an increase in ploidy, and there was not a significant correlation (at 95% level) of phosphoenolpyruvate carboxylase activity or content and pyruvate,Pi dikinase activity with increase in ploidy. The number of photosynthetic cells per unit leaf area progressively decreased with increasing ploidy from diploid to hexaploid, but thereafter remained constant in octaploid and decaploid plants. Numbers of cells per leaf area were not correlated with cell volumes. The mean photosynthetic rates per unit leaf area were lowest in the diploid, similar in 4×, 6×, and 8×, and highest in the decaploid. The photosynthetic rate per leaf area was highly correlated with the DNA content per leaf area.     

Effects of polyploidy on photosynthesis

In polyploid plants the photosynthetic rate per cell is correlated with the amount of DNA per cell. The photosynthetic rate per unit leaf area is the product of the rate per cell times the number of photosynthetic cells per unit area. Therefore, the photosynthetic rate per unit leaf area will increase if there is a less than proportional increase in cell volume at higher ploidal levels, or if cell packing is altered to allow more cells per unit leaf area. In autopolyploids (Medicago sativa, C₃ species, and Pennisetum americanum, C₄ species) there is a doubling of photosynthesis per cell and of cell volume in the tetraploid compared to the diploid. However, there is a proportional decrease in number of cells per unit leaf area with this increase in ploidy such that the rate of photosynthesis per leaf area does not change. There is more diversity in the relationship between ploidal level (gene dosage) and photosynthetic rates per unit leaf area in allopolyploids. This is likely to reflect the effects of natural selection on leaf anatomy, and novel genetic interactions from contributed genomes which can occur with allopolyploidy. In allopolyploid wheat (C₃ species) a higher cell volume per unit DNA at the higher ploidal level is negatively correlated with photosynthesis rate per unit leaf area. Although photosynthesis per cell increases with ploidy, photosynthesis per leaf area decreases, being lowest in the allohexaploid, cultivated bread wheat (Triticum aestivum). Alternatively, doubling of photosynthetic rate per cell with doubling of DNA, with apparent natural selection for decreased cell volume per unit DNA, results in higher rates of photosynthesis per leaf area in octaploid compared to tetraploid Panicum virgatum (C₄) which may be a case of allopolyploidy. Similar responses probably occur in Festuca arundinacea. Therefore, in some systems anatomical factors affecting photosynthesis are also affected by ploidal level. It is important to evaluate that component as well as determining the effect on biochemical processes. Current information on polyploidy and photosynthesis in several species is discussed with respect to anatomy, biochemistry and bases for expressing photosynthetic rates.Abbreviations Chl chlorophyll - RuBPC ribulose-1,5-bisphosphate carboxylase     

Effect of ploidy increase on transgene expression: example from <Emphasis Type="Italic">Citrus</Emphasis> diploid cybrid and allotetraploid somatic hybrid expressing the EGFP gene

Polyploidization is an important speciation mechanism for all eukaryotes, and it has profound impacts on biodiversity dynamics and ecosystem functioning. Green fluorescent protein (GFP) has been used as an effective marker to visually screen somatic hybrids at an early stage in protoplast fusion. We have previously reported that the intensity of GFP fluorescence of regenerated embryoids was also an early indicator of ploidy level. However, little is known concerning the effects of ploidy increase on the GFP expression in citrus somatic hybrids at the plant level. Herein, allotetraploid and diploid cybrid plants with enhanced GFP (EGFP) expression were regenerated from the fusion of embryogenic callus protoplasts from ‘Murcott’ tangor (Citrus reticulata Blanco × Citrus sinensis (L.) Osbeck) and mesophyll protoplasts from transgenic ‘Valencia’ orange (C. sinensis (L.) Osbeck) expressing the EGFP gene, via electrofusion. Subsequent simple sequence repeat (SSR), chloroplast simple sequence repeat and cleaved amplified polymorphic sequence analysis revealed that the two regenerated tetraploid plants were true allotetraploid somatic hybrids possessing nuclear genomic DNA of both parents and cytoplasmic DNA from the callus parent, while the five regenerated diploid plants were cybrids containing nuclear DNA of the leaf parent and with complex segregation of cytoplasmic DNA. Furthermore, EGFP expression was compared in cells and protoplasts from mature leaves of these diploid cybrids and allotetraploid somatic hybrids. Results showed that the intensity of GFP fluorescence per cell or protoplast in diploid was generally brighter than in allotetraploid. Moreover, same hybridization signal was detected on allotetraploid and diploid plants by Southern blot analysis. By real-time RT-PCR and Western blot analysis, GFP expression level of the diploid cybrid was revealed significantly higher than that of the allotetraploid somatic hybrid. These results suggest that ploidy level conversion can affect transgene expression and citrus diploid cybrid and allotetraploid somatic hybrid represents another example of gene regulation coupled to ploidy.     

