DEVELOPMENT OF THE EMBRYONIC CHICKEN THYMUS III. UNEQUAL DIVISION OF LYMPHOID CELLS

Cell division of thymus lymphoid cells from 11- to 17-day old embryonic chickens, as well as chickens just after hatch was investigated on cell smears stained with Giemsa. Unequally dividing cells were observed in the developmental stage of thymocytes. At the telophase of such cells, the cytoplasm of one of two future daughter cells was apparently larger in amount and was sometimes stained deeper than the cytoplasm of its counterpart. Unequal division was also observed in pro-, meta- and anaphase; sometimes a dividing cell had a large cytoplasmic process belonging to one hemisphere, suggesting that only one of the two daughter cells would receive the cytoplasmic process through cell division.
The incidence of unequal division calculated by a rough estimation was around 10% of the total cell division between 11 and 13 days of embryonic development, and decreased progressively thereafter.     

Cell division and nuclear movement in the saccoderm desmidNetrium interruptus

Summary During anaphase in thisNetrium, the reforming daughter nuclei hardly pause at the poles before they elongate and rapidly and smoothly move along the daughter cells in one of the grooves in the chloroplast. Ahead of each nucleus is a pointed mass of cytoplasm that is distinctly striated; straight, mobile strands of cytoplasm emanate from this region ahead of the nucleus. When the nucleus reaches the large vacuole that divides the two chloroplasts, it steadily slides over to the chloroplast surface distal to the cleavage furrow. It then stops moving and slowly expands into the normal interphase morphology.Under the electron microscope, the chromosome-to-pole distance does not decrease much during anaphase (i.e., anaphase A is minimal) and so the half spindles remain about the same length by telophase. The poles of the open spindle are initially broad and contain typical spindle microtubules (MTs). These persist intact during anaphase and become focused upon a discrete Organizing Centre as the daughter nuclei reform. These MTs become a cone-shaped array that creates the pointed cytoplasmic mass ahead of the moving nucleus in live cells. Thus, this placoderm desmid behaves very likeClosterium during division and shows the lack of anaphase A, and the transformation of the telophase spindle into a MT-based motility system, now characteristic of many members of the Zygnematales.Abbreviations MT microtubule - MTOC microtubule organizing centre Dedicated to the memory of Professor Oswald Kiermayer     

Cytoplasmic manifestation of the nuclear membrane's hormone binding capacity during cell division

Binding of insulin and thyrotropic hormone (TSH) to the nuclear membrane of Chang liver cells was demonstrated by qualitative and quantitative cytofluorimetry, which failed to substantiate a similar binding affinity for BSA. It appears that in the dividing cell the binding structures (receptors) of the nuclear membrane migrate in the cytoplasm together with the chromosomes by the end of the prophase and become reorganized in the nucleus around the telophase. The fluorescence which indicated binding also appeared in the midbody region during division of the two daughter cells. These experimental observations strongly suggest that, after cell division, only part of the nuclear membrane's receptor complement has to be resynthesized in the daughter cells, because the receptor number required by a single cell is conserved in cytoplasmic membrane details of nuclear membrane origin.     

Cytoplasmic manifestation of the nuclear membrane's hormone binding capacity during cell division

Summary Binding of insulin and thyrotropic hormone (TSH) to the nuclear membrane of Chang liver cells was demonstrated by qualitative and quantitative cytofluorimetry, which failed to substantiate a similar binding affinity for BSA. It appears that in the dividing cell the binding structures (receptors) of the nuclear membrane migrate in the cytoplasm together with the chromosomes by the end of the prophase and become reorganized in the nucleus around the telophase. The fluorescence which indicated binding also appeared in the midbody region during division of the two daughter cells. These experimental observations strongly suggest that, after cell division, only part of the nuclear membrane's receptor complement has to be resynthesized in the daughter cells, because the receptor number required by a single cell is conserved in cytoplasmic membrane details of nuclear membrane origin.     

