Distribution of CD133 reveals glioma stem cells self-renew through symmetric and asymmetric cell divisions

Malignant gliomas contain a population of self-renewing tumorigenic stem-like cells; however, it remains unclear how these glioma stem cells (GSCs) self-renew or generate cellular diversity at the single-cell level. Asymmetric cell division is a proposed mechanism to maintain cancer stem cells, yet the modes of cell division that GSCs utilize remain undetermined. Here, we used single-cell analyses to evaluate the cell division behavior of GSCs. Lineage-tracing analysis revealed that the majority of GSCs were generated through expansive symmetric cell division and not through asymmetric cell division. The majority of differentiated progeny was generated through symmetric pro-commitment divisions under expansion conditions and in the absence of growth factors, occurred mainly through asymmetric cell divisions. Mitotic pair analysis detected asymmetric CD133 segregation and not any other GSC marker in a fraction of mitoses, some of which were associated with Numb asymmetry. Under growth factor withdrawal conditions, the proportion of asymmetric CD133 divisions increased, congruent with the increase in asymmetric cell divisions observed in the lineage-tracing studies. Using single-cell-based observation, we provide definitive evidence that GSCs are capable of different modes of cell division and that the generation of cellular diversity occurs mainly through symmetric cell division, not through asymmetric cell division.     

Post-embryonic cell lineages of the nematode,Caenorhabditis elegans

The number of nongonadal nuclei in the free-living soil nematode Caenorhabditis elegans increases from about 550 in the newly hatched larva to about 810 in the mature hermaphrodite and to about 970 in the mature male. The pattern of cell divisions which leads to this increase is essentially invariant among individuals; rigidly determined cell lineages generate a fixed number of progeny cells of strictly specified fates. These lineages range in length from one to eight sequential divisions and lead to significant developmental changes in the neuronal, muscular, hypodermal, and digestive systems. Frequently, several blast cells follow the same asymmetric program of divisions; lineally equivalent progeny of such cells generally differentiate into functionally equivalent cells. We have determined these cell lineages by direct observation of the divisions, migrations, and deaths of individual cells in living nematodes. Many of the cell lineages are involved in sexual maturation. At hatching, the hermaphrodite and male are almost identical morphologically; by the adult stage, gross anatomical differences are obvious. Some of these sexual differences arise from blast cells whose division patterns are initially identical in the male and in the hermaphrodite but later diverge. In the hermaphrodite, these cells produce structures used in egg-laying and mating, whereas, in the male, they produce morphologically different structures which function before and during copulation. In addition, development of the male involves a number of lineages derived from cells which do not divide in the hermaphrodite. Similar postembryonic developmental events occur in other nematode species.     

Lateral root initiation by asymmetrical transverse divisions of pericycle cells in four plant species:Raphanus sativus,Helianthus annuus,Zea mays,andDaucus carota

Summary In roots ofRaphanus sativus, Helianthus annuus, Zea mays, andDaucus carota, lateral root initiation occurs when a pair of neighbouring elongated and highly vacuolated pericycle cells in the same column almost simultaneously undergo asymmetrical transversal division. This produces a pair of very short pericycle cells lying end-to-end, flanked above and below by two longer cells. This occurs because both mitoses occur close to the ends of the neighbouring pericycle cells. The two longer daughter pericycle cells divide again later. In roots of radish, sunflower, and carrot these cells divide transversely and asymmetrically, producing more short cells adjacent to the previous ones. In corn roots, they undergo oblique divisions. Much later, the first pair of short pericycle cells undergoes periclinal divisions. Although such periclinal divisions of pericycle cells are generally thought to mark lateral root initiation, our results show that the first pair of short neighbouring pericycle cells in the same column offers another morphological criterion which permits identification of the site of lateral root initiation, both earlier and nearer to the apex than previously documented.     

Nonapical symmetric divisions underlie horizontal cell layer formation in the developing retina in vivo

Symmetric cell divisions have been proposed to rapidly increase neuronal number late in neurogenesis, but how critical this mode of division is to establishing a specific neuronal layer is unknown. Using in vivo time-lapse imaging methods, we discovered that in the laminated zebrafish retina, the horizontal cell (HC) layer forms quickly during embryonic development upon division of a precursor cell population. The precursor cells morphologically resemble immature, postmitotic HCs and express HC markers such as ptf1a and Prox1 prior to division. These precursors undergo nonapical symmetric division at the laminar location where mature HCs contact photoreceptors. Strikingly, the precursor cell type we observed generates exclusively HCs. We have thus identified a dedicated HC precursor, and our findings suggest a mechanism of neuronal layer formation whereby the location of mitosis could facilitate rapid contact between synaptic partners.     