Use of fluorescein diacetate (FDA) to determine ploidy of in vitro watermelon shoots

Ploidy of watermelon [Citrullus lanatus (Thunb.) Matsum. and Nakai shoots and plantlets was estimated by painting the lower epidermis of intact in vitro-derived leaves with fluorescein diacetate (FDA) and observing fluorescence of guard cell chloroplasts with a microscope and UV light. Leaves from in vitro shoot-tip cultures of known diploid cultivars and tetraploid breeding lines were used to establish the mean number of chloroplasts per guard cell pair. Leaves from diploid and tetraploid shoot cultures had 9.7 and 17.8 chloroplasts per guard cell pair, respectively. This method then was used to estimate the ploidy of shoots regenerated from cotyledon explants of the diploid cultivar Minilee. Approximately 11% of the 188 regenerated shoots were classified as tetraploid during in vitro culture. Putative tetraploids were transplanted to the field and self-pollinated. About 45% of tetraploids identified in vitro produced fruit and viable seed. Chloroplast counts of R₁ progeny were used to confirm their ploidy. All of the putative diploids were confirmed diploid and all putative tetraploids proved to be non-chimeric true breeding tetraploids. This revised version was published online in June 2006 with corrections to the Cover Date.     

Chromosome doubling via tuber disc culture in dihaploid potato as determined by confocal microscopy

Summary The potential of tuber disc culture for chromosome doubling was investigated in somaclonal populations of four dihaploid genotypes and one tetraploid cultivar of potato (Solanum tuberosum). Laser scanning confocal microscopy (LSCM) was used for rapid determination of the ploidy level based on the number of chloroplasts in stomatal guard cells of leaves. Factorial analysis of chloroplast number in 58 clones and two leaf types showed that somaclones were clearly divided in two groups. Clones with 5–7 chloroplasts per cell as observed in tuber derived diploid controls were classified as 2X (not doubled), while those with 9–14 chloroplasts resembled the tuber derived tetraploid controls and were considered 4X (doubled). A high frequency of spontaneous chromosome doubling, 42% – 50%, was detected in 3 dihaploid genotypes, whereas no doubling was observed in one of the dihaploids as well as the tetraploid cultivar Yukon Gold. Effects of leaf type on chloroplast number was also significant. The middle leaf showed significantly higher chloroplast number than the younger leaves.     

Variation in cellular ribulose-1,5-bisphosphate-carboxylase content in leaves of Triticum genotypes at three levels of ploidy

Ribulose-1,5-bisphosphate carboxylase/oxygenase (EC 1.1.39) (RuBPCase) was quantified using polyacrylamide-gel electrophoresis in whole 9-d-old first leaves of 14 genotypes of Triticum, and cellular RuBPCase levels calculated. Diploids, tetraploids and hexaploids were analysed and it was confirmed that the RuBPCase level per cell is closely related to ploidy in wheat. Inter-genotypic variation in RuBPCase levels per cell and per leaf were surveyed. It was found that the interactions between leaf size, cell size and RuBPCase levels result in small variations in RuBPCase levels per unit leaf area between genotypes.Abbreviation RuBPCase ribulose-1,5-bisphosphate carboxylase/oxygenase     

Induction of tetraploid poplar and black locust plants using colchicine: chloroplast number as an early marker for selecting polyploids in vitro

Tetraploid plants were produced by inducing chromosome doubling using colchicine in in vitro shoot tips of poplar and black locust clones. Many of the plants treated with colchicine showed modified morphological characteristics like stunted growth, thicker leaves and modified leaf morphology. The counting of chloroplast number in the epidermal guard cells of stomata was used for the rapid screening of tetraploids. The differences in mean chloroplast numbers between diploid and tetraploid plants were highly significant. For all plants tested, the tetraploid genotype had almost double the number of chloroplasts per guard cell compared to the diploid origin. Some plants were further analysed by flow cytometry to verify their ploidy status that was determined by chloroplast numbers. The results of this study demonstrated for the first time that chloroplast counting in poplar and black locust could be an effective and reliable method for pre-screening large numbers of plants for their ploidy level. The protocol might be applicable in a wide scope of breeding programs.     