The SCARECROW gene's role in asymmetric cell divisions in rice plants

Asymmetric cell division is one of the most important mechanisms in the diversification of cell function and fate. In Arabidopsis, SCARECROW (SCR) is essential for the asymmetric division of the cortex/endodermis progenitor cell in the root. To learn more about how SCR is involved in asymmetric division, we analyzed the rice SCR (OsSCR) expression. In the root tip, OsSCR expression was observed in the endodermal cell layer and downregulated in the daughter cortex cell after asymmetric division, just as with Arabidopsis SCR. In leaf primordia, expression of OsSCR was observed in stomatal and ligule formation. In stomatal development, OsSCR was specifically expressed in the stomatal cell files before formation of guard mother cells (GMCs), and then, its expression was localized in GMCs, when the first asymmetric division occurred to generate the GMCs. Before the second asymmetric division of subsidiary mother cells (SMCs), localized OsSCR expression was observed in SMCs in the area close to the GMCs. Before these asymmetric divisions, the localization of OsSCR mRNA in GMC-forming cells and SMCs was observed in the area of the daughter GMC and subsidiary cells. OsSCR expression was also observed in the initiation area of ligule formation, and its downregulation occurred in the inner L2 cells generated by asymmetric division. Based on these observations, we proposed that OsSCR is involved not only in the asymmetric division of the cortex/endodermis progenitor cell but also during stomata and ligule formation by establishing the polarization of cytoplasm.     

Morphological characterization of the myelopoietic stem cell reserves in the human

According to microkinomatographic observations made on single cells up to ten days in vitro, there are the following laws of growth in haematopoiesis: Small cells will increase in growth up to five times in size, with their morphologic and kinetic properties being preserved, the blood lymphocyte will grow to immunoblasts, the small pluripotent stem cell to bone-marrow histiocytes. When growing, the myelopoietic stem cell may be gradually deviated into all myelopoietic cell lines. Instead of bone-marrow histiocytes it may differentiate to promyelocytes, promonocytes or proerythroblasts, all having an equal nucleus size, when it is induced by serum factors. Apart from histiocytes these large cells are capable of differentiating to a clon of blood cells, such as granulocytes, monocytes or reticulocytes, by several successive divisions of maturity. Contrary to the stimulated lymphocyte, symmetric mitoses will frequently occur, when small pluripotent stem cells are growing to bone-marrow histiocytes to be no further differentiated. Occasionally, asymmetric divisions may also be observed, i.e. one of the daughter cells will differentiate into one of the myelopoietic lines, whereas the other one will remain a progenitor cell. Moreover, there are various pathological mitoses in all progenitor cell sizes, such as endomitosis, cytoplasm fusion after mitosis, nucleus fusion after cytoplasm conjunction or amitotic nucleus division without cytokinesis. They produce megacaryoblasts further differentiating to megacaryocytes by corresponding pathological mitoses. According to our vital observations the pluripotency of the haematopoetic stem cell is being lost step by step.     

Rab24 is Required for Normal Cell Division

Rab24 is an atypical member of the Rab GTPase family whose distribution in interphase cells has been characterized; however, its function remains largely unknown. In this study, we have analyzed the distribution of Rab24 throughout cell division. We have observed that Rab24 was located at the mitotic spindle in metaphase, at the midbody during telophase and in the furrow during cytokinesis. We have also observed partial co‐localization of Rab24 and tubulin and demonstrated its association to microtubules. Interestingly, more than 90% of transiently transfected HeLa cells with Rab24 presented abnormal nuclear connections (i. e. chromatin bridges). Furthermore, in CHO cells stably transfected with GFP‐Rab24wt, we observed a large percentage of binucleated and multinucleated cells. In addition, these cells presented an extremely large size and multiple failures in mitosis, as aberrant spindle formation (metaphase), delayed chromosomes (telophase) and multiple cytokinesis. A marked increase in binucleated, multinucleated and multilobulated nucleus formation was observed in HeLa cells depleted of Rab24. We also present evidence that a fraction of Rab24 associates with microtubules. In addition, Rab24 knock down resulted in misalignment of chromosomes and abnormal spindle formation in metaphase leading to the appearance of delayed chromosomes during late telophase and failures in cytokinesis. Our findings suggest that an adequate level of Rab24 is necessary for normal cell division. In summary, Rab24 modulates several mitotic events, including chromosome segregation and cytokinesis, perhaps through the interaction with microtubules.     

