Studies of multipolar mitoses in euploid tissue cultures

Cultures of kidney epithelium and fibroblasts of 39 specimens of Microtus agrestis were investigated. In all 77 cultures multipolar mitoses were found. They were studied in living state and after pulse labelling with ³H-thymidine. The ploidy of the multipolar mitoses and of their daughter nuclei was determined by measuring the relative Feulgen-DNA content and by counting the predominantly constitutive heterochromatic sex chromosomes. Constitutive heterochromatin was demonstrated by late replication, retarded separation of the chromatids in anaphase, heteropycnosis and by the Giemsa technique of Arrighi and Hsu (1971). The latter stained also the spindle apparatus of mitoses.—In living cells, transformation of multipolar mitoses into bipolar mitoses was observed. The chromosomes of multipolar mitoses are separated into complete genomes; the daughter nuclei can be haploid, diploid, triploid or tetraploid. The chromosomes of haploid and triploid metaphases were studied with the Giemsa banding technique. The banding pattern shows an exact monosomy and trisomy, respectively, for each chromosome. Haploid nuclei are likely to be viable only in multinucleate cells, whereas triploid cells behave like diploid cells during the S period and the mitosis.Dedicated to Prof. Dr. K. Goerttler on the occasion of his 75th birthday.Supported by the Bundesministerium für Bildung und Wissenschaft of the Federal Republic of Germany.     

Die Verteilung der Chromosomen auf die Tochterzellkerne multipolarer Mitosen in euploiden Gewebekulturen von Microtus agrestis

In kidney epithelial cultures from female Microtus agrestis, 3,55% of all mitoses are multipolar, 94% of them tripolar. Feulgen photometric measurements of 21 tripolar mitoses reveal a total DNA amount corresponding to the mitotic diploid value (4c) in 5 cases, and to the tetraploid value (8c) in 16 cases, Diploid tripolar mitoses divide into one daughter nucleus with a diploid DNA value (2c) and two nuclei each with a haploid DNA value (1c). Most tetraploid tripolar mitoses divide into one daughter nucleus with a diploid DNA value (2c) and two nuclei with a triploid DNA value (3c). Also the sex chromosomes are distributed to the daughter nuclei in the relation of 2∶3∶3. This can be seen in anaphase figures as well as in interphase nuclei presumably derived from tripolar mitoses, showing chromocenters according to the number of X-chromosomes. In two cases of tripolar tetraploid mitoses the resulting nuclei have a haploid, a triploid and a tetraploid DNA value. The DNA replication pattern is always identical in the daughter nuclei of diploid and tetraploid tripolar mitoses. — Our observations suggest segregation and distribution of haploid chromosome sets or multiples of haploid sets to the daughter nuclei of multipolar mitoses. They also show a possible way of formation of haploid and triploid cells in a basically diploid tissue. Presumably triploid nuclei (with 3 chromocenters) are capable of DNA synthesis.     

Analysis of chromatin and DNA during chromosome endoreduplication in the endosperm ofTriticum durum Desf.

Summary Chromatin structure was studied in nuclei of the endosperm of durum wheat (Triticum durum Desf., cv. Creso), where a large number of cells undergo chromosome endoreduplication during caryopsis development. Optical density profiles of interphase nuclei at different ploidy levels after Feulgen staining were determined cytophotometrically. It was observed that, within each development stage, polyploid nuclei (6–12C and 12–24C) show more condensed chromatin than euploid nuclei (3–6C): this should indicate that endoreduplication is accompanied by some reduction of nuclear activity. Within the same ploidy level, 3–6C and 6–12C nuclei become increasingly condensed with development (except for the last stage), while 12-24C nuclei are identical at all stages. DNA methylation at different stages of caryopsis development was then analyzed in genomic DNA, highly repeated sequences and ribosomal DNA, by digestion with cytosine-methylation-sensitive restriction enzymes. We observed that (i), depending on the enzyme, DNA from caryopses may show higher mean length than DNA from shoot apices and variations occur during endosperm development; (ii) highly repeated DNA sequences also show some variation in base methylation between apices and endosperms and among endosperm development stages, even though to a lesser extent than genomic DNA; (iii) rDNA shows variations only between endosperm and apices while no variation was observed among endosperm development stages in relation to chromosome endoreduplication. Our data may be explained by assuming the occurrence, during endosperm development, of processes of chromatin condensation possibly involved in silencing the activity of extra copies of DNA resulting from chromosome endoreduplication. At least in part, DNA methylation is involved in the process of chromatin condensation. rDNA shows no variation during endosperm development: this suggests that rDNA copies are actively transcribed in both triploid and endoreduplicated nuclei.     

