Your search keyword '"Symmetric cell division"' showing total 167 results

51. Dynamics of Asymmetric and Symmetric Divisions of Muscle Stem Cells In Vivo and on Artificial Niches

Author

Shahragim Tajbakhsh, Brendan Evano, Gilles Le Carrou, Sara Khalilian, Geneviève Almouzni, Cellules Souches et Développement / Stem Cells and Development, Institut Pasteur [Paris]-Centre National de la Recherche Scientifique (CNRS), Dynamique du noyau [Institut Curie], Institut Curie [Paris]-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), This work was supported by Institut Pasteur and grants from Agence Nationale de la Recherche ANR, (Laboratoire d’Excellence Revive, Investissement d’Avenir, ANR-10-LABX-73, ANR-16-CE12-0024) and Association Française contre les Myopathies, AFM, le Centre national de la recherche scientifique Centre national de la recherche scientifique, (CNRS), and the European Research Council (Advanced Research Grant 332893).G.A. received support from the French National Research Agency (ANR), Investissement D’avenir Labex développement, épigenèse, épigénétique et potentiel (DEEP), and the European Research Council Advanced (grant ChromAdict)., ANR-10-LABX-0073,REVIVE,Stem Cells in Regenerative Biology and Medicine(2010), ANR-16-CE12-0024,CHIFT,Chaperons et Histones Déterminants pour l'Identité Cellulaire, le Destin de Lignage et les Transitions(2016), ANR-10-IDEX-0001,PSL,Paris Sciences et Lettres(2010), European Project: 332893,332893, European Project: 694694,Chromatin Adaptations through Interactions of Chaperones in Time (ChromADICT), and Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS)

Subjects

0301 basic medicine, Cell division, [SDV]Life Sciences [q-bio], Symmetric cell division, Biology, General Biochemistry, Genetics and Molecular Biology, Germline, Histones, Mice, 03 medical and health sciences, 0302 clinical medicine, Genes, Reporter, Muscle stem cells, symmetric cell division, Asymmetric cell division, medicine, Animals, Cell Lineage, non-random DNA segregation, Transgenes, Stem Cell Niche, lcsh:QH301-705.5, Epigenomics, SNAP-tag, muscle regeneration, Muscles, Stem Cells, Regeneration (biology), Asymmetric Cell Division, Skeletal muscle, DNA, Pax7, Cell biology, Histone 3, 030104 developmental biology, medicine.anatomical_structure, lcsh:Biology (General), Myogenin, Stem cell, 030217 neurology & neurosurgery

Abstract

International audience; Stem cells can be maintained through symmetric cell divisions (SCDs) and asymmetric cell divisions (ACDs). How and when these divisions occur in vivo in vertebrates is poorly understood. Here, we developed a clonogenic cell tracing method that demonstrates the asymmetric distribution of transcription factors along with old and new DNA in mouse muscle stem cells during skeletal muscle regeneration. Combining single-cell tracking and artificial niches ex vivo, we show how cells switch from ACDs to SCDs, suggesting that they are not engaged in an obligate mode of cell division. Further, we generated SNAP-tagged histone H3-reporter mice and find that, unlike fly germline stem cells, differential fate outcomes are associated with a symmetric distribution of the H3.1 and H3.3 histone variants in mouse muscle stem cells. This versatile and efficient H3-SNAP labeling system will allow an investigation of mechanisms underlying the maintenance of epigenomic identity and plasticity in a variety of tissues.; Les cellules souches peuvent être maintenues par des divisions cellulaires symétriques (DCS) et des divisions cellulaires asymétriques (DCA). On comprend mal comment et quand ces divisions se produisent in vivo chez les vertébrés. Ici, nous avons développé une méthode de traçage cellulaire clonogène qui démontre la distribution asymétrique des facteurs de transcription ainsi que de l'ADN ancien et nouveau dans les cellules souches de muscles de souris pendant la régénération des muscles squelettiques. En combinant le traçage d'une seule cellule et des niches artificielles ex vivo, nous montrons comment les cellules passent des ACD aux SCD, ce qui suggère qu'elles ne sont pas engagées dans un mode de division cellulaire obligatoire. En outre, nous avons généré des souris indicatrices d'histone H3 marquées par SNAP et nous avons découvert que, contrairement aux cellules souches germinales de mouches, les résultats différentiels du destin sont associés à une distribution symétrique des variantes d'histone H3.1 et H3.3 dans les cellules souches musculaires de souris. Ce système de marquage H3-SNAP polyvalent et efficace permettra d'étudier les mécanismes sous-jacents au maintien de l'identité et de la plasticité épigénomiques dans une variété de tissus.

Published

2020

52. The mean and noise of stochastic gene transcription with cell division

Author

Qi Wang, Jianshe Yu, Kunwen Wen, and Lifang Huang

Subjects

0301 basic medicine, Cell division, Transcription, Genetic, Stochastic modelling, Cell, Symmetric cell division, Signal-To-Noise Ratio, 03 medical and health sciences, Transcription (biology), Stochastic simulation, Statistics, Asymmetric cell division, medicine, Animals, Humans, Computer Simulation, RNA, Messenger, Mathematics, Stochastic Processes, Models, Genetic, Quantitative Biology::Molecular Networks, Applied Mathematics, Cell Cycle, General Medicine, Mathematical Concepts, Cell cycle, Quantitative Biology::Genomics, Computational Mathematics, 030104 developmental biology, medicine.anatomical_structure, Modeling and Simulation, General Agricultural and Biological Sciences, Cell Division

Abstract

Life growth and development are driven by continuous cell divisions. Cell division is a stochastic and complex process. In this paper, we study the impact of cell division on the mean and noise of mRNA numbers by using a two-state stochastic model of transcription. Our results show that the steady-state mRNA noise with symmetric cell division is less than that with binomial inheritance with probability 0.5, but the steady-state mean transcript level with symmetric division is always equal to that with binomial inheritance with probability 0.5. Cell division except random additive inheritance always decreases mean transcript level and increases transcription noise. Inversely, random additive inheritance always increases mean transcript level and decreases transcription noise. We also show that the steady-state mean transcript level (the steady-state mRNA noise) with symmetric cell division or binomial inheritance increases (decreases) with the average cell cycle duration. But the steady-state mean transcript level (the steady-state mRNA noise) with random additive inheritance decreases (increases) with the average cell cycle duration. Our results are confirmed by Gillespie stochastic simulation using plausible parameters.

Published

2018

53. Asymmetric cell division-dominant neutral drift model for normal intestinal stem cell homeostasis

Author

Jianying Feng, Carson C. Chow, Stephen A. Wank, and Yoshitatsu Sei

Subjects

0301 basic medicine, inorganic chemicals, Intestinal stem cell homeostasis, Physiology, Symmetric cell division, Biology, digestive system, 03 medical and health sciences, Mice, 0302 clinical medicine, Physiology (medical), Lineage tracing, Moran process, Asymmetric cell division, Animals, Homeostasis, Regeneration, Cell Lineage, Intestinal Mucosa, Cells, Cultured, Branching process, Hepatology, Stem Cells, Asymmetric Cell Division, Gastroenterology, LGR5, Cell Differentiation, Cell biology, Intestines, 030104 developmental biology, 030211 gastroenterology & hepatology, Stem cell, Research Article

Abstract

The normal intestinal epithelium is continuously regenerated at a rapid rate from actively cycling Lgr5-expressing intestinal stem cells (ISCs) that reside at the crypt base. Recent mathematical modeling based on several lineage-tracing studies in mice shows that the symmetric cell division-dominant neutral drift model fits well with the observed in vivo growth of ISC clones and suggests that symmetric divisions are central to ISC homeostasis. However, other studies suggest a critical role for asymmetric cell division in the maintenance of ISC homeostasis in vivo. Here, we show that the stochastic branching and Moran process models with both a symmetric and asymmetric division mode not only simulate the stochastic growth of the ISC clone in silico but also closely fit the in vivo stem cell dynamics observed in lineage-tracing studies. In addition, the proposed model with highest probability for asymmetric division is more consistent with in vivo observations reported here and by others. Our in vivo studies of mitotic spindle orientations and lineage-traced progeny pairs indicate that asymmetric cell division is a dominant mode used by ISCs under normal homeostasis. Therefore, we propose the asymmetric cell division-dominant neutral drift model for normal ISC homeostasis.NEW & NOTEWORTHY The prevailing mathematical model suggests that intestinal stem cells (ISCs) divide symmetrically. The present study provides evidence that asymmetric cell division is the major contributor to ISC maintenance and thus proposes an asymmetric cell division-dominant neutral drift model. Consistent with this model, in vivo studies of mitotic spindle orientation and lineage-traced progeny pairs indicate that asymmetric cell division is the dominant mode used by ISCs under normal homeostasis.

