A cytological study of Nematospora coryli pegl

A study is made of nuclear division in Nematospora coryli, a pathogenic yeast. The DNA of cells (grown on a V-8-medium) was stained with leuco-basic fuchsin (Feulgen test) at pH 3.5. After budding has started the rounded nucleus elongates and some differentiation into chromosomes is perceptible. A few slides suggest the number of chromosomes being 4. After some time the nucleus appears to have duplicated. This nucleus migrates towards the isthmus between mother cell and bud. In the isthmus, or just in front of it, the two daughter nuclei proceed to disjoin and move along each other to opposite directions. One daughter nucleus moves into the bud; the other one migrates back into the mother cell.Samples from synchronously growing cultures show that a fraction of the young yeast cells are destined to grow out to asci, in which after about 6 hours the presence of bivalents seems highly probable. The succeeding nuclear divisions take place in the same way as described for the vegetative cells and stop when the majority of the enlarged asci contain 8 nuclei.Problems of haploidy and diploidy are discussed.Small, densely stained bodies are observed in certain vegetative and some meiotic stages. As these bodies contain DNA, their function and possible homology with centrioles is discussed.     

Presence of a defect in karyokinesis during megakaryocyte endomitosis

Megakaryocyte is the naturally polyploid cell that gives rise to platelets. Polyploidization occurs by endomitosis, a process corresponding to a late failure of cytokinesis with a backward movement of the daughter cells. Generally, a pure defect in cytokinesis produces a multinucleated cell, but megakaryocytes are characterized by a single polylobulated nucleus with a 2^N ploidy. Here, we show the existence of a defect in karyokinesis during the endomitotic process. From late telophase until the reversal of cytokinesis, some dipolar mitosis/endomitosis and most multipolar endomitosis present a thin DNA link between the segregated chromosomes surrounded by an incomplete nuclear membrane formation, which implies that sister chromatid separation is not complete. This observation may explain why polyploid megakaryocytes display a single polylobulated nucleus along with an increase in ploidy.     

Karyology of a Marine Non-Motile Dinoflagellate, Pyrocystis lunula

Dinoflagellates have a unique and interesting intracellular architecture such as permanently condensed chromosomes throughout the cell cycle. However the study of dinoflagellate chromosomes is not amendable because of the unusually higher number of chromosomes and problems in sample preparation. The species of Pyrocystis spend most of their life cycle as vegetative cyst forms and have been used as experimental organisms for bioluminescence and circadian rhythms. Here, we documented the content of DNA in different life stages and the chromosome karyology in a marine non-motile dinoflagellate Pyrocystis lunula, through light and fluorescent microscopy, serial ultra-thin sectioning, and three dimension (3D) modeling. The DNA content doubles during DNA synthesis and in the end of the cell division two separate daughter cells have the approximately same fluorescent values for the mother cells. Using serial ultra-thin sectioning and 3D modeling, we report the first ultrastructural karyogram. The cells chosen were at the end of karyokinesis. A total of 98 chromosomes were counted and assigned to 49 pairs. In this species, DNA synthesis appears to occur before, or during asexual division and P. lunula lives a diplontic life cycle.     

FEULGEN MICROSPECTROPHOTOMETRIC STUDIES OF PANDORINA MORUM AND OTHER VOLVOCALES (CHLOROPHYCEAE)12

The nuclear DNA content during normal vegetative growth and division has been examined in three species of Volvocales, Chlamydomonas reinhardtii Dangeard, Pandorina morum Bory, and Volvox carteri f. nagariensis Iyengar. The results are consistent with the nuclear cycle reported in the literature for Eudorina. Nuclear DNA content does not increase during the prolonged cell growth phase. At the time of colony formation, nuclear DNA doubles, the nucleus divides, and this alternation continues until the final 2ⁿ complement of progeny nuclei is formed. The 4- and 8-nucleate stages of dividing gonidia of V. carteri have a nuclear DNA content in the same range as the somatic cells; they are not polyploid or polytene. Four normal clones of Pandorina, having 2, 5 or 12 chromosomes, all had similar amounts of DNA per nucleus, suggesting that the species has a nuclear genome of fairly constant size rather than consisting of many strains representing a polyploid series. One unique clone, a hybrid with double the chromosome number of either its parents, had twice as much DNA as the normal clones. The Feulgen spectrophotometric method is sufficiently sensitive to detect 2-fold differences in DNA content at the level of 2 × 10^?13 g of DNA /nucleus, and its use avoids the complications associated with the presence of organelle DNA.     

