Cell division and chromosome numbers in the tissue culture ofNicotiana tabacum

The callus tissue derived from tobacco pith and subcultured for 5^1/2 years on a solid synthetic modium revealed considerable differences in cell division activity depending on the age of the subculture and diurnal rhythm. The callus cells exhibited different level of ploidy among which an aneuploid condition nearer to diploid (2n=30–50) predominated. Chromosomal bridges and other structural rearrangements (lagging chromosomes, fragments) were observed in ana-and telophase.     

Requirements for division of the generative nucleus in cultured pollen tubes ofNicotiana

Summary Production of sperm cells by division of the generative cell occurs during growth ofNicotiana (tobacco) pollen tubes through the sporophytic tissue of the style, and is associated with transition to the second phase of pollen-tube growth. WhenNicotiana pollen tubes are grown in liquid culture, the extent of generative-nucleus division and the timing of this division depend on the chemical composition of the medium. Addition of reduced forms of nitrogen, either as mixed amino-acids (0.03% w/v of an acid hydrolysate of casein) or as 1 mM ammonium chloride, induces division of the generative nucleus in over 90% of the tubes; 3 mM calcium nitrate does not stimulate division. Individual amino-acids differ in their ability to induce this division. Contaminants in some batches of poly(ethylene glycol), which is a major component of pollen-tube growth media, inhibit generative-nucleus division; this inhibition is greater in the absence of nitrogen, which increases the observed nitrogen-dependence of division. Reduced forms of nitrogen are also required for growth of pollen tubes after division, when callose plugs are deposited. In the absence of nitrogen, growth continues until the point where sperm cell production would normally occur, then ceases. Addition of amino-acids or ammonium chloride thus allows cultured pollen tubes ofNicotiana to progress to their second phase of growth. WhenNicotiana pollen is germinated in a complete culture medium at 25–26°C, sperm nuclei are first observed in the growing tubes after about 10 h, and by about 16 h most of the tubes have undergone division; at lower temperatures, division is delayed. The timing of division also varies between species ofNicotiana, but division occurs similarly in self-compatible and self-incompatible species. Anaphase in an individual pollen tube is calculated to take less than 4 min. The resultant sperm nuclei usually trail behind the vegetative nucleus, but a variety of arrangements of the three nuclei are observed.Abbreviations DAPI 4,6-diamidino-2-phenylindole - PEG poly(ethylene glycol) - OG ordinary grade of PEG - SP Specially Purified for Biochemistry grade of PEG     

Cell division orientation in animals

Cell division orientation during animal development can serve to correctly organize and shape tissues, create cellular diversity or both. The underlying cellular mechanism is regulated spindle orientation. Depending on the developmental context, extrinsic signals or intrinsic cues control the correct orientation of the mitotic spindle. Cell geometry has been known to be another determinant of spindle orientation and recent results have shed new light?on the link between cellular shape and cell division orientation. The importance of controlling spindle orientation is manifested in neurodevelopmental defects such as?microcephaly, tumor initiation as well as defects in tissue architecture and cell fate misspecification. Here, we summarize the role of oriented cell division during animal development and also outline the cellular and molecular mechanisms in selected invertebrate and vertebrate systems.     

Cell polarity from cell division

Apical-basal polarity of epithelial cells is critical for their symmetric versus asymmetric division and commonly thought to be established in interphase. In a novel type of cell division termed "mirror-symmetric", apical cell constituents accumulate during M-phase at the cleavage furrow, resulting in epithelial daughter cells with opposite apical-basal polarity.     

Cell division: mid-level management

When a fission yeast cell divides, the anillin-like protein mid1p helps to position the contractile ring in the cell middle. Recent experiments from two groups have shown how the cell-polarity factor pom1p negatively regulates the distribution of mid1p.     