Developmental Morphology and Histogenesis of Reproductive Structures of the Millet,Panicum miliaceum L. Histogenesis of the Inflorescence and Flower

The branches of successive orders of the inflorescence of Panicum miliaceum L. arise in the axils of the bracts of the branches of next lower order. Their initiation is evidenced by periclinal division of sub-hypodermal cells. The primordia of branches arise in initiation like a normal axillary bud. The floral histogenesis of Panicum miliaceum L. is similar to that of Triticum. Primordia of the spikelet, flower and stamen are initiated by the activity of the periclinal division of the sub-hypodermal cell or cells. Sometimes, periclinal divisions also occur in a few hypodermal cells during these primordial developments; such divisions are more frequent in the formation of the flower and stamen primordia than in the formation of the spikelet primordia. The periclinal division of the dermatogen ceils never occurs in the formation of these organs. Glumes and lemma are initiated in the periclinal division of the dermatogen and hypodermal cell or cells. The primordia of the palea, lodicule and carpel are initiated by means of the periclinal division in the dermatogen cell or cells. In the formation of the palea and carpel, periclinal divisions also occur in hypodermat cells, but their derivatives are protruding into the bases of the primordia and do not constitute the tissues of the palea and carpel. The growing point of the flower axis develops into the ovule. The integuments arise from the periclinal division of dermatogen cells. The periclinal division of dermatogen cells is characteristic of the initiation of the phylloid organs in the Gramineae.     

Cell proliferation in the erythroid compartment of guinea-pig bone marrow: studies with 3H-thymidine.

Single and multiple injections of 3H-TdR have been used for measuring the rate of proliferation in morphologically defined cell populations of guinea-pig bone marrow that are committed to erythroid differentiation. The conclusions are based on the analysis of absolute cell numbers in the maturational compartments, the labeling and mitotic indices, labeled mitotic curves, pulse and chase grain counts over dividing and interphase cells, and on the rate or labeling during multiple, repeated injections of 3H-TdR. The average duration of S and the rate of cycling is similar in all maturational compartments of the erythrom. The majority of cells progress to the next maturational compartment by the time they divide for the second time. All proerythroblasts and basophilic erythroblasts are in cycle. Polychromatic erythroblasts incapable of incorporating 3H-TdR reach the orthochromatic population in the span of 5-6 hr. The orthochromatic population is renewed every 20-24 hr. The number of divisions between the proerythroblast and orthochromatic erythroblast does not exceed four and some cells may undergo only two divisions during the maturation pathway. Cell input from a progenitor cell population contributes to the maintenance of the erythron. The kinetic behavior of progenitor cells is similar to that of proerythroblasts. By the time of their second division, progenitor cells may reach either the proerythroblast or basophilic erythroblast compartments. The kinetic behavior of basophilic transitional cells corresponds to the predicted behavior of the erythroblast progenitor cell pool. Several of the conclusions are based on the assumption that grain count halving is the result of cell division. In view of the evidence discussed, this assumption in the present studies seems justified.     

Morphology of mitochondrial nucleoids, mitochondria, and nuclei during meiosis and sporulation of the yeast Saccharomycodes ludwigii

The morphology of mitochondrial nucleoids (mt-nucleoids), mitochondria, and nuclei was investigated during meiosis and sporulation of the diploid cells of the ascosporogenic yeast Saccharomycodes ludwigii. The mt-nucleoids appeared as discrete dots uniformly distributed in stationary-phase cells as revealed by 4',6-diamidino-2-phenylindole (DAPI) staining. Throughout first and second meiotic divisions, the mt-nucleoids moved to be located close to the dividing nuclei with the appearance of dots. On the other hand, mitochondria, which had tubular or fragmented forms in stationary-phase cells, increasingly fused with each other to form elongated mitochondria during meiotic prophase as revealed by 3,3' -dihexyloxacarbocyanine iodide [DiOC(6)(3)] staining. Mitochondria assembled to be located close to dividing nuclei during first and second meiotic divisions, and were finally incorporated into spores. During the first meiotic division, nuclear division occurred in any direction parallel, diagonally, or perpendicular to the longitudinal axis of the cell. In contrast, the second meiotic division was exclusively parallel to the longitudinal axis of the cell. The behavior of dividing nuclei explains the formation of a pair of spores with opposite mating types at both ends of cells. In the course of this study, it was also found that ledges between two spores were specifically stained with DiOC(6)(3).     