Endopolyploidization patterns in non-generative antheridial cells in mono- and dioeciousChara spp. (Characeae) with different DNA C-values

Cytophotometric measurements of nuclear DNA contents and morphometric analyses in the antheridia of five species ofChara indicate that the level of endopolyploidy plays an important role in determining the maximum sizes that shield cells, manubria, and capitular cells attain at the final stage of spermiogenesis. Dioecious species with low DNA C-values—C. aspera andC. tomentosa—display higher values of endopolyploidy: their male sex organs are larger and the quantities of spermatozoids per antheridium are greater than those estimated for monoecious species—C. vulgaris, C. fragilis, andC. contraria. Two types of nucleotypic effects were found to synchronize developmental traits in germ line cells and non-generative component parts within the antheridia; both are discussed in relation to the biological productivity of male sex organs in mono- and dioecious species ofChara.     

Edeine inhibition and resistance in Neurospora

To obtain data on the biochemical effects of edeine in the fungus Neurospora crassa, in vivo protein synthesis, in vitro protein synthesis, as well as in vivo RNA and DNA synthesis of the wildtype and an edeine resistant mutant were measured.—Incorporation of ³H leucine into conidia of both strains, which served as a measure for in vivo protein synthesis, was inhibited by 200 g edeine/ml as follows: Wildtype approx. 40%, mutant approx. 6%.—Incorporation of ¹⁴C phenylalanine into polyphenylalanine in a cell free system with ribosomes from either the wildtype or the mutant, was inhibited between 74 and 95% by edeine at a ratio of 2 molecules edeine per ribosome.—Incorporation of ³H adenosine into conidia, serving as a measure for in vivo RNA synthesis, was inhibited in the wild-type (approx. 30% inhibition by 200 g edeine/ml). It was, however, not influenced in the ed ^r mutant. Similarly, in vivo DNA synthesis was decreased in the wildtype, but not in the mutant.—These results suggest that edeine acts at more than one site. The resistance of the mutant ed ^r -29 (ed ^r -2 locus) is tentatively interpreted as due to a block in edeine uptake.     

Evidence for dosage compensation in parthenogenetic Hymenoptera

Amount of DNA-Feulgen staining in individual somatic nuclei and mature sperm of the parthenogenetic wasps, Habrobracon juglandis, H. serinopae, and Mormoniella vitripennis, were determined with a scanning microdensitometer. The haploid genome for both species of Habrobracon was estimated to be 0.15–0.16×10^–12 g DNA, corresponding to a molecular weight of roughly 10×10¹⁰ daltons. The haploid genome of M. vitripennis is approximately twice this value, 0.33–0.34×10^–12 g, or about 20×10¹⁰ daltons. Measurements made on dividing nuclei from syncytial preblastoderm embryos of H. juglandis and M. vitripennis showed that the chromosomes of impaternate males were present in the haploid number and contained the C amount of DNA; whereas nuclei from female preblastoderm embryos contained the diploid number of chromosomes and the 2C amount of DNA. However, hemocyte and brain cell nuclei from either male or female adult wasps contained 2C and 4C amounts of DNA. Both sexes also showed equivalent levels of polyploidy (8C, 16C, or 32C) in Malpighian tubule nuclei. Therefore, in these parthenogenetic species, a mechanism must exist that compensates during later development for the initial two-fold difference in the chromatin content of somatic nuclei in haploid male and diploid female embryos. Hemocytes from impaternate Mormoniella diploid males and triploid females contain the 2C and 3C amounts of DNA, respectively. Therefore dosage compensation involves an additional cycle of DNA replication only in haploid cells, and it insures that a certain minimum quantity of DNA is received by each somatic cell.     