Photosynthesis, Leaf Anatomy, and Cellular Constituents in the Polyploid C(4) Grass Panicum virgatum

Photosynthetic gas exchange, activities of six key C₄ cycle enzymes, amounts of soluble protein, chlorophyll, and DNA, and various leaf anatomical and structural features were measured in naturally occurring tetraploid and octaploid plants of the NAD-malic enzyme type C₄ grass Panicum virgatum L. On a leaf area basis, the photosynthetic rate and concentrations of DNA, soluble protein, and chlorophyll were 40 to 50% higher, and enzyme activities 20 to 70% higher in the octaploid than in the tetraploid. Photosynthetic cells in the octaploid were only 17 to 19% larger in volume, yet contained 33 to 38% more chloroplasts than cells in the tetraploid. On a per cell basis the contents of DNA, soluble protein, and chlorophyll, activities of carboxylating photosynthetic enzymes, and carbon assimilation rate were all doubled in octaploid compared with tetraploid cells. Since cellular volume did not double with genome doubling, cellular constituents were more concentrated in the cells of the octaploid. The influences of polyploidy were balanced between mesophyll and bundle sheath cells since the changes in physical and biochemical parameters with ploidy level were similar in both cell types. We conclude that photosynthetic activity in these two polyploid genotypes of P. virgatum is determined by enzyme activities and concentrations of biochemical constituents, and that selection for smaller cell volume has led to higher photosynthetic rates per unit leaf area in the octaploid. The ratio of DNA content to cellular volume is a major factor determining the concentrations of gene products in cells. The number of chloroplasts, however, is controlled more by cellular volume than by the number of nuclear chromosomes.     

Polyploidy and cellular mechanisms changing leaf size: comparison of diploid and autotetraploid populations in two species of Lolium

BACKGROUND AND AIMS: Growth and development of plant organs, including leaves, depend on cell division and expansion. Leaf size is increased by greater cell ploidy, but the mechanism of this effect is poorly understood. Therefore, in this study, the role of cell division and expansion in the increase of leaf size caused by polyploidy was examined by comparing various cell parameters of the mesophyll layer of developing leaves of diploid and autotetraploid cultivars of two grass species, Lolium perenne and L. multiflorum. METHODS: Three cultivars of each ploidy level of both species were grown under pot conditions in a controlled growth chamber, and leaf elongation rate and the cell length profile at the leaf base were measured on six plants in each cultivar. Cell parameters related to division and elongation activities were calculated by a kinematic method. KEY RESULTS: Tetraploid cultivars had faster leaf elongation rates than did diploid cultivars in both species, resulting in longer leaves, mainly due to their longer mature cells. Epidermal and mesophyll cells differed 20-fold in length, but were both greater in the tetraploid cultivars of both species. The increase in cell length of the tetraploid cultivars was caused by a faster cell elongation rate, not by a longer period of cell elongation. There were no significant differences between cell division parameters, such as cell production rate and cell cycle time, in the diploid and tetraploid cultivars. CONCLUSION: The results demonstrated clearly that polyploidy increases leaf size mainly by increasing the cell elongation rate, but not the duration of the period of elongation, and thus increases final cell size.     

Is There a Relationship between Infection by Rhizobia and Occurrence of Disomatic Nuclei in Nodules of Alfalfa (Medicago sativa L.)?