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     

GROWTH CHARACTERISTICS OF MARINE PHYTOPLANKTON DETERMINED BY CELL CYCLE PROTEINS: THE CELL CYCLE OF ETHMODISCUS REX (BACILLARIOPHYCEAE) IN THE SOUTHWESTERN NORTH ATLANTIC OCEAN AND CARIBBEAN SEA1

Ethmodiscus spp. is an important contributor to oceanic tropical-ooze sediments and thus might be an important transport vehicle of carbon from the ocean surface to sediments. The knowledge of its cell cycle and growth rate, which is still lacking, is necessary to evaluate the importance of Ethmodiscus in nutrient cycling and to solve the discrepancy between its high sedimentary abundance and rarity in the plankton. We used immunofluorescence of a cell cycle protein, prolqerating cell nuclear antigen (PCNA), and DNA-specific staining to study the progression of the cell cycle and roughly estimate the growth rate for E. rex (Rattray) Wiseman and Hendey in the southwestern North Atlantic Ocean and Caribbean Sea in June 1994 and January 1995. During the cell division cycle, the chloroplasts appeared to synthesize DNA before the nucleus (S phase). Following the S phase, the nucleus moved from one end of the cell toward the center underneath the midline of the girdle band (G2 phase) where it divided (M phase). During a very brief period, the parent cell split and moved apart from the girdle midline, and two new valves were produced (late M phase). The two daughter nuclei apparently remained attached at the joint of the two newly produced valves, where they appeared to be responsible for coordinating the symmetrical formation of the new valves. The morphologically complete daughter cells remained joined for a short period of time before separating into solitary cells whose nucleus was located at one end of the cell. Derived from the phase fraction curves, the duration of the cell cycle phases decreased in the order from G1, S, G2, to M. A conservative estimate of the growth rate in the study area obtained by using PCNA immunostaining was 0.39–0.46 d^?1 in June and 0.15 d^?1 in January. The validity and implication of the growth rate estimates are discussed.     

Derepression of the cell cycle by starvation is involved in the induction of tobacco pollen embryogenesis

Summary Microspectrophotometry following Feulgen staining and autoradiography following (³H)-thymidine labelling were used to study cell-cycle events during pollen development in tobacco (Nicotiana tabacum L.). During normal gametophytic pollen development in the anther and in vitro the generative nucleus passes through the S phase to the G₂ phase soon after microspore mitosis, while the vegetative nucleus remains arrested in G₁ (=G₀). During embryogenie induction by an in vitro starvation treatment of immature pollen ongoing DNA replication in the generative nucleus is completed and followed by DNA replication in the vegetative cell in a large fraction of the pollen grains. Addition of the DNA replication inhibitor hydroxyurea to the starvation medium postpones S phase entry until the pollen is transferred to a rich medium and does not affect embryo formation. These results demonstrate that one of the crucial events of embryogenic induction is the derepression of the G₁ arrest in the cell cycle of the vegetative cell.     

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.     

Quantitation of Absolute Pneumocystis carinii Nuclear DNA Content. Trophic and Cystic Forms Isolated from Infected Rat Lungs are Haploid Organisms

The Pneumocystis carinii carinii DNA content in nuclei of trophic forms and cysts (spore cases) containing 2, 4, or 8 intracystic bodies, were compared using quantitative fluorescence image analysis. The nuclear DNA content was found to be lower than the theoretical limits of Feulgen cytophotometry. Several fluorescent DNA dyes provide brighter staining, but these techniques suffer from nonspecific binding to other cellular components, such as RNA. It was demonstrated that the thick glycocalyx surfaces of trophic forms and the cyst walls of P. carinii organisms, as well as the cell wall of S. cerevisiae, bound all fluorescent dyes tested to varying degrees. Hence in this study, measurements were performed on cells in which the outer surfaces of organisms were first removed with lyticase. Two stains that appeared most specific for DNA, DB181 and 4′,6-diamidino-2-phenylindole (DAPI), were used for quantitations; lower deviations of fluorescence intensities were observed with DB181. Haploid wild type Saccharomyces cerevisiae and cdc-28 temperature-sensitive mutant cells, accumulated at the restrictive temperature (37° C), were used as quantitative internal standards for estimating the absolute nuclear DNA content of P. carinii. Haploid wild type and mutant nuclei stained with DAPI had the same relative fluorescence intensities. The P. carinii nuclear DNA content of trophic forms and individual intracystic bodies (spores), regardless of life cycle stage, were not different. The mean values obtained were 6.9 and 6.7 fg DNA/nucleus with DB181 and DAPI, respectively (approximately 9.26 and 8.99 Mbp nucleotides, respectively). Since these would include 2C (G-2 phase) and S-phase nuclei, a 1C population of nuclei was selected by histogram distributions of DB181-stained nuclei. Almost all nuclei analyzed in all life cycle stages fell within this population. The 1C mean of 6.55 fg DNA/nucleus (median, 6.62 fg DNA/nucleus) was estimated as representing 8.79 Mbp nucleotides, assuming only A-T binding of the dye and taking into account the G+C content of S. cerevisiae and P. carinii. A 4C (G-2-phase diploid nuclei) population was not detected in histograms of DB181- or DAPI-stained nuclei. The P. carinii nuclear DNA content values obtained in this study were similar to those independently obtained by calculating the total DNA in the organism's chromosomes resolved by electrophoretic techniques. Together, the data on total chromosome numbers and the estimated DNA content of those chromosomes, with our quantitation of nuclear DNA content of different life-cycle stages demonstrate that P. carinii carinii isolated from infected rat lungs are haploid organisms.     