DNA endoreduplication in maize endosperm cells: the effect of exposure to short-term high temperature

DNA endoreduplication in Zea mays L. (cv. A619 × W64A) endosperm peaks between 16 and 18 d after pollination (DAP). The physiological function of DNA endoreduplication is not known but it is believed to be important in maize kernel development. In the present study, we investigated how 2, 4 or 6 d of high temperature (35 °C) affected DNA endoreduplication and maize kernel development in comparison with control kernels grown at 25 °C. Data were collected on fresh weight (FW), nuclei number, mitotic index, and DNA endoreduplication. Maize endosperm FW and nuclei number were reduced by exposure to 4 or 6 d of high temperature. At 18 DAP, the 2 d high temperature treatment (HTT) caused a reduction in FW and nuclei number, but had no effect on DNA endoreduplication and average DNA content per endosperm. However, when the exposure to high temperature was increased to 4 or 6 d, FW, nuclei number and the magnitude of DNA endoreduplication were progressively reduced, and the peak mitotic index was delayed compared with the control endosperm. At 18 DAP, the 4 d treatment showed 54·7% of the cells were 3 or 6 C, whereas only 41·2% were 12 C or higher. Six days of high temperature also resulted in a reduction in endosperm FW, nuclei number and a delay in the peak of mitotic index. DNA endoreduplication occurred in the kernels exposed to this treatment, although the magnitude was severely reduced compared with the control kernels. Nuclear DNA content was highly correlated (r = 0·93) with kernel FW, suggesting an important role of DNA endoreduplication in determining endosperm FW. The data suggest that high temperature during endosperm cell division exerted negative effects on DNA endoreduplication by dramatically reducing the nuclei number, leaving fewer nuclei available for DNA endoreduplication. However, the data also suggest that prolonged exposure to high temperature restricts entry of mitotic cells into the endoreduplication phase of the cell cycle.     

Differential DNA synthesis in heterochromatic and euchromatic chromosome sets of Planococcus citri

In males of the mealy bug Planococcus citri, Nur (1966) counted five heterochromatic (H) and about 5, 10, 20, 40, or 80 euchromatic (E) chromosomes in testis sheath nuclei which were undergoing endomitosis. He suggested that the H chromosomes were not replicating and that the nuclei were becoming polyploid as a result of successive cycles of replication of only the E chromosomes. This hypothesis was tested using autoradiography with H³-thymidine to detect DNA synthesis and microspectrophotometric measurements of the Feulgen reaction in nuclei to detect quantitative changes in DNA. — The integrated absorbance of the whole nucleus and of the isolated clump of heterochromatic chromosomes (H body) in polyploid testis sheath nuclei were measured using the mechanical scanner of the CYDAC system. The absorbance of the H body was similar in all testis sheath nuclei examined and was not significantly different from the absorbance of a haploid set of H chromosomes measured after meiosis. The absorbance of the euchromatic component varied in different sheath nuclei, the values closely corresponding to the terms of the series 2c, 4c, 8c. This series is expected if the DNA in the E chromosomes is exactly doubled at each cycle of replication. — Autoradiographs showed that most labeled sheath nuclei had silver grains localized exclusively over euchromatin. With one exception, the remainder of the labeled nuclei had silver grains over both euchromatin and the H body. The observation that euchromatin was much more heavily labeled than the H body and that labeled H bodies occurred at a low frequency and only in the presence of labeled euchromatin suggests that the H body did not incorporate the label and that the silver grains over the H body were the result of -particles which originated in proximal euchromatin.     