Cytological examination of nodules from diploid, tetraploid, and octoploid alfalfa (Medicago sativa L.) plants revealed that the proportion of nodule cells infected by rhizobia was not significantly affected by nuclear ploidy of the host plant. Flow cytometry was used to determine the influence of host plant nuclear ploidy on the nuclear ploidy of infected cells. In nodules from diploid plants, most of the nuclei were tetraploid, whereas in nodules from tetraploid plants, about half of the nodule nuclei were tetraploid and half were octoploid; in octoploid plants, most of the nodule nuclei were octoploid. The occurrence of disomatic nuclei was independent of infection of nodule cells by rhizobia, because diploid plants had mostly disomatic nodule nuclei, and octoploid plants had mostly monosomatic nodule nuclei, whereas all nodules maintained a constant proportion of infected to uninfected cells. These results do not support the earlier hypothesis that infected nodule cells contain disomatic nuclei.     

Photosynthetic and Photorespiratory Carbon Metabolism in Mesophyll Protoplasts and Chloroplasts Isolated from Isogenic Diploid and Tetraploid Cultivars of Ryegrass (Lolium perenne L.)

Photosynthetic ¹⁴CO₂ fixation, [¹⁴C]glycolate formation, and the decarboxylation of [1-¹⁴C]glycolate and [1-¹⁴C]glycine by leaf mesophyll protoplasts isolated from isogenic diploid and tetraploid cultivars of ryegrass (Lolium perenne L.) were examined. The per cent O₂ inhibition of photosynthesis in protoplasts from the tetraploid cultivar was less than that of the diploid line at both 21 and 49% O₂. Kinetic studies revealed that the K_m (CO₂) for photosynthesis by the diploid protoplasts was about twice that of the tetraploid line. In contrast, the K_i (O₂) for protoplast photosynthesis was similar in both cultivars, as was the potential for oxidizing glycolate and glycine to CO₂ via the photorespiratory carbon oxidation cycle. Although the maximal rates of glycolate accumulation by the isolated protoplasts in the presence of 21% O₂ and a glycolate oxidase inhibitor were similar in the two cultivars, the percentage of total fixed ¹⁴C entering the [¹⁴C]glycolate pool and the ratio of the rate of [¹⁴C]glycolate formation to ¹⁴CO₂ fixation at 21% O₂ and low pCO₂ were about two times greater in protoplasts and intact chloroplasts isolated from the diploid line compared to the tetraploid. These results fully support the recent observation that a doubling of ploidy in various ryegrass cultivars reduced the K_m (CO₂) of purified ribulose bisphosphate carboxylase-oxygenase by about one-half without affecting the K_i (O₂) (Garrett 1978 Nature 274: 913-915).     

Relationships between CO(2) Exchange Rates and Activities of Pyruvate,Pi Dikinase and Ribulose Bisphosphate Carboxylase, Chlorophyll Concentration, and Cell Volume in Maize Leaves

The relationships between CO₂-exchange rate (CER), DNA and chlorophyll (Chl) concentrations, pyruvate,Pi dikinase (PPDK) and ribulose bisphosphate carboxylase (RuBPCase) activities in ten maize (Zea mays L.) genotypes were investigated. The in vivo degrees of activation of PPDK and RuBPCase were estimated to make meaningful comparisons with CER. In leaves at a photosynthetic photon flux density (PPFD) of 720 micromoles per square meter per second, in vivo PPDK degree of activation was 80% of that of PPDK fully activated in vitro, whereas RuBPCase could not be further activated in vitro, suggesting that RuBPCase was fully activated in vivo. CER varied about 50% among the genotypes tested. Significant genetic differences were observed for the average weight of a cell (estimated by gram fresh weight per milligram DNA), but this character was not correlated with CER expressed on a fresh weight basis. CER was correlated with Chl concentration, and with estimates of the in vivo degree of activation of PPDK and RuBPCase. We concluded that in maize, CER is controlled by the metabolic components of photosynthesis rather than by membrane resistances to CO₂. If the latter factor were controlling CER, then smaller cells with higher amounts of exposed cell surface area per unit cell volume would have lower resistance to CO₂ diffusion, and therefore higher CER. When data were expressed on a DNA basis (proportional to a per cell basis), results indicated that larger cells (i.e. those with higher fresh weight per milligram DNA) have a higher content of Chl, and higher PPDK and RuBPCase activities, resulting in higher CER than in smaller cells.     