DIPLOIDY IN DNA CONTENT IN VEGETATIVE CELLS OF CLOSTERIUM EHRENBERGII (CHLOROPHYTA)1

DNA content of the nucleus in the placoderm desmid, Closterium ehrenbergii Meneghini was measured throughout the life cycle by epifluorescence microspectrophotometry after DNA specific dye [4′,6-diamidino-2-phenylindol (DAPI)] staining. Postulating a mean DNA content of gamete nuclei as 1C, the nucleus of a newly divided vegetative cell was 2C. Most vegetative cells in the stage of exponential growth had a DNA content from 2C to 4C, while most in stationary phase, with the highest frequency of zygote formation, were 2C. They became pre-gametes (2C) upon mixing two heterothallic strains. Four gametes were made by a DNA reduction division of each pre-gamete cell. Therefore, there was a nonmeiotic DNA reduction stage by one half. During germination, the zygote underwent meiosis to produce two gones, each of which contained one surviving nucleus (large nucleus) and one degenerating nucleus (small nucleus). The DNA content of these four nuclei was 1C basically. The DNA of the surviving nucleus duplicated to 2C and further quadruplicated to 4C without cell or nuclear division. These two 4C gones had different cell morphology from ordinary vegetative cells. After the first cell division following meiosis, each gone produced two vegetative cells in which the DNA content became 2C to 4C again.     

Double fertilization inEphedra trifurca,a non-flowering seed plant: The relationship between fertilization events and the cell cycle

Summary Fertilization inEphedra trifurca was examined with a combination of light and fluorescence microscopy. Developmental analysis clearly indicates that double fertilization events, similar to those described inE. nevadensis, regularly occur during the process of sexual reproduction inE. trifurca. In addition to the typical fusion of a sperm nucleus and egg nucleus, a second fertilization event occurs between the second sperm nucleus from an individual pollen tube and the ventral canal nucleus. Both of the fertilization events take place within the confines of an individual egg cell of the female gametophyte. Microspectrofluorometric data demonstrate that each nucleus involved in a sexual fusion event proceeds through the synthesis phase of the cell cycle and increases its DNA content from 1C to 2C before the process of nuclear fusion is completed. Photometric data also confirm that the product of the second fertilization event is equal in DNA content (4C) to the zygotic nucleus derived from the first fertilization event, and is prepared to enter into mitosis as a fully functional diploid nucleus.Abbreviations DAPI 4;,6-diamidino-2-phenylindole - RFU relative fluorescence units     

LIN54 harboring a mutation in CHC domain is localized to the cytoplasm and inhibits cell cycle progression