The arrangement of chromosomes in nuclei of sperm from plethodontid salamanders

Plethodontid salamanders have n = 13 or 14 large metacentric or sub-metacentric chromosomes. Sperm nuclei from Plethodon cinereus measure 72×1 m. The nucleoprotein of spermatids is at first finely granular. In elongate spermatids it clumps into larger granules, which then fuse to form the compact nucleoprotein of the mature sperm. The nuclei of mature sperm are negatively birefringent with respect to their length. — ³H RNA complementary to high-density satellite DNA of centromeric heterochromatin in P. cinereus has been hybridized in-situ to spermatids and sperm, and its site of binding to these cells has been examined by autoradiography. Labelling of round spermatid nuclei is localized in a single patch. Elongate spermatid nuclei are labelled only over the rear quarter of the nucleus. Label over the nuclei of mature sperm is localized in a region extending 10–20 m forwards from the rear of the nucleus. — In P. cinereus the ribosomal genes are located near the centromere on the short arm of chromosome 7. ³H ribosomal RNA hybridizes to a single patch in round spermatid nuclei. Elongate spermatid nuclei show label over a short segment of the rear half of the nucleus. In spermatids nearing maturity the labelled region is never more than 20 m long. — These results indicate that in P. cinereus each chromosome is arranged in a U formation with its centromere at the base of the sperm nucleus, and its arms extended forwards along the length of the nucleus. — Among plethodontids, increase in C value and corresponding increase in chromosome size is accompanied by increase in the length rather than the width of the sperm nucleus. — ³H ribosomal RNA hybridizes to a short segment in spermatid and sperm nuclei from Xenopus and Triturus. In these animals, the position of the labelled segment varies from sperm to sperm.     

Flow cytometric evidence for endopolyploidy in seedlings of some Brassica species

Flow cytometric analysis of the nuclear DNA contents of somatic tissues from seedlings of Brassica rapa L. and B. oleracea L. revealed extensive endoreduplication, resulting in tissues that contain cells with multiple ploidy levels (also called ’endopolyploidy’). Multiples of the haploid nuclear genome complement (1C) corresponding to 2C, 4C, 8C, 16C, 32C and 64C were observed in Brassica rapa, while B. oleracea exhibited a mixture of cells with five ploidy levels, 2C, 4C, 8C, 16C and 32C. The distribution of cells with the different ploidy levels was tissue-specific and characteristic of the stage of development. Multiploidy was not found in the embryos of dry seeds. Rapid endoreduplication occurred during seedling development. It is most probable that multiploidy is, if not a general feature, at least very common in Brassica species. The physiological and genetic implications of this original feature are discussed. Received: 17 March 2000 / Accepted: 17 April 2000     

The anaphase promoting complex activator CCS52A,a key factor for fruit growth and endoreduplication in tomato

Tomato fruit growth is characterized by the occurrence of numerous rounds of DNA endoreduplication in connection to cell expansion and final fruit size determination. Endoreduplication occurs as an impairment of mitosis, which can originate from the selective degradation of M-phase-specific cyclins via the ubiquitin-mediated proteolytic pathway, requiring the E3 ubiquitin ligase Anaphase Promoting Complex/Cyclosome (APC/C). In plants CCS52A is the ortholog of CDH1/FZR proteins from yeast, drosophila and human, belonging to the WD40-repeat protein family. During fruit development, the SlCCS52A gene expression is specifically associated to endoreduplication in tomato. Altering SlCCS52A expression in either negative or positive manner impacts the extent of endoreduplication in fruit and affects fruit size. When SlCCS52A is down-expressed endoreduplication is impaired during fruit growth leading to reduced fruit growth. However when SlCCS52A is overexpressed, endoreduplication is initially delayed, accounting for the altered final fruit size, but resumes and is even enhanced leading to fruit growth recovery, pointing at the physiological role of endoreduplication in growth induction during tomato fruit development.Key words: anaphase promoting complex, CCS52A, endoreduplication, fruit development, growth, tomatoEndoreduplication represents the most common mode of cell endopolyploidization in plants and is estimated to occur in over 90% of Angiosperms.^1,2 This process is an endonuclear DNA stock duplication leading to the production of chromosomes with 2n chromatids without any change in chromosome number.^3,4 As a consequence hypertrophying nuclei arise from successive cycles of DNA replication.In fruits of Cucurbitaceae and Solanaceae, mesocarp cells commonly undergo six rounds of DNA duplication (endocycle), and the highest ploidy levels for these cells being reached in tomato fruits where eight endocycles (up to 512C) can be observed.⁵ This high level of endopolyploidy in tomato fruits and the numerous data reported on this process in this species,^6–9 makes it an outstanding model for studying endopolyploidization and its physiological role during fruit development.     