MOM-5 frizzled regulates the distribution of DSH-2 to control C. elegans asymmetric neuroblast divisions

Asymmetric cell divisions produce all 302 neurons of the C. elegans hermaphrodite. Here, we describe a role for a C. elegans Dishevelled homolog, DSH-2, in an asymmetric neuroblast division. In dsh-2 mutants, neurons normally descended from the anterior neuroblast daughter of the ABpl/rpppa blast cell were frequently duplicated, while non-neuronal cells produced by the posterior daughter cell were often missing. These observations indicate that in the absence of dsh-2 function, the posterior daughter cell was transformed into a second anterior-like cell. Loss of mom-5, a C. elegans frizzled homolog, produced a similar phenotype. We also show that the DSH-2 protein localized to the cell cortex in most cells of the embryo. In the absence of MOM-5/Fz, DSH-2 was localized to the cytoplasm, suggesting that MOM-5 regulates asymmetric cell division by controlling the localization of DSH-2. Although all neurons in C. elegans are produced by an invariant pattern of cell divisions, our results indicate that cell signaling may contribute to asymmetric neuroblast division during embryogenesis.     

An Ultrastructural Study on Triggering of Cell Division in Young Pollen Protoplast Culture of Hemerocallis fulva L.

The ultrastructural changes of young pollen protoplasts under culture condition in Hemerocallis fulva were studied. In comparison with the original pollen grains, the pollen protoplasts had been completely deprived of pollen wall, but kept the internal structure intact, including a large vacuole, a thin layer of cytoplasm and a peripherally located nucleus. After 8 days of culture a few pollen protoplasts were triggered to cell division: some of them were just undergoing mitosis with clearly visible chromosomes and spindle fibers; the others already divided into 2-celled units. The two daughter cells were equal or unequal in size but with similar distribution of organelles inside. Besides cell division, there were also free nuclear division, amitosis and formation of micronuclei indicating a diversity of division modes in pollen protoplast culture, A series of changes occurred during the process of induction of cell division, such as locomotion of the nucleus toward the central position, disappearence of the large vacuole, increase of electron density of cytoplasm, increase and activation of organelles, diminishing of starch granules in plastids, etc. However, the regeneration of surface wall was not sufficient it contained mostly vesicles with only a few microfibrits. The wall separating the two daughter cells were either complete or incomplete. The weak capability of wall formation is supposed to be one of the major obstacles which has so far restricted sustained cell divisions of young pollen protoplasts under current culture condition.     

Experimental Modification of Cell Division Patterns in the Root Meristem of Zea mays

In the meristem of the young primary root of maize seedlingsthe first transverse division in the cortex 250 µm fromthe root apex results in two daughter cells of distinctly unequalsize. This division could be rendered equal by raising the seedlingsin up to 7.5% methanol. The pattern of the subsequent two orthree transverse divisions in the cortex, as revealed by thearrangement of the newly divided cells in the resultant cellularpackets, was acropetal in the methanol-treated roots but basipetalin the control roots. The sequence of division within a cellularpacket tended to follow the distribution of cell sizes - largercells divided earlier than smaller cells. A temporary arrestof cell division by exposing roots to cold (5 °C) conditionshad no effect on the sequence of divisions that followed whenthe roots were allowed to recover at 20 °C. The resultssuggest that the normally asymmetric position of the cell wallformed at cytokinesis is subject to active regulation and thatmethanol interferes with this process. The cytoplasm of certaincells in the root meristem was also found to be unequally distributed,as judged by Azure B staining, between the two ends of the cell.Cytoplasmic asymmetry was not directly correlated with inequalityof division, although it too was affected by methanol. Cell polarity, root meristem, unequal division, Zea mays     

Suspension Culture of Endosperm Callus Cell and Amitosis In Vitro

The endosperm calli were induced on MS basic medium supplemented with lppm 2,4-D, 0.5ppm KT and 5% sucrose. The medium which contained lppm BAP, 0.1ppm NAA and 2% sucrose was used for cell suspension culture. In suspension cell culture, amitosis of cleavage division of nucleus have been observed after 5 days of culture. First the nuclear membrane and nucleolus disappeared. The crevice appeared in the center of the nucleus, and the nucleus divided into two daughter nuclei of similar size and each with a nucleolus. The daughter nucleus resembled an eye in shape. Following the emergence of cell wall, the two new unequal cells were produced. Such amitotic division proceeded repeatedly until the callus developed and eventually plantlet regenerated.     