The mammalian LIN complex (LINC) plays important roles in regulation of cell cycle genes. LIN54 is an essential core subunit of the LINC and has a DNA binding region (CHC domain), which consists of two cysteine-rich (CXC) domains separated by a short spacer. We generated various LIN54 mutants, such as CHC deletion mutant, and investigated their subcellular localizations and effects on cell cycle. Wild-type LIN54 was predominantly localized in the nucleus. We identified two nuclear localization signals (NLSs), both of which were required for nuclear localization of LIN54. Interestingly, deletion of one CXC domain resulted in an increased cytoplasmic localization. The cytoplasmic LIN54 mutant accumulated in the nucleus after leptomycin B treatment, suggesting CRM1-mediated nuclear export of LIN54. Point mutations (C525Y and C611Y) in conserved cysteine residues of CXC domain that abolish DNA binding activity also increased cytoplasmic localization. These data suggest that DNA binding activity of LIN54 is required for its nuclear retention. We also found that LIN54^C525Y and LIN54^C611Y inhibited cell cycle progression and led to abnormal nuclear morphology. Other CXC mutants also induced similar abnormalities in cell cycle progression. LIN54^C525Y led to a decreased expression of some G₂/M genes, whose expressions are regulated by LINC. This cell cycle inhibition was partially restored by overexpression of wild-type LIN54. These results suggest that abnormal cellular localization of LIN54 may have effects on LINC activity.     

Real-Time Imaging of Nuclear Permeation by EGFP in Single Intact Cells

The NPC is the portal for the exchange of proteins, mRNA, and ions between nucleus and cytoplasm. Many small molecules (<10 kDa) permeate the nucleus by simple diffusion through the pore, but molecules larger than 70 kDa require ATP and a nuclear localization sequence for their transport. In isolated Xenopus oocyte nuclei, diffusion of intermediate-sized molecules appears to be regulated by the NPC, dependent upon [Ca²⁺] in the nuclear envelope. We have applied real-time imaging and fluorescence recovery after photobleaching to examine the nuclear pore permeability of 27-kDa EGFP in single intact cells. We found that EGFP diffused bidirectionally via the NPC across the nuclear envelope. Although diffusion is slowed ~100-fold at the nuclear envelope boundary compared to diffusion within the nucleus or cytoplasm, this delay is expected for the reduced cross-sectional area of the NPCs. We found no evidence for significant nuclear pore gating or block of EGFP diffusion by depletion of perinuclear Ca²⁺ stores, as assayed by a nuclear cisterna-targeted Ca²⁺ indicator. We also found that EGFP exchange was not altered significantly during the cell cycle.     

The organization of microtubules during generative-cell division inConvallaria majalis

Summary The organization of the microtubule cytoskeleton in the generative cell ofConvallaria majalis has been studied during migration of the cell through the pollen tube and its division into the two sperm cells. Analysis by conventional or confocal laser scanning microscopy after tubulin staining was used to investigate changes of the microtubule cytoskeleton during generative-cell migration and division in the pollen tube. Staining of DNA with 4,6-diamidino-2-phenylindole was used to correlate the rearrangement of microtubules with nuclear division during sperm cell formation. Before pollen germination the generative cell is spindle-shaped, with microtubules organized in bundles and distributed in the cell cortex to form a basketlike structure beneath the generative-cell plasma membrane. During generative-cell migration through the pollen tube, the organization of the microtubule bundles changes following nuclear division. A typical metaphase plate is not usually formed. The generative-cell division is characterized by the extension of microtubules concomitant with a significant cell elongation. After karyokinesis, microtubule bundles reorganize to form a phragmoplast between the two sperm nuclei. The microtubule organization during generative-cell division inConvallaria majalis shows some similarities but also differences to that in other members of the Liliaceae.Abbreviations CLSM confocal laser scanning microscopy - EM electron microscopy - GC generative cell - GN generative nucleus - MT microtubule - SC sperm cell - SN sperm nucleus - VN vegetative nucleus     

Studies on the Macronuclei of Doublet Paramecium tetraurelia: Distribution of Macronuclei and DNA at Fission*

SYNOPSIS. Doublet Paramecium tetraurelia would be expected to contain 2 macronuclei if their nuclear complement were strictly analogous to that of singlets. However, most doublets are unimacronucleate. It is shown in this study that dimacronucleate cells are present only in young clones. Unimacronucleate cells arise either through abnormalities in the determination and distribution of macronuclear anlagen during the first cell cycle after conjugation, or from dimacronucleate cells through abnormal division and segregation of macronuclei during the fission process. When a change in the number of macronuclei occurs through abnormalities in the division and segregation of daughter macronuclei, the daughter cells produced typically have DNA contents more similar than those expected from either random segregation of daughter macronuclei, or from the normal segregation pattern in ciliates in which changes in the number of macronuclei in progeny cells do not occur. This suggests that part of the regulation process of macronuclear DNA content in Paramecium may occur through control of the segregation pattern of daughter macronuclei.     

Il genere Allium L. in Italia. IV. Studio citofotometrico sul granulo pollinico di Allium Chamaemoly L.