An efficient method for flow cytometric analysis of pollen and detection of 2n nuclei in Brassica napus pollen

A simple and reliable method was developed for isolating pollen nuclei from Brassica napus and Triticum aestivum for DNA analysis using flow cytometry. The nuclei were released from pollen by ultrasonic treatment. The isolated nuclei following filtration through nylon mesh and a purification procedure were suitable for flow cytometric analysis as well as for isolating genomic DNA. Ultrasonic treatment time was optimized for B. napus pollen at different developmental stages. The method is effective and suitable for the preparation of many samples. We analyzed the nuclear DNA levels in pollen of B. napus at three major developmental stages as well as in mature wheat pollen. Only a single 1C peak representing the haploid DNA level was detected in the nuclei isolated from Brassica uninucleate microspores as well as in mature Triticum pollen. Interestingly, diploid nuclei were detected in both binucleate and mature pollen of B. napus. The possible origins of the diploid nuclei are discussed.Abbreviations DAPI 4,6-Diamidino-2-phenylindole - NIB Nuclear isolation buffer     

Chromosome endoreduplication as a factor of salt adaptation in Sorghum bicolor

Summary. Nuclear DNA amounts were measured by Feulgen cytophotometry in Sorghum bicolor cv. 610 plants early exposed to 150 mM NaCl, a treatment known to induce an increased tolerance to salinity in plants carrying this genotype. In salt-treated plants, the percentages of 8C, 16C, and 32C nuclei in roots in the primary state of growth were 21.9%, 13.3%, and 4.3%, respectively. By contrast, in nonsalinized plants, only 3.5% of the nuclei had an 8C content and no higher DNA contents were observed. The salt treatment induced chromosome endoreduplication during the differentiation of cells in the root cortex, where 41.2% of the cells displayed a DNA content higher than 4C (versus 1.3% in control plants). No enhancement of endopolyploidy was observed in cells of the root vascular cylinder or the leaves of the salt-treated plants. In another S. bicolor genotype (DK 34-Alabama), noncompetent for salt adaptation, the same NaCl treatment did not induce chromosome endoreduplication in root cortex cells. Endopolyploidy may be considered as a part of the adaptive response of S. bicolor competent genotypes to salinity. Correspondence and reprints: Dipartimento di Biologia Cellulare e Ambientale, Università di Perugia, Via A. Pascoli, 06123 Perugia, Italy.     

Comparative analysis of DNA nuclear content by flow cytometry on strawberry plants propagated via runners and regenerated from meristem and callus cultures

ABSTRACT

DNA variation may occur in plant species grown either in vivo or in vitro. In this study flow cytometric analyses were undertaken on Fragaria x ananassa Duch. runner plants, and on plants regenerated from callus cultures of leaf explants and from meristem cultures. Our aims were to investigate DNA variation in runner plants of different cultivars, and to compare DNA content in plants of the same cultivar obtained by different propagation procedures (i.e. from meristems or callus cultures). Plants growing in vitro and in the greenhouse were also compared. A good regeneration ability was observed in all the cultivars, with different percentages of shoot formation. No significant differences were detected in multiplication rate and rooting percentage within cultivars. This work documents the occurrence of DNA variations in strawberry plants in vivo and in vitro. Flow cytometric measurements of DNA content showed the presence of 4C nuclei, besides 2C nuclei, in runner plants of cultivar Pajaro. DNA content variations (2C/4C nuclei) were observed in plants regenerated from callus cultures. These variations were lost after transfer of the plants to the greenhouse, except for cultivar Don. The extent of such DNA variations was influenced by genotype. Our study confirms earlier reports indicating that DNA variation induced by in vitro culture could be lost or retained after transfer of the plants to the greenhouse.     

Subnuclear redistribution of DNA species in confluent and growing mammalian cells