Hybridization of asporogenic strains of Hansenula polymorpha yeasts by protoplast fusion

Intrastrain and interstrain hybrids of different ploidy were produced by the fusion of protoplasts of Hansenula polymorpha haploid and diploid strains. The diploid hybrids were found to be stable in contrast to the triploid and tetraploid hybrids. The instability of the triploid and tetraploid states in Hansenula polymorpha was expressed in the elevated frequency of spontaneous formation of auxotrophic markers and in the decreased content of DNA per cell in the course of storage.     

Biochemical,morphological and flow cytometric evaluation of the effects of hexachlorobenzene on rat liver

This study investigated the ability of HCB (0.1% in the diet for 15 days) to cause early changes in the cellular ploidy of rat liver. Treatment caused marked hepatomegaly, increase of microsomal proteins and cytochrome P-450 content and reduction of hepatocyte microviscosity. Microscopic examination showed that the hepatocytes were enlarged, with hyaline cytoplasm and vacuoles. The size distribution of the isolated hepatocytes showed a larger percentage of bigger cells. Flow-cytometric DNA/protein analysis was performed on whole (fixed) cells and on nuclei. From the combined results of both analyses it was possible to exclude significant changes in the percentages of diploid, mononucleated tetraploid, binucleated tetraploid and octoploid hepatocytes. The DNA and protein content of each subpopulation remained unchanged. Our results suggest that HCB does not cause early diploidization of liver cells and that hepatomegaly and cytochrome P-450 induction seem not to be correlated with effects on total DNA and total protein contents.Abbreviations HCB hexachlorobenzene - PI propidium iodide - FITC fluorescein isothiocyanate - DN diploid nuclei - SN 2N-4N nuclei in S-phase - TN tetraploid nuclei - DC diploid cells - SDC 2N-4N diploid cells in S-phase - TC tetraploid cells - STC 4N-8N tetraploid cells in S-phase - OC octoploid cells - MDC mononucleated diploid cells - SMDC mononucleated diploid cells in S-phase - BOC binucleated octoploid cells - SBTC binucleated tetraploid cells in S-phase - BTC binucleated tetraploid cells - MTC mononucleated tetraploid cells.     

Determination of the ploidy level in chamomile (Chamomilla recutita (L.) Rausch.) strains rich in alpha-bisabolol

The present study aimed to identify morphological traits whose performance depends on plant ploidy in Chamomilla recutita. Flowerhead diameter, 100-flowerhead weight, 1000-seed weight, pollen grain diameter, stoma length, and number of chloroplasts per guard cell, were examined in 5 tetraploid and 5 diploid strains. Out of these traits, stoma length, number of chloroplasts per guard cell, 100-flowerhead weight, and 1000-seed weight, proved to be significantly higher in tetraploid than in diploid strains, and can be used for indirect identification of tetraploid and diploid genotypes in various developmental stages of this species.     

Microspectrophotometry of cell nuclei stained with the Feulgen reaction. IV. Formation of tetraploid nuclei in rat liver cells during postnatal growth

1. DNA contents of the individual parenchymal nuclei of rat livers during postnatal growth were estimated by microspectrophotometric apparatus, and different ploidy classes of nuclei were classified by their DNA contents. With the same material the total number of parenchymal nuclei in the liver was counted microscopically. 2. If the DNA content of nuclei encountered most frequently in several tissues represents the diploid class, the ploidy classes of the rat liver cell nuclei correspond to di-, tri-, tetra-, and octoploid, with the di- and tetraploid ones predominating considerably. 3. In suckling rats (below 25 gm. of body weight) the liver parenchyma is composed almost exclusively of cells with diploid nuclei, whereas in young rats (above 80 gm.), of tetraploid nuclei. In the growth stage between 25 and 80 gm., there is a remarkable replacement of the diploid nuclei by the tetraploid ones. However, in the liver of adult rats weighing more than 150 gm., any increase or decrease in the frequency of diploid and tetraploid nuclei is hardly observable. In such rats, the nuclear population of the liver parenchyma seems to reach a cell-ecological equilibrium which is considered to be a stable one. 4. It is shown that such nuclear populations and the total number of nuclei in a liver are controlled by the growth state, and not by the age. 5. The decrease in the total number of diploid nuclei and the increase in tetraploid nuclei in the growing livers of rats weighing from 40 up to 130 gm. can both be explained by the hypothesis that the tetraploid nuclei originate from the interphase diploid nuclei without involving mitosis. This hypothesis implies that mitosis is confined to the reproduction of diploid cells alone. 6. It is suggested that, in general, the synthesis of DNA does not necessarily result in the formation of visible mitotic chromosomes. 7. Mitotic time and generation time of diploid nuclei and the percentage of the tetraploidization from diploid nuclei are calculated and discussed.     