哺乳动物卵母细胞不对称分裂的研究进展

哺乳动物卵母细胞成熟过程需要进行两次连续的不对称分裂,最终形成体积差异巨大的子细胞：大体积的卵母细胞和两种体积较小的极体。不对称分裂现象是哺乳动物卵母细胞减数分裂的典型特征,不对称分裂后的卵母细胞是高度极化的细胞。精卵结合后,细胞重新恢复了对称分裂,但是在卵母细胞减数分裂过程中形成的极性特征却得以保留并影响早期胚胎的极性。本文对近年来在哺乳动物卵母细胞不对称分裂方面的相关研究展开综述,从细胞质不对称分裂和细胞核不对称分裂两个方面对染色体、细胞骨架在哺乳动物卵母细胞不对称分裂中的作用、细胞器在哺乳动物卵母细胞成熟过程中的重组分配、染色体非随机分离等过程进行介绍,旨在从细胞和分子水平阐述哺乳动物卵母细胞不对称分裂的主要机制。     

Spermatogenesis and spermiogenesis in Ascaris lumbricoides Var. suum

Reorganization of the prophase I nucleus marks the beginning of the first meiotic division. A pair of centrioles is present at each pole at metaphase I and mitochondria are not observed in the spindle area. A chromosomal pellicle, which resembles a kinetochore plate but has no apparent association with microtubules, surrounds each autosome at metaphase I and II. The sex body lags behind the autosomes at anaphase I and segregates differentially to one daughter cell. Mitochondria and a pair of centrioles are present in the spindle during the second meiotic division. Localized condensation of chromatin and fusion of the condensed chromatin of the secondary spermatocyte telophase nucleus results in a compact spermatid nucleus. Loss of spermatid cytoplasm is effected by the ejection of a cytophore vesicle.     

Studies on the behavior of meiotic protoplasts

Meiotic protoplasts obtained from lily microsporocytes in late prophase to telophase I were cultured in an enzyme solution which prevents formation of a cell wall around the protoplsts. The removal of the surface wall interfered with nuclear and cell division when the wall was removed prior to metaphase. The main effects were non-segregation of chromosomes and aberrant cytokinesis. In contrast, the absence of a cell wall during the later periods in which actual segregation of the nucleus and cytoplasm takes place did not interfere with the spindle function. The regular process was accomplished through the formation of a cell plate or septum, and 2 hemispheric daughter protoplasts were formed. After that, a furrow was usually formed at the septum in the absence of a surrounding cell wall, and the protoplasts became dumbbell shaped. Some abnormal behavior was also observed using the time lapse technique.     

Roles for polarity and nuclear determinants in specifying daughter cell fates after an asymmetric cell division in the maize leaf

Asymmetric cell divisions occur repeatedly during plant development, but the mechanisms by which daughter cells are directed to adopt different fates are not well understood [1,2]. Previous studies have demonstrated roles for positional information in specification of daughter cell fates following asymmetric divisions in the embryo [3] and root [4]. Unequally inherited cytoplasmic determinants have also been proposed to specify daughter cell fates after some asymmetric cell divisions in plants [1,2,5], but direct evidence is lacking. Here we investigate the requirements for specification of stomatal subsidiary cell fate in the maize leaf by analyzing four mutants disrupting the asymmetric divisions of subsidiary mother cells (SMCs). We show that subsidiary cell fate does not depend on proper localization of the new cell wall during the SMC division, and is not specified by positional information acting on daughter cells after completion of the division. Instead, our data suggest that specification of subsidiary cell fate depends on polarization of SMCs and on inheritance of the appropriate daughter nucleus. We thus provide evidence of a role for unequal inheritance of an intracellular determinant in specification of cell fate after an asymmetric plant cell division.     

Fine structure of the Golgi complex during mitosis of cartilaginous cells in vitro

Chondrocytes were isolated enzymatically from guinea-pig epiphyses and grown in vitro. The fate of the Golgi complex during mitosis in relation to changes in the cytoplasmic microtubules was then studied by transmission electron microscopy. Interphase cells were observed to be polarized, with the Golgi complex occupying a well-defined juxtanuclear area of the cell's cytoplasmic pole. During prophase the cytoplasmic microtubules were largely lost, the nucleus moved to the center of the cell and the Golgi complex dissolved into single dictyosomes spread diffusely throughout the cytoplasm. The distribution of other organelles also changed to a more random pattern. In telophase, i.e. after the completion of nuclear division, the mitotic spindle decomposed and cytoplasmic microtubules reappeared. Furthermore, the organization of the Golgi complex and other organelles returned to that characteristic of interphase cells. Previous studies on cells treated with colchicine have indicated that the polarized distribution of cell organelles is dependent on the presence of intact cytoplasmic micro-tubules. It is suggested that the disappearance of such tubules observed here to be coupled with the disorganization of cell interphase structure fulfills the double function of providing free tubulin units from which to build the mitotic spindle and ensuring an approximately equal distribution of dictyosomes and other organelles to the daughter cells during cytokinesis.     