Published

2018

54. Centrosomal ALIX regulates mitotic spindle orientation by modulating astral microtubule dynamics

Author

Lene Malerød, Åsmund Husabø Eikenes, Kaisa Haglund, Anette Lie-Jensen, Knut Liestøl, Harald Stenmark, Andreas Brech, Roland Le Borgne, University of Oslo (UiO), Institut de Génétique et Développement de Rennes (IGDR), Structure Fédérative de Recherche en Biologie et Santé de Rennes ( Biosit : Biologie - Santé - Innovation Technologique )-Centre National de la Recherche Scientifique (CNRS)-Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES), 605009, Kreftforeningen, ASTF 391‐2010, EMBO Short Term Fellowship, 2012054, Helse Sør‐Øst RHF (Southern and Eastern Norway Regional Health Authority), 179571, Forskningsrådet (The Research Council of Norway), EL2014‐LNCC, La Ligue National contre Cancer ‐ L'Equipe Labellisée, ANR‐16‐CE13‐004‐01, ANR programme PRC Vie, santé et bien‐être, CytoSIGN, Simon Fougner Hartmann Foundation, Université de Rennes (UR)-Centre National de la Recherche Scientifique (CNRS)-Structure Fédérative de Recherche en Biologie et Santé de Rennes ( Biosit : Biologie - Santé - Innovation Technologique ), University of Oslo ( UiO ), Institut de Génétique et Développement de Rennes ( IGDR ), Université de Rennes 1 ( UR1 ), and Université de Rennes ( UNIV-RENNES ) -Université de Rennes ( UNIV-RENNES ) -Centre National de la Recherche Scientifique ( CNRS ) -Structure Fédérative de Recherche en Biologie et Santé de Rennes ( Biosit : Biologie - Santé - Innovation Technologique )

Subjects

0301 basic medicine, Male, Mitosis, Symmetric cell division, Spindle Apparatus, Biology, Microtubules, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, ALIX, Microtubule, Animals, Drosophila Proteins, Humans, MAP1S, Molecular Biology, Pericentriolar material, Centrosome, [SDV.GEN]Life Sciences [q-bio]/Genetics, General Immunology and Microbiology, General Neuroscience, Stem Cells, Microfilament Proteins, Ovary, Signal transducing adaptor protein, Brain, Epithelial Cells, γ‐tubulin, Articles, Spindle apparatus, Cell biology, 030104 developmental biology, Drosophila, Female, mitotic spindle orientation, Astral microtubules, [ SDV.GEN ] Life Sciences [q-bio]/Genetics, Cytokinesis, HeLa Cells, microtubule

Abstract

International audience; The orientation of the mitotic spindle (MS) is tightly regulated, but the molecular mechanisms are incompletely understood. Here we report a novel role for the multifunctional adaptor protein ALG-2-interacting protein X (ALIX) in regulating MS orientation in addition to its well-established role in cytokinesis. We show that ALIX is recruited to the pericentriolar material (PCM) of the centrosomes and promotes correct orientation of the MS in asymmetrically dividing Drosophila stem cells and epithelial cells, and symmetrically dividing Drosophila and human epithelial cells. ALIX-deprived cells display defective formation of astral microtubules (MTs), which results in abnormal MS orientation. Specifically, ALIX is recruited to the PCM via Drosophila Spindle defective 2 (DSpd-2)/Cep192, where ALIX promotes accumulation of γ-tubulin and thus facilitates efficient nucleation of astral MTs. In addition, ALIX promotes MT stability by recruiting microtubule-associated protein 1S (MAP1S), which stabilizes newly formed MTs. Altogether, our results demonstrate a novel evolutionarily conserved role of ALIX in providing robustness to the orientation of the MS by promoting astral MT formation during asymmetric and symmetric cell division.

Published

2018

55. Zeb1 Regulates the Symmetric Division of Mouse Lewis Lung Carcinoma Stem Cells through Numb mediated by miR-31

Author

Doudou Liu, Tiejun Zhou, Zhiwei Sun, Shixia Zhou, H. Rosie Xing, Yongli Liu, Ting Ye, Liangsheng Kong, Jingyuan Li, Jianyu Wang, and Junlin Tang

Subjects

0301 basic medicine, animal structures, Symmetric cell division, Nerve Tissue Proteins, Biology, Applied Microbiology and Biotechnology, 03 medical and health sciences, Carcinoma, Lewis Lung, Mice, Cancer stem cell, Cell Line, Tumor, Asymmetric cell division, Animals, Humans, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Lewis lung carcinoma, Membrane Proteins, Zinc Finger E-box-Binding Homeobox 1, Cell Biology, Neural stem cell, mir-31, Gene Expression Regulation, Neoplastic, MicroRNAs, 030104 developmental biology, NUMB, Cancer research, Neoplastic Stem Cells, Stem cell, Cell Division, Developmental Biology, Protein Binding

Abstract

Symmetric cell division (SD) and asymmetric cell division (ASD) were the unique characteristics of stem cells and the mechanisms underlying stem cell renewal. While recent studies have identified the presence of SD and ASD in lung cancer stem cells (CSCs), the mechanisms regulating SD and ASD in cancer state have not been elucidated, mostly due to the lack of stable cellular models of SD and ASD in CSC research. In this study, the interaction between Zeb1, an Epithelial-Mesenchymal Transition (EMT) factor shown to regulate CSCs self-renew, and Numb, which regulates SD and ASD in the normal neural stem cell was investigated using the stable mouse Lewis lung adenocarcinoma SD (LLC-SD) and ASD (LLC-ASD) lines established from our previous study. The most significant finding derived from this line of research is that we have identified and molecularly ordered the axis of Zeb1-miR-31-Numb that regulates the SD, a mechanism of CSC self-renewal that has not been previously described. More specifically, the expression of Zeb1 and Numb were both significantly higher in LLC-SD than LLC-ASD cells. Silencing of Zeb1 or Numb expression lead to decreased ratio of SD and weakened single-cell cloning formation, tumor growth and tumor metastasis, respectively. The rescure experiments have molecularly ordered the regulation of Numb by Zeb1, indirectly mediated by miR-31. Moreover, we also provided preliminary evidence supporting the clinical relevance of our finding. In summary, our study provides a new insight for the self-renew of lung CSCs in which SD is regulated by the axis of Zeb1-miR-31-Numb.

Published

2018

56. Asymmetric cell division in Mycobacterium tuberculosis and its unique features

Author

Parthasarathi Ajitkumar, Srinivasan Vijay, Mukkayyan Nagaraja, and Jees Sebastian

Subjects

Cell division, Population, Symmetric cell division, Biochemistry, Microbiology, Time-Lapse Imaging, Mycobacterium, Mycobacterium tuberculosis, Microscopy, Electron, Transmission, Genetics, Asymmetric cell division, Humans, Tuberculosis, education, Molecular Biology, Mycobacterium marinum, Microbiology & Cell Biology, Mycobacterium bovis, education.field_of_study, biology, Mycobacterium smegmatis, Asymmetric Cell Division, Sputum, General Medicine, biology.organism_classification, Microscopy, Fluorescence

Abstract

Recently, several reports showed that about 80 % of mid-log phase Mycobacterium smegmatis, Mycobacterium marinum, and Mycobacterium bovis BCG cells divide symmetrically with 5–10 % deviation in the septum position from the median. However, the mode of cell division of the pathogenic mycobacterial species, Mycobacterium tuberculosis, remained unclear. Therefore, in the present study, using electron microscopy, fluorescence microscopy of septum- and nucleoid-stained live and fixed cells, and live cell time-lapse imaging, we show the occurrence of asymmetric cell division with unusually deviated septum/constriction in 20 % of the 15 % septating M. tuberculosis cells in the mid-log phase population. The remaining 80 % of the 15 % septating cells divided symmetrically but with 2–5 % deviation in the septum/constriction position, as reported for M. smegmatis, M. marinum, and M. bovis BCG cells. Both the long and the short portions of the asymmetrically dividing M. tuberculosis cells with unusually deviated septum contained nucleoids, thereby generating viable short and long cells from each asymmetric division. M. tuberculosis short cells were acid fast positive and, like the long cells, further readily underwent growth and division to generate micro-colony, thereby showing that they were neither mini cells, spores nor dormant forms of mycobacteria. The freshly diagnosed pulmonary tuberculosis patients’ sputum samples, which are known for the prevalence of oxidative stress conditions, also contained short cells at the same proportion as that in the mid-log phase population. The probable physiological significance of the generation of the short cells through unusually deviated asymmetric cell division is discussed.