Ploidy of somatic embryos and the ability to regenerate plantlets in melon (Cucumis melo L.)

Summary The number of chromosomes in cells of callus, somatic embryos and regenerated plantlets during somatic embryogenesis were examined in two cultivars of melon (Cucumis melo L.). Somatic embryos were diploid (50.0%/32.1%), tetraploid (38.5%/57.5%) and octoploid (11.5%/10.4%) whereas in callus cells diploidy (41.9%/43.3%), tetraploidy (27.9%/25.8%), octoploidy (11.6%/15.5%) and a low frequency of other types of ploidy and aneuploidy were observed. Mixoploid somatic embryos were not observed. These results suggest that the somatic embryos were selectively differentiated from diploid, tetraploid and octoploid cells, and that endopolyploidization of cultured cells occurred before the start of cell division leading to somatic embryogenesis. The ratio of diploid to tetraploid (1.30/0.55) in somatic embryos was less than that in callus cells (1.50/1.68) while ratios of diploid to octoploid (4.35/3.09) and tetraploid to octoploid (3.35/5.52) in somatic embryos were greater than those in callus cells (3.61/2.80 and 2.40/1.67). Therefore, it appears that the ability of callus cell to differentiate into somatic embryos increases in the following order: octoploid < diploid < tetraploid. Regenerated plantlets were diploid (65.5%/55.1%) and tetraploid (34.5%/44.9%). No octoploid plantlets were observed. The ratio of diploid to tetraploid in regenerated plantlets (1.72/1.23) was greater than that in somatic embryos. Therefore, it appears that the ability of somatic embryos to develop into plantlets increases in the following order: octoploid < tetraploid < diploid.     

MICROSPECTROPHOTOMETRY OF CELL NUCLEI STAINED WITH THE FEULGEN REACTION : IV. FORMATION OF TETRAPLOID NUCLEI IN RAT LIVER CELLS DURING POSTNATAL GROWTH

1. DNA contents of the individual parenchymal nuclei of rat livers during postnatal growth were estimated by microspectrophotometric apparatus, and different ploidy classes of nuclei were classified by their DNA contents. With the same material the total number of parenchymal nuclei in the liver was counted microscopically. 2. If the DNA content of nuclei encountered most frequently in several tissues represents the diploid class, the ploidy classes of the rat liver cell nuclei correspond to di-, tri-, tetra-, and octoploid, with the di- and tetraploid ones predominating considerably. 3. In suckling rats (below 25 gm. of body weight) the liver parenchyma is composed almost exclusively of cells with diploid nuclei, whereas in young rats (above 80 gm.), of tetraploid nuclei. In the growth stage between 25 and 80 gm., there is a remarkable replacement of the diploid nuclei by the tetraploid ones. However, in the liver of adult rats weighing more than 150 gm., any increase or decrease in the frequency of diploid and tetraploid nuclei is hardly observable. In such rats, the nuclear population of the liver parenchyma seems to reach a cell-ecological equilibrium which is considered to be a stable one. 4. It is shown that such nuclear populations and the total number of nuclei in a liver are controlled by the growth state, and not by the age. 5. The decrease in the total number of diploid nuclei and the increase in tetraploid nuclei in the growing livers of rats weighing from 40 up to 130 gm. can both be explained by the hypothesis that the tetraploid nuclei originate from the interphase diploid nuclei without involving mitosis. This hypothesis implies that mitosis is confined to the reproduction of diploid cells alone. 6. It is suggested that, in general, the synthesis of DNA does not necessarily result in the formation of visible mitotic chromosomes. 7. Mitotic time and generation time of diploid nuclei and the percentage of the tetraploidization from diploid nuclei are calculated and discussed.