Fine structure of division in ciliate protozoa. I. Micronuclear mitosis in Blepharisma

The mitotic, micronuclear division of the heterotrichous genus Blepharisma has been studied by electron microscopy. Dividing ciliates were selected from clone-derived mass cultures and fixed for electron microscopy by exposure to the vapor of 2% osmium tetroxide; individual Blepharisma were encapsulated and sectioned. Distinctive features of the mitosis are the presence of an intact nuclear envelope during the entire process and the absence of centrioles at the polar ends of the micronuclear figures. Spindle microtubules (SMT) first appear in advance of chromosome alignment, become more numerous and precisely aligned by metaphase, lengthen greatly in anaphase, and persist through telophase. Distinct chromosomal and continuous SMT are present. At telophase, daughter nuclei are separated by a spindle elongation of more than 40 µ, and a new nuclear envelope is formed in close apposition to the chromatin mass of each daughter nucleus and excludes the great amount of spindle material formed during division. The original nuclear envelope which has remained structurally intact then becomes discontinuous and releases the newly formed nucleus into the cytoplasm. The micronuclear envelope seems to lack the conspicuous pores that are typical of nuclear envelopes. The morphology, size, formation, and function of SMT and the nature of micronuclear division are discussed.     

Origin of nuclear buds and micronuclei in normal and folate-deprived human lymphocytes

Micronuclei are formed from chromosomes and chromosomal fragments that lag behind in anaphase and are left outside daughter nuclei in telophase. They may also be derived from broken anaphase bridges. Nuclear buds, micronucleus-like bodies attached to the nucleus by a thin nucleoplasmic connection, have been proposed to be generated similarly to micronuclei during nuclear division or in S-phase as a stage in the extrusion of extra DNA, possibly giving rise to micronuclei. To better understand these phenomena, we have characterized the contents of 894 nuclear buds and 1392 micronuclei in normal and folate-deprived 9-day cultures of human lymphocytes using fluorescence in situ hybridization with pancentromeric and pantelomeric DNA probes. Such information has not earlier been available for human primary cells. Surprisingly, there appears to be no previous data on the occurrence of telomeres in micronuclei (or buds) of normal human cells in general. Our results suggest that nuclear buds and micronuclei have partly different mechanistic origin. Interstitial DNA without centromere or telomere label was clearly more prevalent in nuclear buds (43%) than in micronuclei (13%). DNA with only telomere label or with both centromere and telomere label was more frequent in micronuclei (62% and 22%, respectively) than in nuclear buds (44% and 10%, respectively). Folate deprivation especially increased the frequency of nuclear buds and micronuclei harboring telomeric DNA and nuclear buds harboring interstitial DNA but also buds and micronuclei with both centromeric and telomeric DNA. According to the model we propose, that micronuclei in binucleate lymphocytes primarily derive from lagging chromosomes and terminal acentric fragments during mitosis. Most nuclear buds, however, are suggested to originate from interstitial or terminal acentric fragments, possibly representing nuclear membrane entrapment of DNA that has been left in cytoplasm after nuclear division or excess DNA that is being extruded from the nucleus.     

Rotation and asymmetry of the mitotic spindle direct asymmetric cell division in the developing central nervous system

The asymmetric segregation of cell-fate determinants and the generation of daughter cells of different sizes rely on the correct orientation and position of the mitotic spindle. In the Drosophila embryo, the determinant Prospero is localized basally and is segregated equally to daughters of similar cell size during epidermal cell division. In contrast, during neuroblast division Prospero is segregated asymmetrically to the smaller daughter cell. This simple switch between symmetric and asymmetric segregation is achieved by changing the orientation of cell division: neural cells divide in a plane perpendicular to that of epidermoblast division. Here, by labelling mitotic spindles in living Drosophila embryos, we show that neuroblast spindles are initially formed in the same axis as epidermal cells, but rotate before cell division. We find that daughter cells of different sizes arise because the spindle itself becomes asymmetric at anaphase: apical microtubules elongate, basal microtubules shorten, and the midbody moves basally until it is positioned asymmetrically between the two spindle poles. This observation contradicts the widely held hypothesis that the cleavage furrow is always placed midway between the two centrosomes.