Published

2018

57. The intracellular and intercellular cross-talk during subsidiary cell formation in Zea mays: existing and novel components orchestrating cell polarization and asymmetric division

Author

Emmanuel Panteris, Basil Galatis, Panagiotis Apostolakos, Pantelis Livanos, and Eleni Giannoutsou

Subjects

0301 basic medicine, Cell type, Cell division, Morphogenesis, Reviews, Cell Polarity, Symmetric cell division, Plant Science, Receptor Cross-Talk, Biology, Zea mays, Cell biology, 03 medical and health sciences, 030104 developmental biology, Guard cell, Cell polarity, Mitosis, Intracellular, Cell Division, Plant Proteins

Abstract

BACKGROUND: Formation of stomatal complexes in Poaceae is the outcome of three asymmetric and one symmetric cell division occurring in particular leaf protodermal cells. In this definite sequence of cell division events, the generation of subsidiary cells is of particular importance and constitutes an attractive model for studying local intercellular stimulation. In brief, an induction stimulus emitted by the guard cell mother cells (GMCs) triggers a series of polarization events in their laterally adjacent protodermal cells. This signal determines the fate of the latter cells, forcing them to divide asymmetrically and become committed to subsidiary cell mother cells (SMCs). SCOPE: This article summarizes old and recent structural and molecular data mostly derived from Zea mays, focusing on the interplay between GMCs and SMCs, and on the unique polarization sequence occurring in both cell types. Recent evidence suggests that auxin operates as an inducer of SMC polarization/asymmetric division. The intercellular auxin transport is facilitated by the distribution of a specific transmembrane auxin carrier and requires reactive oxygen species (ROS). Interestingly, the local differentiation of the common cell wall between SMCs and GMCs is one of the earliest features of SMC polarization. Leucine-rich repeat receptor-like kinases, Rho-like plant GTPases as well as the SCAR/WAVE regulatory complex also participate in the perception of the morphogenetic stimulus and have been implicated in certain polarization events in SMCs. Moreover, the transduction of the auxin signal and its function are assisted by phosphatidylinositol-3-kinase and the products of the catalytic activity of phospholipases C and D. CONCLUSION: In the present review, the possible role(s) of each of the components in SMC polarization and asymmetric division are discussed, and an overall perspective on the mechanisms beyond these phenomena is provided.

Published

2018

58. SCF/SCFR Signaling Plays an Important Role in the Early Morphogenesis and Neurogenesis of Human Embryonic Neural Retina

Author

Zheng Qin Yin, Qiyou Li, Linlin Ge, Yijian Li, Xiangyu He, Juncai He, Haiwei Xu, Yu Gong, Baishijiao Bian, and Yuxiao Zeng

Subjects

Neurogenesis, Morphogenesis, Stem cell factor, Symmetric cell division, Biology, Retina, 03 medical and health sciences, 0302 clinical medicine, Vasculogenesis, medicine, Humans, Molecular Biology, 030304 developmental biology, 0303 health sciences, Early embryonic stage, Retinal pigment epithelium, Stem Cells, Apical constriction, Cell Differentiation, Cell migration, Embryo, Mammalian, Embryonic stem cell, Cell biology, Proto-Oncogene Proteins c-kit, medicine.anatomical_structure, sense organs, 030217 neurology & neurosurgery, Developmental Biology, Signal Transduction

Abstract

Background: The stem cell factor receptor (SCFR) has been demonstrated to be expressed in the neural retina of mice, rat, and human for decades. Previous reports indicate that SCFR correlates with glia differentiation of late retinal progenitor cells, retinal vasculogenesis, and homeostasis of the blood-retinal barrier. However, the role of SCF/SCFR signaling in the growth and development of the neural retina (NR), especially in the early embryonic stage, remains poorly understood. Methods: Human optic cup (OC) cultures were generated from human embryonic stem cells (hESCs) with SFEBq method. The angle between retinal pigment epithelium (RPE) and NR, the axial length of OC, and the length of the ciliary marginal zone (CMZ) were measured. Proliferation, mechanical dynamic, and cellular migration were assessed with BrdU labeling and quantitative immunofluorescence. Findings: We show that the SCF/SCFR signaling orchestrates invagination of the NR via regulation of symmetric cell division, cytoskeleton dynamic, and apical constriction of retinal progenitor cells in the CMZ. Furthermore, activation of SCF/SCFR signaling enhances neurogenesis in the central-most NR via accelerating the migration of immature ganglion cells. Interpretation: Our study reveals an important role of SCF/SCFR signaling in controlling ciliary marginal cellular behaviors during early morphogenesis and neurogenesis of the human embryonic NR, providing a new potential therapeutic target for human congenital eye diseases such as anophthalmia, microphthalmia, and congenital high myopia. Funding Statement: This study was supported by the National Key R&D program of China (2018YFA01017302), National Basic Research Program of China (2013CB967002) and National Natural Science Foundation of China (81873688). Declaration of Interests: All authors declare no competing interests. Ethics Approval Statement: All experiments were performed in accordance with the guidelines of the Ethics Committee of Southwest Hospital, The Army Medical University.

Published

2018

59. MCM2 promotes symmetric inheritance of modified histones during DNA replication

Author

Caroline B Strømme, Robin Andersson, Nataliya Petryk, Alice Wenger, Anne Strandsby, Maria Dalby, and Anja Groth

Subjects

0301 basic medicine, Multidisciplinary, biology, Cell division, DNA replication, Helicase, Symmetric cell division, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Histone, chemistry, biology.protein, Histone code, Sister chromatids, DNA

Abstract

How cells ensure symmetric inheritance Parental histones with modifications are recycled to newly replicated DNA strands during genome replication, but do the two sister chromatids inherit modified histones equally? Yu et al. and Petryk et al. found in mouse and yeast, respectively, that modified histones are segregated to both DNA daughter strands in a largely symmetric manner (see the Perspective by Ahmad and Henikoff). However, the mechanisms ensuring this symmetric inheritance in yeast and mouse were different. Yeasts use subunits of DNA polymerase to prevent the lagging-strand bias of parental histones, whereas in mouse cells, the replicative helicase MCM2 counters the leading-strand bias. Science , this issue p. 1386 , p. 1389 ; see also p. 1311

Published

2018

60. Ubiquitin in regulation of spindle apparatus and its positioning: implications in development and disease

Author

Oishee Chakrabarti and Devika Srivastava

Subjects

biology, Ubiquitin, Ubiquitin-Protein Ligases, Dynein, Symmetric cell division, Spindle Apparatus, Cell Biology, SIAH1, Disease, Microtubules, Biochemistry, Spindle apparatus, Cell biology, BARD1, biology.protein, Humans, Molecular Biology, Mitosis

Abstract

Emerging data implicates ubiquitination, a post-translational modification, in regulating essential cellular events, one of them being mitosis. In this review we discuss how various E3 ligases modulate the cortical proteins such as dynein, LGN, NuMa, Gα, along with polymerization, stability, and integrity of spindles. These are responsible for regulating symmetric cell division. Some of the ubiquitin ligases regulating these proteins include PARK2, BRCA1/BARD1, MGRN1, SMURF2, and SIAH1; these play a pivotal role in the correct positioning of the spindle apparatus. A direct connection between developmental or various pathological disorders and the ubiquitination mediated cortical regulation is rather speculative, though deletions or mutations in them lead to developmental disorders and disease conditions.

Published

2015

61. Selective chromatid segregation mechanism for Bruchus wings piebald color

Author

Amar J. S. Klar

Subjects

Genetics, Models, Genetic, General Immunology and Microbiology, Somatic cell, Pigmentation, Symmetric cell division, Biology, Chromatids, Sister chromatid segregation, General Biochemistry, Genetics and Molecular Biology, Epigenesis, Genetic, Chromosome segregation, Coleoptera, Phenotype, Chromosome Segregation, Schizosaccharomyces, Asymmetric cell division, Morphogenesis, Animals, Wings, Animal, Chromatid, Imprinting (psychology), Black spot

Abstract

The mechanisms of asymmetric organ development have been under intensive investigation for years, yet the proposed mechanisms remain controversial (1-3). The female Bruchus quadrimaculatus beetle insect develops two black-colored spots bilaterally located on each upper elytra wing by an unknown mechanism. Fifty percent of the P (for piebald, two colors) gene homozygous mutant insects, described in 1925, had a normal left elytrum (with two black spots) and an abnormal right elytrum (with two red spots) and the balance supported the converse lateralized pigment arrangement (4). Rather than supporting the conventional morphogen model for the wings pigmentation development, their biological origin is explained here with the somatic strand-specific epigenetic imprinting and selective sister chromatid segregation (SSIS) mechanism (5). We propose that the P gene product performs the selective sister chromatid segregation function to produce symmetric cell division of a specific cell during embryogenesis to result in the bilateral symmetric development of elytra black color spots and that the altered chromatid segregation pattern of the mutant causes asymmetric cell division to confer the piebald phenotype.