Separation of cell enlargement and division in bean leaves

A method is presented for inducing cell enlargement in intact leaves and leaf strips of Phaseolus vulgaris L. without the complication of cell division. Primary bean leaves complete cell division and stop growing after 10 d in dim red light. Transfer to white light induces expansion (50% in 24 h) which is entirely the consequence of cell enlargement. Leaf strips from red-light-grown seedlings placed in white light and provided external solutes (10 mM KCl+10 mM sucrose) expand at the same rate as intact leaves in the light. This system makes possible future investigation of the mechanism of leaf cell enlargement.     

Cell surface and cell division

A mathematical model of the regulation of cell division is suggested. The model is based on the hypothesis that the process giving rhythm to cell division is located in the cell membrane: i.e., the process of free-radical oxidation of membrane lipids. Much depends on the physical state of the membrane. In the membrane, phase transitions take place because of the changes in lipid composition. These transitions differ in normal and tumor cells: in normal cells they are sharp and hysteretic owing to the presence of a framework (membrane skeleton) on the surface of the membrane, while in tumor cells the integrity of the surface is violated so that the transitions are smooth. This model makes it possible to explain differences in the regulation of normal and cancer cell proliferation. Within the limits of the model, such phenomena as density dependent inhibition of growth, reverse transformation, influence of cyclic AMP and ions of Ca2+ on the cell cycle, the actions of serum and of proteases on the cycle, and so on, are explained. A rational scheme for the appearance of the selective damage found in tumor cells is proposed.     

Cell division by swelling stresses

It is demonstrated that, if the variations of viscosity throughout a cell are considered, swelling stresses may produce elongation and division. To do this it is necessary to generalize Betti's theorem to cover systems containing viscosity gradients and such a generalization is presented. On the basis of two special assumptions it is shown that most of the results of the diffusion drag theory of cell division may be duplicated by the present theory.     

Cell division and morphogenesis in angiosperm embryogenesis

Angiosperm embryogenesis generates the basic body organization of flowering plants. The underlying processes of pattern formation, which establishes the diversity of position-dependent cell fates, and morphogenesis, which brings about the shape of the embryo, may not only involve intercellular communication and controlled cell expansion but also non-random cell divisions. Genetic analysis ofArabidopsisembryogenesis which displays a large invariant pattern of cell divisions suggests that unequal cell divisions segregate cell fates and are thus involved in pattern formation whereas other oriented cell divisions and differential mitotic rates reflect patterning and rather play a role in morphogenesis.     

Cell division and trichome breakage in Beggiatoa

The process ofBeggiatoa trichome division was elucidated through phase-contrast microscopy and transmission and scanning electron microscopy. Trichome breakage and dispersion is accomplished by the formation of sacrificial cells (necridia) at various points within the trichome. Upon dying, the sacrificial cells lyse, dividing the trichome into two daughter trichomes. This process is identical with that found in many oscillatorian blue-green bacteria, but differs from the mechanism of trichome division in most of the other flexuous gliding bacteria. Cellular division within the trichome occurs by septation, involving the cytoplasmic membrane and the electron-dense L2 (peptidoglycan) layer. The outer envelope layers do not take part in division.     

Cell division in the pennate diatomDiatoma vulgare

Protoplasma - Mitosis and cytokinesis in the pennateDiatoma is described. Prior to division, a doubled “Persistent Polar Complex” (PPC), the focus of numerous cytoplasmic microtubules,...     

Cell division in Escherichia coli minB mutants

In Escherichia coli minB mutants, cell division can take place at the cell poles as well as non-polarly in the cell. We have examined growth, division patterns, and nucleoid distribution in individual cells of a minC point mutant and a minB deletion mutant, and compared them to the corresponding wild-type strain and an intR1 strain in which the chromosome is over-replicated. The main findings were as follows. In the minB mutants, polar and non-polar divisions appeared to occur independently of each other. Furthermore, the timing of cell division in the cell cycle was found to be severely affected. In addition, nucleoid conformation and distribution were considerably disturbed. The results obtained call for a re-evaluation of the role of the MinB system in the E. coli cell cycle, and of the concept that limiting quanta of cell division factors are regularly produced during the cell cycle.