BASL and EPF2 act independently to regulate asymmetric divisions during stomatal development

The initiation of stomatal development in the developing Arabidopsis epidermis is characterized by an asymmetric ‘entry’ division in which a small cell, known as a meristemoid, and a larger daughter cell is formed. The meristemoid may undergo further asymmetric divisions, regenerating a meristemoid each time, before differentiating into a guard mother cell which divides symmetrically to form a pair of guard cells surrounding a stomatal pore. Recently EPF2 and BASL have emerged as regulators of these asymmetric divisions and here we present results indicating that these two factors operate independently to control stomatal developmentKey words: stomata, development, meristemoids, asymmetric cell division, leaf epidermis, cell polarity, peptide signal     

Ultrastructural Studies on the Behavior of Centrioles during Meiosis of Starfish Oocytes

The behavior of centrioles and ultrastructural changes of the nucleus were observed in maturing oocytes of the starfishes, Asterina pectinifera and Asterias amurensis . Observations were focused on the number and behavior of centrioles during two successive meiotic divisions. Examination of serial sections revealed that in meiosis I each division pole has a pair of centrioles, whereas in meiosis II each has only one centriole, confirming the observations by Sluder et al. (1989) on oocytes of Pisaster ocraceus and Asterias forbesi . The first polar body had two centrioles and the second polar body had only one. These results indicate that no duplication of centrioles occurs during the two successive meiotic divisions, and that the egg inherits one centriole from a primary oocyte.     

Histological changes associated with acquisition of competence for shoot regeneration in leaf discs ofSaintpaufla ionantha xconfusa hybrid (African violet) cultured in vitro

In leaf discs ofSaintpaulia ionantha xconfusa hybrid (cv. Virginia) cultured on shoot-inducing medium, periclinal divisions were initiated in epidermal cells 3–5 days after explant isolation. This timing coincided with the time for competence acquisition determined in tissue-transfer experiments. Some of the daughter cells from periclinal divisions formed the target cells which divided both anticlinally and periclinally to form cell division centers (meristemoids), precursors of adventitious shoots. The target cells were not morphologically distinct from other epidermal cells at the light microscope level. It is suggested that the periclinal divisions in epidermal cells represent the dedifferentiation phase during which target (competent) cells are formed. Once the cells have acquired the ability to divide periclinally, both dedifferentiation and shoot induction occur in the presence of exogenous plant hormones.Abbreviations SIM Shoot-inducing medium     

A study of the effect of radium upon the eggs of Ascaris megalocephala univalens

Conclusions My observations support the conclusions ofPerthes andHertwig that the achromatic figure appears perfectly normal; that the first segmentation divisions are regular; and that irregularities enter sooner or later which cause the death of the embryo. They further support the conclusions ofHertwig that the effect of the radium manifests itself in the first segmentation division and that the chromosomes are broken up into irregular masses and granules. In addition to these, I find that in the first segmentation division, the enlarged masses of chromatin which are similar to the cast off ends in the somatic cells of normal segmentation, may or may not take part in nuclear reconstruction and the succeeding division; that the chromatin of the first segmentation division is more greatly disturbed than in the divisions which follow. More important, however, than these is the fact that the chromatin of the sex and somatic cells in the second and third segmentation divisions behaves differently. That is, while the chromosomes of both cells break up, the fragments in the sex cells are generally larger.     

What determines whether chromosomes segregate reductionally or equationally in meiosis?

Normal meiosis consists of a single round of DNA replication followed by two nuclear divisions. In the 1st division the chromosomes segregate reductionally whereas in the 2nd division they segregate equationally (as they do in mitosis). In certain yeast mutants, a single-division meiosis takes place, in which some chromosomes segregate reductionally while others divide equationally. This autonomous segregation behaviour of individual chromosomes on a common spindle is determined by the centromeres they carry. The relationship between reductional segregation of a pair of chromosomes and their earlier recombinational history is also discussed.     