Published

2015

62. STEM-40. THE ROLE OF SYMMETRIC CELL DIVISION IN POST THERAPY GLIOMA STEM CELL EXPANSION

Author

Cheol Park, Robert Hall, Shivani Baisiwala, and Atique Ahmed

Subjects

Cancer Research, endocrine system, business.industry, fungi, Symmetric cell division, Biology, medicine.disease, Abstracts, Text mining, Oncology, Glioma, medicine, Cancer research, Neurology (clinical), Stem cell, business

Abstract

Glioblastoma is an aggressive primary malignancy of the brain with almost 100% recurrence rate. Our lab and others have shown that GBM contains a subpopulation of glioma stem cells (GSCs) that may drive the therapeutic resistance capabilities of recurrent GBM. We have shown that the GSC population expands following administration of temozolomide (TMZ). While it has been suggested that this expansion relies solely on Darwinian selection, we and others have demonstrated that cellular plasticity-driven expansion of therapy resistance GSCs post-therapy may play a role in disease recurrence. GSCs can divide in three ways: (1) asymmetric division, which produces one GSC and one differentiated cancer cell, (2) symmetric division that promotes self-renewal by forming two daughter GSCs or (3) symmetric division that supports differentiation by forming two mature cancer cells. Here, we show that symmetric self-renewing cell division—where one GSC gives rise to two daughter GSCs—occurs at a rate of 24% in GBM cells treated with control vehicle, yet at a rate of 54% following TMZ therapy (p

Published

2017

63. PLK1-mediated phosphorylation of WDR62/MCPH2 ensures proper mitotic spindle orientation

Author

Hideshi Kawakami, Shinya Matsuura, Hirofumi Ohashi, Yoshinori Masatsuna, Akihiro Fukumitsu, Tatsuo Miyamoto, Hiroyuki Morino, Kosuke Hosoba, Silvia Natsuko Akutsu, Takashi Yamamoto, and Kenji Shimizu

Subjects

0301 basic medicine, Male, Cellular pathology, Mutation, Missense, Mitosis, Symmetric cell division, Cell Cycle Proteins, Nerve Tissue Proteins, Spindle Apparatus, Biology, Protein Serine-Threonine Kinases, PLK1, Microtubules, Spindle pole body, Cell Line, 03 medical and health sciences, Microtubule, Pregnancy, Proto-Oncogene Proteins, Genetics, Humans, Gene Knock-In Techniques, Phosphorylation, Molecular Biology, Genetics (clinical), Centrosome, Base Sequence, Infant, Newborn, General Medicine, HCT116 Cells, Spindle apparatus, Cell biology, 030104 developmental biology, Microcephaly, Female, Astral microtubules, Cell Division

Abstract

Primary microcephaly (MCPH) is an autosomal recessive disorder characterized by congenital reduction of head circumference. Here, we identified compound heterozygous mutations c.731 C > T (p.Ser 244 Leu) and c.2413 G > T (p.Glu 805 X) in the WDR62/MCPH2 gene, which encodes the mitotic centrosomal protein WDR62, in two siblings in a Japanese family with microcephaly using whole-exome sequencing. However, the molecular and cellular pathology of microcephaly caused by WDR62/MCPH2 mutation remains unclear. To clarify the physiological role of WDR62, we used the CRISPR/Cas9 system and single-stranded oligonucleotides as a point-mutation-targeting donor to generate human cell lines with knock-in of WDR62/MCPH2 c.731 C > T (p.Ser 244 Leu) missense mutation. In normal metaphase, the mitotic spindle forms parallel to the substratum to ensure symmetric cell division, while WDR62/MCPH2-mutated cells exhibited a randomized spindle orientation caused by the impaired astral microtubule assembly. It was shown that a mitotic kinase, Polo-like kinase 1 (PLK1), is required for the maintenance of spindle orientation through astral microtubule development. In this study, we demonstrated that WDR62 is a PLK1 substrate that is phosphorylated at Ser 897, and that this phosphorylation at the spindle poles promotes astral microtubule assembly to stabilize spindle orientation. Our findings provide insights into the role of the PLK1-WDR62 pathway in the maintenance of proper spindle orientation.

Published

2017

64. Symmetry Does not Come for Free: Cellular Mechanisms to Achieve a Symmetric Cell Division

Author

Damian Dudka and Patrick Meraldi

Subjects

0301 basic medicine, Cell division, Computer science, Symmetric cell division, Spindle pole body, Symmetry (physics), Spindle apparatus, Combinatorics, 03 medical and health sciences, 030104 developmental biology, Cell cortex, Asymmetric cell division, Mitosis, Neuroscience

Abstract

During mitosis cells can divide symmetrically to proliferate or asymmetrically to generate tissue diversity. While the mechanisms that ensure asymmetric cell division have been extensively studied, it is often assumed that a symmetric cell division is the default outcome of mitosis. Recent studies, however, imply that the symmetric nature of cell division is actively controlled, as they reveal numerous mechanisms that ensure the formation of equal-sized daughter cells as cells progress through cell division. Here we review our current knowledge of these mechanisms and highlight possible key questions in the field.

Published

2017

65. Asymmetric inheritance of cytoophidia in Schizosaccharomyces pombe

Author

Jing Zhang, Lydia Hulme, and Ji-Long Liu

Subjects

Cell division, QH301-705.5, Science, Cell, Symmetric cell division, Biology, General Biochemistry, Genetics and Molecular Biology, medicine, Nucleotide, Biology (General), Asymmetric inheritance, CTP synthase, chemistry.chemical_classification, Genetics, biology.organism_classification, medicine.anatomical_structure, chemistry, Cytoplasm, Schizosaccharomyces pombe, Intracellular compartmentation, Cytoophidium, General Agricultural and Biological Sciences, Nucleus, Research Article

Abstract

A general view is that Schizosaccharomyces pombe undergoes symmetric cell division with two daughter cells inheriting equal shares of the content from the mother cell. Here we show that CTP synthase, a metabolic enzyme responsible for the de novo synthesis of the nucleotide CTP, can form filamentous cytoophidia in the cytoplasm and nucleus of S. pombe cells. Surprisingly, we observe that both cytoplasmic and nuclear cytoophidia are asymmetrically inherited during cell division. Our time-lapse studies suggest that cytoophidia are dynamic. Once the mother cell divides, the cytoplasmic and nuclear cytoophidia independently partition into one of the two daughter cells. Although the two daughter cells differ from one another morphologically, they possess similar chances of inheriting the cytoplasmic cytoophidium from the mother cell, suggesting that the partition of cytoophidium is a stochastic process. Our findings on asymmetric inheritance of cytoophidia in S. pombe offer an exciting opportunity to study the inheritance of metabolic enzymes in a well-studied model system.

Published

2014

66. Evaluating the immortal strand hypothesis in cancer stem cells: Symmetric/self-renewal as the relevant surrogate marker of tumorigenicity

Author

Amy B. Hall, Brinley Furey, Brenda K. Eustace, and Raymond J. Winquist

Subjects

DNA Replication, Pharmacology, Genetics, Cell division, Carcinogenesis, Cellular differentiation, Symmetric cell division, Biology, Biochemistry, Immortal DNA strand hypothesis, Cell biology, Cancer stem cell, Neoplastic Stem Cells, Asymmetric cell division, Animals, Humans, Epigenetics, Stem cell, Biomarkers, Cell Proliferation

Abstract

Stem cells subserve repair functions for the lifetime of the organism but, as a consequence of this responsibility, are candidate cells for accumulating numerous genetic and/or epigenetic aberrations leading to malignant transformation. However, given the importance of this guardian role, stem cells likely harbor some process for maintaining their precious genetic code such as non-random segregation of chromatid strands as predicted by the Immortal Strand Hypothesis (ISH). Discerning such non-random chromosomal segregation and asymmetric cell division in normal or cancer stem cells has been complicated by methodological shortcomings but also by differing division kinetics amongst tissues and the likelihood that both asymmetric and symmetric cell divisions, dictated by local extrinsic factors, are operant in these cells. Recent data suggest that cancer stem cells demonstrate a higher incidence of symmetric versus asymmetric cell division with both daughter cells retaining self-renewal characteristics, a profile which may underlie poorly differentiated morphology and marked clonal diversity in tumors. Pathways and targets are beginning to emerge which may provide opportunities for preventing such a predilection in cancer stem cells and that will hopefully translate into new classes of chemotherapeutics in oncology. Thus, although the existence of the ISH remains controversial, the shift of cell division dynamics to symmetric random chromosome segregation/self-renewal, which would negate any likelihood of template strand retention, appears to be a surrogate marker for the presence of highly malignant tumorigenic cell populations.