About 20 to 25 percent of the nuclear DNA from cultured cells of the African green monkey, Cercopithecus aethiops, consists of a homogeneous, highly repetitive fraction designated C. aethiops component DNA. Use of in situ hybridization techniques reveals component at the centromeres of chromosomes from both diploid and heteroploid African green monkey kidney (AGMK) tissue culture cells. — Component DNA comprises 47 percent of the nucleolar DNA in actively growing primary AGMK cells, but only 31 percent of the nucleolar DNA in confluent cells which show density-dependent growth inhibition. Further, there is a pronounced shift of both main band and component DNA from euchromatin to heterochromatin when growing cells attain confluency. Thus, the relative subnuclear distributions of component and main band DNA's are different in growing and confluent cells. — In situ hybridization techniques indicate that component sequences aggregate in clumps in nuclei of growing cells and show a diffuse distribution in nuclei of confluent cells. This suggests that centromeric regions of the various chromosomes or groups of chromosomes aggregate and disaggregate reversibly as the culture changes from density-dependent growth inhibition to active cell division. — Hypotonic citrate treatment of primary AGMK cells causes nucleoli of confluent cells to disperse: this dispersion following citrate treatment was not seen in growing AGMK cells or in confluent or growing heteroploid cells. Similarly, this nucleolar dispersion was seen in confluent diploid mouse and human cells but not in growing diploid cells or in confluent or growing heteroploid cells.     

Cell-specific endopolyploidy in developing Artemia

Summary Cells in developing Artemia franciscana SFB demonstrated tissue-specific differences in DNA content, as determined by fluorescence intensity of bisbenzimide-stained nuclei and by nuclear area. The general epidermis comprised proliferating diploid (2C) cells. The setal cells had 4C–8C DNA content and did not divide during the first two instars. Salt gland cells were polyploid (>8C) and also did not undergo mitosis. Neural cells in the brain were diploid and were replicating. Cells in the thorax region of the gut had a 4C–8C DNA content and were proliferating. The muscle cells in the cephalic appendages contained 2C non-replicating nuclei. Only diploid epidermal cells were involved in segment morphogenesis. There was no difference in number of chromosomes (n=42) in the epidermal cells and the gut cells, indicating that the tissue-specific endopolyploidy was due to endoreduplication.     

Cytophotometric and autoradiographic evidence for functional apomixis in a gynogenetic fish,Poecilia formosa and its related,triploid unisexuals

Summary Amounts of DNA in individual Feulgen-stained nuclei from squash preparations of ovaries and testes from wild-caught and laboratory-reared stocks of Poecilia spp. were determined with an integrating microdensitometer. The DNA content of primary spermatocytes (4C) at zygotene, pachytene, or at metaphase I (3.3–3.4 pg) was approximately twice that found in secondary spermatocytes (2C) and four times that found for young spermatids (1C). Rarely, mature sperm were found with 2C DNA amounts. Nuclei from follicular epithelium and oogonia from both bisexual and diploid unisexual fish contained about 1.6–1.7 pg DNA; whereas, the DNA content of primary oocyte nuclei was about 3.5–3.7 pg DNA, indicating that just one cycle of chromosomal replication had occurred in these cells during the period of DNA synthesis before the visible onset of meiotic prophase. Similar results were obtained for triploid unisexuals whose 6C primary oocyte nuclei contained 5.0–5.1 pg DNA, which was twice the DNA content of 3C oogonia and follicular epithelial cells (2.4–2.5 pg DNA). Autoradiographic studies, designed to monitor the incorporation of ³H-thymidine by oogonia and primary oocytes in vivo and in vitro, also showed that there is no additional synthesis of DNA during the course of meiotic prophase in these unisexual fish. Therefore, we conclude that apomixis, not endoreduplication, is the cytological basis of reproduction in Poecilia formosa and its related, triploid biotypes.     

Gene amplification in oocytes with 8 germinal vesicles from the tailed frog Ascaphus truei Stejneger