Real-time lineage analysis reveals oriented cell divisions associated with morphogenesis at the shoot apex of Arabidopsis thaliana

Precise knowledge of spatial and temporal patterns of cell division, including number and orientation of divisions, and knowledge of cell expansion, is central to understanding morphogenesis. Our current knowledge of cell division patterns during plant and animal morphogenesis is largely deduced from analysis of clonal shapes and sizes. But such an analysis can reveal only the number, not the orientation or exact rate, of cell divisions. In this study, we have analyzed growth in real time by monitoring individual cell divisions in the shoot apical meristems (SAMs) of Arabidopsis thaliana. The live imaging technique has led to the development of a spatial and temporal map of cell division patterns. We have integrated cell behavior over time to visualize growth. Our analysis reveals temporal variation in mitotic activity and the cell division is coordinated across clonally distinct layers of cells. Temporal variation in mitotic activity is not correlated to the estimated plastochron length and diurnal rhythms. Cell division rates vary across the SAM surface. Cells in the peripheral zone (PZ) divide at a faster rate than in the central zone (CZ). Cell division rates in the CZ are relatively heterogeneous when compared with PZ cells. We have analyzed the cell behavior associated with flower primordium development starting from a stage at which the future flower comprises four cells in the L1 epidermal layer. Primordium development is a sequential process linked to distinct cellular behavior. Oriented cell divisions, in primordial progenitors and in cells located proximal to them, are associated with initial primordial outgrowth. The oriented cell divisions are followed by a rapid burst of cell expansion and cell division, which transforms a flower primordium into a three-dimensional flower bud. Distinct lack of cell expansion is seen in a narrow band of cells, which forms the boundary region between developing flower bud and the SAM. We discuss these results in the context of SAM morphogenesis.     

Delays in anaphase initiation occur in individual nuclei of the syncytial Drosophila embryo.

The syncytial divisions of the Drosophila melanogaster embryo lack some of the well established cell-cycle checkpoints. It has been suggested that without these checkpoints the divisions would display a reduced fidelity. To test this idea, we examined division error frequencies in individuals bearing an abnormally long and rearranged second chromosome, designated C(2)EN. Relative to a normal chromosome, this chromosome imposes additional structural demands on the mitotic apparatus in both the early syncytial embryonic divisions and the later somatic divisions. We demonstrate that the C(2)EN chromosome does not increase the error frequency of the late larva neuroblast divisions. However, in the syncytial embryonic nuclear divisions, the C(2)EN chromosome produces a 10-fold increase in division errors relative to embryos with a normal karyotype. During late anaphase of the neuroblast divisions, the sister C(2)EN chromosomes cleanly separate from one another. In contrast, during late anaphase of the syncytial divisions in C(2)EN-bearing nuclei, large amounts of chromatin often lag on the metaphase plate. Live analysis of C(2)EN-bearing embryos demonstrates that individual nuclei in the syncytial population of dividing nuclei often delay in their initiation of anaphase. These delays frequently lead to division errors. Eventually the products of the nuclei delayed in anaphase sink inward and are removed from the dividing population of syncytial nuclei. These results suggest that the Drosophila embryo may be equipped with mechanisms that monitor the fidelity of the syncytial nuclear divisions. Unlike checkpoints that rely on cell cycle delays to identify and correct division errors, these embryonic mechanisms rely on cell cycle delays to identify and discard the products of division errors.     

Non‐equivalence in old‐ and new‐flagellum daughter cells of a proliferative division in Trypanosoma brucei

Differentiation of Trypanosoma brucei, a flagellated protozoan parasite, between life cycle stages typically occurs through an asymmetric cell division process, producing two morphologically distinct daughter cells. Conversely, proliferative cell divisions produce two daughter cells, which look similar but are not identical. To examine in detail differences between the daughter cells of a proliferative division of procyclic T. brucei we used the recently identified constituents of the flagella connector. These segregate asymmetrically during cytokinesis allowing the new‐flagellum and the old‐flagellum daughters to be distinguished. We discovered that there are distinct morphological differences between the two daughters, with the new‐flagellum daughter in particular re‐modelling rapidly and extensively in early G1. This re‐modelling process involves an increase in cell body, flagellum and flagellum attachment zone length and is accompanied by architectural changes to the anterior cell end. The old‐flagellum daughter undergoes a different G1 re‐modelling, however, despite this there was no difference in G1 duration of their respective cell cycles. This work demonstrates that the two daughters of a proliferative division of T. brucei are non‐equivalent and enables more refined morphological analysis of mutant phenotypes. We suggest all proliferative divisions in T. brucei and related organisms will involve non‐equivalence.     