Published

2014

67. CLONAL DYNAMICS OF EMBRYONIC AND EARLY-POST-BIRTH BLOOD PRECURSORS

Author

David Finkelstein, Miguel Ganuza, Shannon McKinney-Freeman, and Ashley Chabot

Subjects

Cancer Research, Hematopoietic stem cell, Symmetric cell division, Embryo, Cell Biology, Hematology, Biology, Embryonic stem cell, Cell biology, Transplantation, Haematopoiesis, medicine.anatomical_structure, embryonic structures, Genetics, medicine, Bone marrow, Progenitor cell, Molecular Biology

Abstract

In the mouse the first Hematopoietic Stem Cell (HSC) is detected by transplantation at embryonic day E10.5. HSC emerge in the Aorta-Gonad-Mesonephros Region and migrate to the Fetal Liver (FL) where they supposedly expand dramatically (about 20-fold) between day E12.5-E15.5. HSC then migrate to the Bone Marrow (BM), where they predominantly reside in adult life. We recently reported that lifelong hematopoiesis is established by hundreds of blood precursors throughout mouse ontogeny (Ganuza et al., NCB 2017). Our novel non-invasive approach (based on the inducible multi-color ROSA26Confetti reporter) has allowed us to re-interrogate the clonal dynamics of blood precursors during steady-state without perturbing embryogenesis or using transplantation as a read-out for HSC potential. Here, we applied this approach to interrogate the clonal dynamics of embryonic (E14-E19) and neonatal (P1-P21) hematopoietic precursors. Towards this, Confetti labeling of blood progenitors at discrete stages of development was induced by treating ROSA26(+/Confetti) Ubiquitin(+/ERT2-Cre) (UbiqERT2-Cre) embryos or neonates with tamoxifen at E12-E14, E15-E17, P1, P8-P9, P14-15 or P21-P22. In contrast to previous dogma, we failed to detect a 20-fold expansion in the number of blood precursors during the presumed FL expansion period. Rather, between E11.5 and E15.5 we observed a three-fold expansion in blood precursors that contribute to adult peripheral blood. This was followed by a two-fold expansion in these same precursors between E15.5 and P1 and a 1.5-fold expansion between P1 and P8. These results contribute to our understanding of the precise developmental windows (and presumably niches) that support the symmetric cell division of HSCs.

Published

2019

68. Metabolic Imaging Reveals a Unique Preference of Symmetric Cell Division and Homing of Leukemia-Initiating Cells in an Endosteal Niche

Author

Bo O. Zhou, Junke Zheng, Yi Yang, Xiaoxiao He, Dan Huang, Chiqi Chen, Cheng Cheng Zhang, Yaping Zhang, Yuzheng Zhao, Guo-Qiang Chen, Xiaoyun Lai, Li Xie, Zhuo Yu, Xiaocui Zhang, Xiaoxin Hao, Hui Sophie Shu, Hao Gu, and Yejun Zou

Subjects

0301 basic medicine, Physiology, Niche, Mice, Transgenic, Symmetric cell division, Mice, SCID, Biology, Mice, 03 medical and health sciences, 0302 clinical medicine, Mice, Inbred NOD, medicine, Animals, Stem Cell Niche, Clonogenic assay, Molecular Biology, Myeloid leukemia, Cell Biology, medicine.disease, Cell biology, Mice, Inbred C57BL, Disease Models, Animal, Leukemia, Myeloid, Acute, Leukemia, 030104 developmental biology, medicine.anatomical_structure, Bone marrow, Stem cell, Cell Division, 030217 neurology & neurosurgery, Homing (hematopoietic)

Abstract

Summary The metabolic properties of leukemia-initiating cells (LICs) in distinct bone marrow niches and their relationships to cell-fate determinations remain largely unknown. Using a metabolic imaging system with a highly responsive genetically encoded metabolic sensor, SoNar, we reveal that SoNar-high cells are more glycolytic, enriched for higher LIC frequency, and develop leukemia much faster than SoNar-low counterparts in an MLL-AF9-induced murine acute myeloid leukemia model. SoNar-high cells mainly home to and locate in the hypoxic endosteal niche and maintain their activities through efficient symmetric division. SoNar can indicate the dynamics of metabolic changes of LICs in the endosteal niche. SoNar-high human leukemia cells or primary samples have enhanced clonogenic capacities in vitro or leukemogenesis in vivo. PDK2 fine-tunes glycolysis, homing, and symmetric division of LICs. These findings provide a unique angle for the study of metabolisms in stem cells, and may lead to development of novel strategies for cancer treatment.

Published

2019

69. Rate of Progression through a Continuum of Transit-Amplifying Progenitor Cell States Regulates Blood Cell Production

Author

Jideofor Ezike, M. Inmaculada Barrasa, Styliani Markoulaki, Clement Ma, Huan Yang, Zoë A. Feder, Harvey F. Lodish, Hojun Li, Anirudh Natarajan, and Yenthanh Le

Subjects

Erythrocytes, Cell division, Cellular differentiation, Cell, Symmetric cell division, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Transcriptome, Mice, 03 medical and health sciences, 0302 clinical medicine, Erythroid Cells, medicine, Animals, Erythropoiesis, Progenitor cell, Glucocorticoids, Molecular Biology, Cells, Cultured, Cell Proliferation, 030304 developmental biology, Progenitor, Erythroid Precursor Cells, 0303 health sciences, Blood Cells, High-Throughput Nucleotide Sequencing, Cell Differentiation, Cell Biology, Hematopoiesis, Cell biology, Haematopoiesis, medicine.anatomical_structure, Single-Cell Analysis, Cell Division, 030217 neurology & neurosurgery, Developmental Biology

Abstract

© 2019 Elsevier Inc. The nature of cell-state transitions during the transit-amplifying phases of many developmental processes—hematopoiesis in particular—is unclear. Here, we use single-cell RNA sequencing to demonstrate a continuum of transcriptomic states in committed transit-amplifying erythropoietic progenitors, which correlates with a continuum of proliferative potentials in these cells. We show that glucocorticoids enhance erythrocyte production by slowing the rate of progression through this developmental continuum of transit-amplifying progenitors, permitting more cell divisions prior to terminal erythroid differentiation. Mechanistically, glucocorticoids prolong expression of genes that antagonize and slow induction of genes that drive terminal erythroid differentiation. Erythroid progenitor daughter cell pairs have similar transcriptomes with or without glucocorticoid stimulation, indicating largely symmetric cell division. Thus, the rate of progression along a developmental continuum dictates the absolute number of erythroid cells generated from each transit-amplifying progenitor, suggesting a paradigm for regulating the total output of differentiated cells in numerous other developmental processes. Li et al. utilize single-cell RNA-seq and functional assays to demonstrate erythropoiesis progresses through a continuum of both transcriptomic and phenotypic states. Perturbation of developmental progression through this continuum with glucocorticoid steroids reveals differentiation speed can be uncoupled from cell-cycle progression, generating greater numbers of erythrocytes.

Published

2019

70. An Accelerated Method for Simulating Population Dynamics

Author

Daniel A. Charlebois and Mads Kærn

Subjects

Biochemical kinetics, education.field_of_study, Physics and Astronomy (miscellaneous), Population model, Computer science, Dynamics (mechanics), Monte Carlo method, Population, Benchmark (computing), Symmetric cell division, Parameter space, Biological system, education

Abstract

We present an accelerated method for stochastically simulating the dynamics of heterogeneous cell populations. The algorithm combines a Monte Carlo approach for simulating the biochemical kinetics in single cells with a constant-number Monte Carlo method for simulating the reproductive fitness and the statistical characteristics of growing cell populations. To benchmark accuracy and performance, we compare simulation results with those generated from a previously validated population dynamics algorithm. The comparison demonstrates that the accelerated method accurately simulates population dynamics with significant reductions in runtime under commonly invoked steady-state and symmetric cell division assumptions. Considering the increasing complexity of cell population models, the method is an important addition to the arsenal of existing algorithms for simulating cellular and population dynamics that enables efficient, coarse-grained exploration of parameter space.