In the last 3 oogonial mitoses in Ascaphus truei all daughter nuclei remain in the same cell. The oocyte is 8-nucleate at the start of meiotic prophase and remains so until late in oogenesis when 7 of the nuclei disappear. All 8 nuclei in a single oocyte resemble one another with respect to size and chromatin distribution at all stages of meiotic prophase. Much of the Feulgen-positive material in pachytene nuclei is concentrated into one region of the nucleus. — All of the 8 germinal vesicles of yolky oocytes have a full set of lampbrush diplotene bivalents. Germinal vesicles from oocytes of up to 0.8 mm diameter have less than 100 nucleoli, some of which are multiple nucleoli in the sense that they have more than one core region. Each of the 8 nuclei in oocytes from one animal had about the same volume of nucleolar material. — Two values have been obtained for the amount of DNA in a diploid nucleus from Ascaphus. A biochemical estimate utilizing erythrocyte nuclei and the diphenylamine reaction yielded a value of 7.1 pg per nucleus. Microphotometry of erythrocyte nuclei stained with Feulgen's reagent gave a value of 8.2 pg per nucleus. — Microphotometric measurements of Feulgen-stained nuclei at various stages of meiotic prophase up to diplotene indicate that each nucleus synthesizes up to 5 pg of extrachromosomal DNA during and immediately after pachytene. This DNA is considered to be nucleolar. Autoradiography of nuclei from oocytes which had been incubated for 6h in ³H thymidine showed silver grains over pachytene and early diplotene nuclei only. In pachytene nuclei the silver grains overlaid that part of the nucleus where Feulgen-positive material was most concentrated. Most of the chromosomal material was unlabelled. — The significance of the 8-nucleate condition in Ascaphus oocytes is discussed, and the amount of nucleolar DNA synthesized at pachytene and of nucleolar material present in germinal vesicles is compared with corresponding situations in other amphibians.     

Les ultrastructures nucléaires de la Noctiluque (Dinoflagellé libre) au cours de la sporogenèse

The trophozoït of Noctiluca miliaris has a large nucleus (30 ) with several nucleoli of considerable size that contain DNA fibrillae lying in the interspaces. — Before and during the first sporogenetic divisions, the nucleoli disintegrate, releasing towards the cytoplasma numerous groups of ribonucleic granules passing through the nuclear ampullae. At the end of the sporulation, there are no nucleoli visible in the nuclei and no ampullae. — The nucleoplasm diminishes, as the DNA filaments are built up, to form the meshes of a network which limit the masses of chromatic material that take the shape of chromosomes characterized by regular fibrillar arches, at the 8–16 nuclei stage. In their centre, there is an axial structure which remains intact during the chromosomal segregation; its function during mitosis seems to be important: supplementary layers of arches appear at this level. — The progressive condensation of the chromosomes is correlated to the sporogenetic evolution of the nuclei, not to the different phases of the mitotic cycle. — The karyokinesis is brought about, during early stages, by mere splitting of the chromatic mass and of its envelope, and later one by separation into two lots of chromosomes. The segregation of these chromosomes is effected by partial intervention and growth of the envelope of the nucleus; there is no centromeric structure visible. At the end of divisions, the nucleus is almost entirely formed by its chromosomes. — The nucleolar structure, the karyokinesis, the structure of the nuclear envelope and the chromosomal cycle show the particularly high evolution of Noctiluca, within the Dinoflagellata.     

Effect of Chilling on DNA Endoreplication in Root Cortex Cells and Root Hairs of Soybean Seedlings

Relative nuclear DNA contents in cortex parenchyma cells in root segments of 3- and 7-d-old soybean seedlings grown at 25 °C and in plants grown for 3 d at 25 °C, and then for 4 d at 10 °C, were determined with cytophotometry. Measurements revealed that in each variant the cortex cell nuclei with DNA content between 2C and 8C were in all the examined segments and nuclei with 8C – 16C DNA appeared in higher parts of roots. However, in chilled plant cells the number of 8C – 16C DNA nuclei was very low. Therefore, chilling inhibited endoreplication in comparison with plants grown at 25 °C for 7 d, and even reduced endopolyploidy level as compared to the initial seedlings, i.e. 3-d-old plants. DNA contents in root hairs grown at 25 °C (control) and in root hairs emerged at 10 °C were also determined. In controls 4C – 8C DNA nuclei predominated while in chilled plants an additional population of 2C – 4C DNA appeared. Thus a reduction of DNA synthesis was brought about by low temperature. The occurrence of an intermediate DNA contents besides those with full endoreplication cycles suggests the possibility of differential DNA replication. This suggestion seems to be supported by the lack of ³H-thymidine incorporation into root hair nuclei at the examined developmental stage both in control and chilled root hairs. The same number, but larger, chromocentric lumps in polyploid cortex cell nuclei of higher root zones, in comparison to meristematic nuclei, suggests that endoreduplication process occurred. This revised version was published online in July 2006 with corrections to the Cover Date.