The cleavage program in the 2d cell lineage of Tubifex embryos

Early development in clitellate annelids is characterized by a highly stereotyped sequence of unequal, spiral cleavages. Cell 2d (i.e., the second micromere of the D quadrant) in the oligochaete Tubifex tubifex also undergoes an evolutionarily conserved sequence of cell division to produce four bilateral pairs of ectodermal teloblasts that act as embryonic stem cells. This study was conducted to characterize each of the 15 rounds of cell division that occur in the 2d cell lineage in this clitellate. After its occurrence, cell 2d undergoes three rounds of highly unequal divisions, giving off the first smaller daughter cell toward the posterior right of the larger daughter cell, the second cell toward the posterior left, and the third cell toward the anterior side of the cell; the larger daughter cell that results from the third division (i.e., the great-granddaughter cell of 2d) then divides equally into a bilateral pair of NOPQ proteloblasts. Cell NOPQ on either side of the embryo undergoes 11 rounds of cell division, during which ectoteloblasts N, Q, and O/P are produced in this order. After its appearance, NOPQ undergoes highly unequal divisions twice cutting off the smaller cells toward the anterior end of the embryo and then divides almost equally into ectoteloblast N and proteloblast OPQ. After its appearance, OPQ undergoes highly unequal divisions twice giving off the first smaller cell toward the anterior and the second smaller cell toward the posterior of the embryo and then divides almost equally into ectoteloblast Q and proteloblast OP. Finally, OP undergoes highly unequal division four times after its birth budding off the smaller cells toward the anterior and then cleaves equally into ectoteloblasts O and P. In the unequally dividing cells of the 2d cell lineage, the mitotic apparatus (MA), which forms at the cell's center, moves eccentrically toward the cortical site where the smaller cell will be given off. The moving MA is oriented perpendicular to the surface it approaches, and its peripheral pole becomes closely associated with the cell cortex. In contrast, the MA involved in the equal divisions remains in the cell center throughout mitosis. The key features of the cleavage program in the 2d cell lineage are discussed in light of the present observations. The mechanical aspects of unequal cleavage in the 2d cell lineage and the modes of specification of MA orientation are discussed. A comparison of the cleavage mode in the 2d cell lineage is also performed among six selected clitellate annelid species.     

SEXUAL REPRODUCTION AND MEIOSIS IN PERIDINIUM INCONSPICUUM LEMMERMANN (DINOPHYCEAE)

In Peridinium inconspicuum Lemmermann, sexual reproduction occurs in both nitrogen-enriched and nitrogen-deficient media. In this homothallic strain, protoplasmic fusion begins between two thecate gametes; but zygote formation is completed in a space outside the fusing pair. This diploid cell can form a plated theca which is shed as the cell enlarges. This spherical zygote then forms a new non-plated theca. The process of ecdysis and the formation of a new non-plated theca is repeated several times. During this process the zygote gradually elongates and by cytoplasmic infurrowing becomes peanut-shaped. Eventually two cells are formed. The first and second meiotic divisions are greatly separated in time. The first meiotic division occurs in the spherical non-thecate zygote. The second meiotic division can occur in the peanut-shaped zygote before it completes cytokinesis. This meiotic division may not be synchronous, occasionally resulting in a trinucleate stage. Eventually four flagellated, haploid products are produced.     

Universal rules for division plane selection in plants

Coordinated cell divisions and cell expansion are the key processes that command growth in all organisms. The orientation of cell divisions and the direction of cell expansion are critical for normal development. Symmetric divisions contribute to proliferation and growth, while asymmetric divisions initiate pattern formation and differentiation. In plants these processes are of particular importance since their cells are encased in cellulosic walls that determine their shape and lock their position within tissues and organs. Several recent studies have analyzed the relationship between cell shape and patterns of symmetric cell division in diverse organisms and employed biophysical and mathematical considerations to develop computer simulations that have allowed accurate prediction of cell division patterns. From these studies, a picture emerges that diverse biological systems follow simple universal rules of geometry to select their division planes and that the microtubule cytoskeleton takes a major part in sensing the geometric information and translates this information into a specific division outcome. In plant cells, the division plane is selected before mitosis, and spatial information of the division plane is preserved throughout division by the presence of reference molecules at a distinct region of the plasma membrane, the cortical division zone. The recruitment of these division zone markers occurs multiple times by several mechanisms, suggesting that the cortical division zone is a highly dynamic region.     

Tissue origins,cell lineages and patterns of cell division in the developing dermal system of the frut of Vitis vinifera L.

Cell division during development of the dermal system of fruit of the grape cv. Gordo is confined to the first growth period. The epidermis is conserved with anticlinal proliferative cell divisions providing for increase in cell number. The hypodermis is the layer of origin of the collenchymatous dermal system. Six or seven layers are differentiated by periclinal cell divisions early in the first growth period, and later increase in size is obtained by proliferative anticlinal cell divisions. These observations are related to developmental and genetic control of fruit shape and volume.