Published

2013

71. Single-Molecule Genomic Data Delineate Patient-Specific Tumor Profiles and Cancer Stem Cell Organization

Author

Andrea Sottoriva, Christina Curtis, Inmaculada Spiteri, Simon Tavaré, and Darryl Shibata

Subjects

Adult, Cancer Research, Colorectal cancer, Symmetric cell division, Biology, Bioinformatics, Article, Malignant transformation, Cancer stem cell, medicine, Humans, Cell Lineage, Computer Simulation, Precision Medicine, Aged, 80 and over, Gene Expression Profiling, Computational Biology, Cancer, Middle Aged, medicine.disease, Transplantation, Gene expression profiling, Cell Transformation, Neoplastic, Oncology, Tumor progression, Neoplastic Stem Cells, Cancer research, Colorectal Neoplasms, Transcriptome, Microdissection

Abstract

Substantial evidence supports the concept that cancers are organized in a cellular hierarchy with cancer stem cells (CSC) at the apex. To date, the primary evidence for CSCs derives from transplantation assays, which have known limitations. In particular, they are unable to report on the fate of cells within the original human tumor. Because of the difficulty in measuring tumor characteristics in patients, cellular organization and other aspects of cancer dynamics have not been quantified directly, although they likely play a fundamental role in tumor progression and therapy response. As such, new approaches to study CSCs in patient-derived tumor specimens are needed. In this study, we exploited ultradeep single-molecule genomic data derived from multiple microdissected colorectal cancer glands per tumor, along with a novel quantitative approach to measure tumor characteristics, define patient-specific tumor profiles, and infer tumor ancestral trees. We show that each cancer is unique in terms of its cellular organization, molecular heterogeneity, time from malignant transformation, and rate of mutation and apoptosis. Importantly, we estimate CSC fractions between 0.5% and 4%, indicative of a hierarchical organization responsible for long-lived CSC lineages, with variable rates of symmetric cell division. We also observed extensive molecular heterogeneity, both between and within individual cancer glands, suggesting a complex hierarchy of mitotic clones. Our framework enables the measurement of clinically relevant patient-specific characteristics in vivo, providing insight into the cellular organization and dynamics of tumor growth, with implications for personalized patient care. Cancer Res; 73(1); 41–49. ©2012 AACR.

Published

2013

72. Wnt and the Cancer Niche: Paracrine Interactions with Gastrointestinal Cancer Cells Undergoing Asymmetric Cell Division

Author

Hong-Wu Xin, Bo-Kyu Kim, Gordon W. Wiegand, Udo Rudloff, Alexander Stojadinovic, John E. Mullinax, Chenwi M. Ambe, Satyajit Ray, Itzhak Avital, Danielle M. Hari, Kshama R. Jaiswal, Snorri S. Thorgeirsson, Susan H. Garfield, and Tomotake Koizumi

Subjects

0303 health sciences, Asymmetric Cell Division, Non-Random Chromosomal Cosegregation, Wnt signaling pathway, Cancer, Symmetric cell division, Biology, medicine.disease, Bioinformatics, 3. Good health, 03 medical and health sciences, Paracrine signalling, 0302 clinical medicine, Oncology, Cancer stem cell, Cancer Stem Cells, 030220 oncology & carcinogenesis, Cancer cell, Asymmetric cell division, medicine, Cancer research, Microenvironment, Stem cell, Research Paper, 030304 developmental biology

Abstract

Objective: Stem-like cancer cells contribute to cancer initiation and maintenance. Stem cells can self-renew by asymmetric cell division (ACD). ACD with non-random chromosomal cosegregation (ACD-NRCC) is one possible self-renewal mechanism. There is a paucity of evidence supporting ACD-NRCC in human cancer. Our aim was to investigate ACD-NRCC and its potential interactions with the cancer niche (microenvironment) in gastrointestinal cancers. Design: We used DNA double and single labeling approaches with FACS to isolate live cells undergoing ACD-NRCC. Results: Gastrointestinal cancers contain rare subpopulations of cells capable of ACD-NRCC. ACD-NRCC was detected preferentially in subpopulations of cells previously suggested to be stem-like/tumor-initiating cancer cells. ACD-NRCC was independent of cell-to-cell contact, and was regulated by the cancer niche in a heat-sensitive paracrine fashion. Wnt pathway genes and proteins are differentially expressed in cells undergoing ACD-NRCC vs. symmetric cell division. Blocking the Wnt pathway with IWP2 (WNT antagonist) or siRNA-TCF4 resulted in suppression of ACD-NRCC. However, using a Wnt-agonist did not increase the relative proportion of cells undergoing ACD-NRCC. Conclusion: Gastrointestinal cancers contain subpopulations of cells capable of ACD-NRCC. Here we show for the first time that ACD-NRCC can be regulated by the Wnt pathway, and by the cancer niche in a paracrine fashion. However, whether ACD-NRCC is exclusively associated with stem-like cancer cells remains to be determined. Further study of these findings might generate novel insights into stem cell and cancer biology. Targeting the mechanism of ACD-NRCC might engender novel approaches for cancer therapy.

Published

2013

73. Axl receptor tyrosine kinase drives cell cycle re-entry and promotes symmetric cell division of airway basal cells in response to injury

Author

Toshifumi Fujimori, Naoya Fujino, Rose A. Maciewicz, and Tracy Hussell

Subjects

Basal (phylogenetics), AXL receptor tyrosine kinase, biology, biology.protein, Asymmetric cell division, Respiratory epithelium, Symmetric cell division, Stem cell, Cell cycle, Receptor tyrosine kinase, Cell biology

Abstract

Airway basal cells are quiescent at steady state but robustly activate and proliferate to repair damaged epithelium in response to injury. However little is known about the molecular mechanisms underlying this process. We previously reported that the TAM receptor tyrosine kinase Axl negatively regulates epithelial differentiation of human lung tissue-derived multi-potent cells in vitro (Eur Respir J 2013 42:P3138 ). To investigate the role of Axl kinase in regulation of airway stem cell function in vivo , we firstly determined cell-types expressing Axl in murine airway epithelium. Histological examination revealed that Axl kinase was expressed by basal cells but not by other luminal cells such as secretory cells and ciliated cells. qRT-PCR confirmed this exclusive expression of Axl mRNA in basal cells. Next, we sought to define the function of Axl on airway basal cells in response to injury. Intra-nasal administration of H1N1/PR8 influenza A virus increased Ki67+ cycling airway basal cells and this increase was attenuated in Axl-deficient mice. We also observed that basal cells undergoing asymmetric cell division increased in Axl-deficient mice during the influenza-induced injury. Consistently, basal cell spheroids at a 2-cell stage generated from trachea of Axl-deficient mice showed more differentiating phenotypes ex vivo compared to wild-type mice. Consequently ciliated cells regeneration was more evident in a resolution phase of the in vivo influenza-injury model. Taken together these data suggest that Axl regulates basal cell expansion by promoting cell cycle re-entry and symmetric cell division in response to injury.

Published

2016

74. Cell division plane orientation based on tensile stress inArabidopsis thaliana

Author

Jean-Daniel Julien, Marion Louveaux, Arezki Boudaoud, Olivier Hamant, Vincent Mirabet, Reproduction et développement des plantes (RDP), Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Recherche Agronomique (INRA)-École normale supérieure - Lyon (ENS Lyon), ARC3 Environnement, Region Rhone-Alpes, European Research Council 615739 307387, École normale supérieure de Lyon (ENS de Lyon)-Institut National de la Recherche Agronomique (INRA)-Université Claude Bernard Lyon 1 (UCBL), and Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)

Subjects

0301 basic medicine, vertex model, [SDV]Life Sciences [q-bio], Meristem, Arabidopsis, Symmetric cell division, Geometry, Curvature, Models, Biological, mechanical force, 03 medical and health sciences, Orientation (geometry), [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, Cell Lineage, Cell Shape, Mathematics, Microscopy, Confocal, Multidisciplinary, Plane (geometry), Isotropy, cell division plane, food and beverages, Division (mathematics), Stress field, 030104 developmental biology, PNAS Plus, Tension (geology), Stress, Mechanical, Algorithms, Cell Division, Plant Shoots

Abstract

International audience; Cell geometry has long been proposed to play a key role in the orientation of symmetric cell division planes. In particular, the recently proposed Besson-Dumais rule generalizes Errera's rule and predicts that cells divide along one of the local minima of plane area. However, this rule has been tested only on tissues with rather local spherical shape and homogeneous growth. Here, we tested the application of the Besson-Dumais rule to the divisions occurring in the Arabidopsis shoot apex, which contains domains with anisotropic curvature and differential growth. We found that the Besson-Dumais rule works well in the central part of the apex, but fails to account for cell division planes in the saddle-shaped boundary region. Because curvature anisotropy and differential growth prescribe directional tensile stress in that region, we tested the putative contribution of anisotropic stress fields to cell division plane orientation at the shoot apex. To do so, we compared two division rules: geometrical (new plane along the shortest path) and mechanical (new plane along maximal tension). The mechanical division rule reproduced the enrichment of long planes observed in the boundary region. Experimental perturbation of mechanical stress pattern further supported a contribution of anisotropic tensile stress in division plane orientation. Importantly, simulations of tissues growing in an isotropic stress field, and dividing along maximal tension, provided division plane distributions comparable to those obtained with the geometrical rule. We thus propose that division plane orientation by tensile stress offers a general rule for symmetric cell division in plants.