Abstract

The genus Allium L. in Italy. IV. A DNA cytophotometric study on the pollen grain of Allium chamaemoly L. — A cytophotometric analysis of DNA contents in pollen generative and vegetative nuclei of Allium chamaemoly L. was carried out. DNA synthesis in both nuclei was confirmed and a lightly higher DNA amount than 2C in the vegetative nucleus was pointed out. An analysis of the Fast-green stainable histones in the generative and vegetative nuclei was also accomplished. While the generative nucleus had a very high content of Fast-green stainable histone, the vegetative one have nearly no stainable histone. The occurrence of DNA synthesis and the very low histone content suggest the vegetative nucleus is functional and biochemically activ. The higher than 2C DNA content supports the possibility of a DNA amplification process including probably the amplification of ribosomal cistrons in the pollen vegetative nucleus.     

Vegetative nuclear structures and their mode of division inCyathus species

Vegetative nuclear division in the homokaryotic and dikaryotic hyphae ofCyathus olla Brodie,C. setosus Brodie andC. bulleri Brodie was investigated. In the homokaryotic hyphae a nucleolus develops within a globular condensed nucleus consisting of a folded up filament. As the nucleolus increases in size, the nucleus unfolds and can assume a ring, horseshoe or filament configuration. The filament duplicates and (usually when unwound from the nucleolus) divides longitudinally. Occasionally, strand separation occurs while the filament is wrapped in the form of a ring around the nucleolus. The daughter nuclei may condense before the next division. In the dikaryotic hyphae the same nuclear cycle occurs as in the homokaryons except that an extra nuclear condensation to the globular form can occur in both the clamp and tube nuclei. The division of these two nuclei is not always synchronous and, moreover, the stage of karyokinesis of the clamp nucleus is not closely synchronized with the formation of the clamp connection. A deeply stained granule is associated with the nucleus. Some granules can be observed to be connected to the nucleus by a faintly Feulgen positive thread-like structure but other granules are sessile. The granule or centriole-like body is thought to direct the nuclear unfolding process. It may divide prior to, or after nuclear division.     

LIN54 harboring a mutation in CHC domain is localized to the cytoplasm and inhibits cell cycle progression

The mammalian LIN complex (LINC) plays important roles in regulation of cell cycle genes. LIN54 is an essential core subunit of the LINC and has a DNA binding region (CHC domain), which consists of two cysteine-rich (CXC) domains separated by a short spacer. We generated various LIN54 mutants, such as CHC deletion mutant, and investigated their subcellular localizations and effects on cell cycle. Wild-type LIN54 was predominantly localized in the nucleus. We identified two nuclear localization signals (NLSs), both of which were required for nuclear localization of LIN54. Interestingly, deletion of one CXC domain resulted in an increased cytoplasmic localization. The cytoplasmic LIN54 mutant accumulated in the nucleus after leptomycin B treatment, suggesting CRM1-mediated nuclear export of LIN54. Point mutations (C525Y and C611Y) in conserved cysteine residues of CXC domain that abolish DNA binding activity also increased cytoplasmic localization. These data suggest that DNA binding activity of LIN54 is required for its nuclear retention. We also found that LIN54^C525Y and LIN54^C611Y inhibited cell cycle progression and led to abnormal nuclear morphology. Other CXC mutants also induced similar abnormalities in cell cycle progression. LIN54^C525Y led to a decreased expression of some G₂/M genes, whose expressions are regulated by LINC. This cell cycle inhibition was partially restored by overexpression of wild-type LIN54. These results suggest that abnormal cellular localization of LIN54 may have effects on LINC activity.     

Isolation,Characterization and Synthesis of DNA from a Malaria Parasite*

SYNOPSIS. Methods for the isolation and purification of DNA from the intraerythrocytic stages of the avian malaria parasite Plasmodium lophurae are described. The DNA of P. lophurae was found to have a 19 mole-percent guanine plus cytosine (G+C) composition as determined by melting temperature and density measurements in CsCl gradients, whereas that of the host cell nucleus was 35 molepercent G+C. Synthesis of DNA by P. lophurae was studied by following the incorporation of P³² during the in vitro growth of plasmodia in infected cell suspension cultures. DNA synthesis was linear during the multiple nuclear divisions of a single growth cycle in highly synchronous cultures. Separation of P³² labeled parasite DNA from the DNA of the duck erythrocyte on CsCl gradients showed that only parasite DNA was synthesized.