Published

2016

75. Dynamic self-organisation of haematopoiesis and (a)symmetric cell division

Author

Frode Måløy, Bjørn Olav Brandsdal, Marthe Måløy, and Per Kristen Jakobsen

Subjects

0301 basic medicine, Statistics and Probability, Adult Germline Stem Cells, Cell division, Cellular differentiation, VDP::Mathematics and natural science: 400::Basic biosciences: 470::Cell biology: 471, Symmetric cell division, Biology, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Germline, 03 medical and health sciences, Modelling and Simulation, Immunology and Microbiology(all), Asymmetric cell division, Animals, Humans, Medicine(all), General Immunology and Microbiology, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), Applied Mathematics, General Medicine, VDP::Matematikk og Naturvitenskap: 400::Matematikk: 410, VDP::Mathematics and natural science: 400::Mathematics: 410, Cell biology, Hematopoiesis, Haematopoiesis, 030104 developmental biology, Modeling and Simulation, Immunology, Drosophila, Stem cell, General Agricultural and Biological Sciences, Cell Division, VDP::Matematikk og Naturvitenskap: 400::Basale biofag: 470::Cellebiologi: 471

Abstract

Source at http://dx.doi.org/10.1016/j.jtbi.2016.11.030 A model of haematopoiesis that links self-organisation with symmetric and asymmetric cell division is presented in this paper. It is assumed that all cell divisions are completely random events, and that the daughter cells resulting from symmetric and asymmetric stem cell divisions are, in general, phenotypically identical, and still, the haematopoietic system has the flexibility to self-renew, produce mature cells by differentiation, and regenerate undifferentiated and differentiated cells when necessary, due to self-organisation. As far as we know, no previous model implements symmetric and asymmetric division as the result of self-organisation. The model presented in this paper is inspired by experiments on the Drosophila germline stem cell, which imply that under normal conditions, the stem cells typically divide asymmetrically, whereas during regeneration, the rate of symmetric division increases. Moreover, the model can reproduce several of the results from experiments on female Safari cats. In particular, the model can explain why significant fluctuation in the phenotypes of haematopoietic cells was observed in some cats, when the haematopoietic system had reached normal population level after regeneration. To our knowledge, no previous model of haematopoiesis in Safari cats has captured this phenomenon.

Published

2016

76. Cell cycle–regulated cortical dynein/dynactin promotes symmetric cell division by differential pole motion in anaphase

Author

Patricia Wadsworth, Jessica L. Faraci, Elizabeth S. Collins, Sai Keshavan Balchand, and Wei-Lih Lee

Subjects

Sus scrofa, Dynein, Mitosis, Symmetric cell division, Spindle Apparatus, macromolecular substances, Biology, Spindle pole body, Cell Line, 03 medical and health sciences, 0302 clinical medicine, Nuclear Matrix-Associated Proteins, Cell cortex, Animals, Molecular Biology, Cytoskeleton, 030304 developmental biology, Anaphase, 0303 health sciences, urogenital system, Kinetochore, fungi, Dyneins, Articles, Cell Cycle Checkpoints, Dynactin Complex, Cell Biology, Spindle apparatus, Cell biology, Dynactin, Microtubule-Associated Proteins, Cell Division, 030217 neurology & neurosurgery

Abstract

Evidence is presented for dynamic cortical association of dynein and dynactin in mammalian cells and its regulation by Plk1, astral microtubules, and the cell cycle. The asymmetric spindle positioning in LLC-Pk1 cells and its correction by dynein and dynactin provide a new system for analysis of spindle position and symmetric cell division., In cultured mammalian cells, how dynein/dynactin contributes to spindle positioning is poorly understood. To assess the role of cortical dynein/dynactin in this process, we generated mammalian cell lines expressing localization and affinity purification (LAP)–tagged dynein/dynactin subunits from bacterial artificial chromosomes and observed asymmetric cortical localization of dynein and dynactin during mitosis. In cells with asymmetrically positioned spindles, dynein and dynactin were both enriched at the cortex distal to the spindle. NuMA, an upstream targeting factor, localized asymmetrically along the cell cortex in a manner similar to dynein and dynactin. During spindle motion toward the distal cortex, dynein and dynactin were locally diminished and subsequently enriched at the new distal cortex. At anaphase onset, we observed a transient increase in cortical dynein, followed by a reduction in telophase. Spindle motion frequently resulted in cells entering anaphase with an asymmetrically positioned spindle. These cells gave rise to symmetric daughter cells by dynein-dependent differential spindle pole motion in anaphase. Our results demonstrate that cortical dynein and dynactin dynamically associate with the cell cortex in a cell cycle–regulated manner and are required to correct spindle mispositioning in LLC-Pk1 epithelial cells.

Published

2012

77. Concerted control of gliogenesis by InR/TOR and FGF signalling in the Drosophila post-embryonic brain

Author

Helen McNeill, Ariana Gatt, Joseph M. Bateman, Aamna K. Kaul, and Amélie Avet-Rochex

Subjects

Nervous system, Time Factors, Symmetric cell division, Biology, Fibroblast growth factor, Models, Biological, Cortex (anatomy), medicine, Animals, Drosophila Proteins, Insulin, Molecular Biology, Research Articles, Crosses, Genetic, In Situ Hybridization, Cell Proliferation, Gliogenesis, TOR Serine-Threonine Kinases, Neurogenesis, Brain, Gene Expression Regulation, Developmental, Receptor Protein-Tyrosine Kinases, Anatomy, Cell biology, Fibroblast Growth Factors, Drosophila melanogaster, medicine.anatomical_structure, nervous system, Neuroglia, RNA Interference, Signal Transduction, Developmental Biology

Abstract

Glial cells are essential for the development and function of the nervous system. In the mammalian brain, vast numbers of glia of several different functional types are generated during late embryonic and early foetal development. However, the molecular cues that instruct gliogenesis and determine glial cell type are poorly understood. During post-embryonic development, the number of glia in the Drosophila larval brain increases dramatically, potentially providing a powerful model for understanding gliogenesis. Using glial-specific clonal analysis we find that perineural glia and cortex glia proliferate extensively through symmetric cell division in the post-embryonic brain. Using pan-glial inhibition and loss-of-function clonal analysis we find that Insulin-like receptor (InR)/Target of rapamycin (TOR) signalling is required for the proliferation of perineural glia. Fibroblast growth factor (FGF) signalling is also required for perineural glia proliferation and acts synergistically with the InR/TOR pathway. Cortex glia require InR in part, but not downstream components of the TOR pathway, for proliferation. Moreover, cortex glia absolutely require FGF signalling, such that inhibition of the FGF pathway almost completely blocks the generation of cortex glia. Neuronal expression of the FGF receptor ligand Pyramus is also required for the generation of cortex glia, suggesting a mechanism whereby neuronal FGF expression coordinates neurogenesis and cortex gliogenesis. In summary, we have identified two major pathways that control perineural and cortex gliogenesis in the post-embryonic brain and have shown that the molecular circuitry required is lineage specific.

Published

2012

78. Min protein patterns emerge from rapid rebinding and membrane interaction of MinE

Author

Christoph Herold, Karsten Kruse, Elisabeth Fischer-Friedrich, Martin Loose, and Petra Schwille

Subjects

Adenosine Triphosphatases, Cell division, Protein Stability, Activator (genetics), Escherichia coli Proteins, ATPase, Cell Membrane, Membrane Proteins, Pattern formation, Cell Cycle Proteins, Symmetric cell division, Biology, Models, Biological, Cell biology, Membrane, Structural Biology, Min System, Escherichia coli, Oscillation (cell signaling), biology.protein, Molecular Biology, Cell Division

Abstract

In Escherichia coli, the pole-to-pole oscillation of the Min proteins directs septum formation to midcell, which is required for symmetric cell division. In vitro, protein waves emerge from the self-organization of MinD, a membrane-binding ATPase, and its activator MinE. For wave propagation, the proteins need to cycle through states of collective membrane binding and unbinding. Although MinD presumably undergoes cooperative membrane attachment, it is unclear how synchronous detachment is coordinated. We used confocal and single-molecule microscopy to elucidate the order of events during Min wave propagation. We propose that protein detachment at the rear of the wave, and the formation of the E-ring, are accomplished by two complementary processes: first, local accumulation of MinE due to rapid rebinding, leading to dynamic instability; and second, a structural change induced by membrane-interaction of MinE in an equimolar MinD-MinE (MinDE) complex, which supports the robustness of pattern formation.

Published

2011

79. Abstract 4949: The role of symmetric cell division in post-therapy glioma-initiating cell expansion

Author

Anne Christensen, Robert Hall, Shivani Baisiwala, Cheol Hong Park, Atique Ahmed, Louisa Warnke, and Jack Shireman

Subjects

Cancer Research, Cell expansion, Oncology, business.industry, Glioma, medicine, Cancer research, Symmetric cell division, medicine.disease, business

Abstract

The purpose of this study is to elucidate the mechanism by which LNX1 regulates Notch1 to increase symmetric self-renewal of glioma-initiating cells (GICs) and thereby to expand the GIC population in glioblastoma (GBM) during therapy. GBM is an aggressive primary malignancy of the brain with an almost 100% recurrence rate. Our lab and others have shown that GBM contains a subpopulation of GICs that may drive the therapeutic resistance capabilities of recurrent GBM. We have shown that the GIC population expands following administration of temozolomide (TMZ), the most commonly used drug for antiglioma chemotherapy. While it has been suggested that this expansion relies solely on Darwinian selection, we and others have demonstrated that cellular plasticity-driven expansion of therapeutically resistant GICs post-therapy may play a role in disease recurrence. GICs follow the normal stem cell pattern of cell division. They can divide in three ways: (1) asymmetric division to form one GIC and one differentiated cancer cell, (2) symmetric self-renewal to form two daughter GICs, or (3) symmetric differentiation to form two cancer cells. Here, we used ImageStream flow cytometry analysis to show that symmetric self-renewal, where one GIC produces two daughter GICs, occurs at a rate of 24% in GBM cells treated with vehicle as compared to 54% following TMZ therapy (p Citation Format: Shivani Baisiwala, Robert Hall, Louisa Warnke, Anne Christensen, Jack Shireman, Cheol H. Park, Atique U. Ahmed. The role of symmetric cell division in post-therapy glioma-initiating cell expansion [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 4949.

Published

2018

80. The asymmetric division and tumorigenesis of stem cells

Author

Yinghui Lü, Qizhao Wang, Yong Diao, Nan Jiang, and Ruian Xu

Subjects

Neurons, Cell division, Tumor Suppressor Proteins, Cell Polarity, Symmetric cell division, Spindle Apparatus, Biology, Cell fate determination, medicine.disease_cause, Spindle apparatus, Cell biology, Cell Transformation, Neoplastic, Oncology, Cancer stem cell, Neoplasms, Cell polarity, Neoplastic Stem Cells, medicine, Animals, Humans, Drosophila, Stem cell, Carcinogenesis, Cell Division

Abstract

Stem cells use asymmetric and symmetric cell division to generate progeny. Symmetric cell division is defined as the generation of daughter cells that are destined to acquire the same fate. Stem cells divide asymmetrically to generate one daughter with a stem-cell fate and one daughter with different fate. Disruption of the machinery that regulates asymmetric division may be a reason for the generation of cancer. The asymmetric mechanism is maintained by cell polarity factors, cell fate determinants, and the spindle apparatus. The mutation or dysregulation of these factors may change stem cells from asymmetric to symmetric cell division, then leading to tumorigenesis. Therefore, further study is needed on the mechanisms of stem cell control between asymmetric and symmetric cell division, as well as the relationships among stem cells, cancer stem cells, and tumor cells. It may bring us a new approach for the resistance, recurrence, and metastasis of tumors.

Published

2010

81. A DNA-transposon-based approach to functional screening in Neural Stem cells

Author

G. Giacomo Consalez, Marco Onorati, Daniele Biasci, Zoltán Ivics, Alessia Moiana, Giovanna Calabrese, Elena Cattaneo, Ilaria Albieri, Stefano Camnasio, Aurora Badaloni, Dimitrios Spiliotopoulos, Albieri, I, Onorati, M, Calabrese, G, Moiana, A, Biasci, D, Badaloni, A, Camnasio, S, Spiliotopoulos, D, Ivics, Z, Cattaneo, E, and Consalez, GIAN GIACOMO

Subjects

Transposable element, Cells, Clone (cell biology), Transposases, Bioengineering, Symmetric cell division, Biology, Applied Microbiology and Biotechnology, Screenings, 03 medical and health sciences, Mice, Sleeping beauty, 0302 clinical medicine, Genetic, Neural Stem Cells, Neural stem cells, Transposons, Animals, Cells, Cultured, Computer Simulation, DNA Transposable Elements, Humans, Mutagenesis, Insertional, Neomycin, Models, Genetic, Biotechnology, Models, Insertional, Transposase, 030304 developmental biology, Genetics, 0303 health sciences, Cultured, General Medicine, Sleeping Beauty transposon system, Embryonic stem cell, Neural stem cell, Cell biology, Mutagenesis, Stem cell, 030217 neurology & neurosurgery

Abstract

We describe the use of DNA transposons as tools for carrying out functional screenings in murine embryonic stem (ES) cell-derived neural stem (NS) cells. NS cells are a new type of stem cells featuring radial glial properties, that undergoes symmetric cell division for an indefinite number of passages, expanding as a monolayer. In this model, the previously unreported Sleeping Beauty transposase M3A achieves an optimal blend of clone generation efficiency and low redundancy of integrations per clone, compared to the SB100X Sleeping Beauty variant and to the piggyBac transposon. The technology described here makes it possible to randomly trap genes in the NS cell genome and modify their expression or tag them with fluorescent markers and selectable genes, allowing recombinant cells to be isolated and expanded clonally. This approach will facilitate the identification of novel determinants of stem cell biology and neural cell fate specification in NS cells.

Published

2010

82. Dynamics of Asymmetric and Symmetric Divisions of Muscle Stem Cells In Vivo and on Artificial Niches.

Author

Evano B, Khalilian S, Le Carrou G, Almouzni G, and Tajbakhsh S

Subjects

Animals, Cell Lineage, DNA metabolism, Genes, Reporter, Histones metabolism, Mice, Transgenes, Asymmetric Cell Division, Muscles cytology, Stem Cell Niche, Stem Cells cytology

Abstract

Stem cells can be maintained through symmetric cell divisions (SCDs) and asymmetric cell divisions (ACDs). How and when these divisions occur in vivo in vertebrates is poorly understood. Here, we developed a clonogenic cell tracing method that demonstrates the asymmetric distribution of transcription factors along with old and new DNA in mouse muscle stem cells during skeletal muscle regeneration. Combining single-cell tracking and artificial niches ex vivo, we show how cells switch from ACDs to SCDs, suggesting that they are not engaged in an obligate mode of cell division. Further, we generated SNAP-tagged histone H3-reporter mice and find that, unlike fly germline stem cells, differential fate outcomes are associated with a symmetric distribution of the H3.1 and H3.3 histone variants in mouse muscle stem cells. This versatile and efficient H3-SNAP labeling system will allow an investigation of mechanisms underlying the maintenance of epigenomic identity and plasticity in a variety of tissues., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2020

83. Cell division orientation and planar cell polarity pathways

Author

Yohanns Bellaïche and Marion Segalen

Subjects

0303 health sciences, Frizzled, Cell division, Morphogenesis, Wnt signaling pathway, Cell Polarity, Proteins, Symmetric cell division, Spindle Apparatus, Cell Biology, Cell fate determination, Biology, Cell biology, 03 medical and health sciences, 0302 clinical medicine, Cell polarity, Asymmetric cell division, Animals, Cell Division, 030217 neurology & neurosurgery, Signal Transduction, 030304 developmental biology, Developmental Biology

Abstract

The orientation of cell division has a crucial role in early embryo body plan specification, axis determination and cell fate diversity generation, as well as in the morphogenesis of tissues and organs. In many instances, cell division orientation is regulated by the planar cell polarity (PCP) pathways: the Wnt/Frizzled non-canonical pathway or the Fat/Dachsous/Four-jointed pathway. Firstly, using asymmetric cell division in both Drosophila and C. elegans, we describe the central role of the Wnt/Frizzled pathway in the regulation of asymmetric cell division orientation, focusing on its cooperation with either the Src kinase pathway or the heterotrimeric G protein pathway. Secondly, we describe our present understanding of the mechanisms by which the planar cell polarity pathways drive tissue morphogenesis by regulating the orientation of symmetric cell division within a field of cells. Finally, we will discuss the important avenues that need to be explored in the future to better understand how planar cell polarity pathways control embryo body plan determination, cell fate specification or tissue morphogenesis by mitotic spindle orientation.

Published

2009

84. Cadherin Adhesion Receptors Orient the Mitotic Spindle during Symmetric Cell Division in Mammalian Epithelia

Author

Carmen V. Buttery, Gang Ren, Madhavi P. Maddugoda, Alpha S. Yap, and Nicole den Elzen

Subjects

Cell division, Recombinant Fusion Proteins, Symmetric cell division, Spindle Apparatus, Biology, Spindle pole body, Cell Line, Dogs, Cell polarity, Cell Adhesion, Asymmetric cell division, Animals, Humans, Molecular Biology, Mitosis, beta Catenin, Cadherin, Cell Polarity, Epithelial Cells, Articles, Cell Biology, Cadherins, Spindle apparatus, Cell biology, Intercellular Junctions, RNA Interference, Cell Division

Abstract

Oriented cell division is a fundamental determinant of tissue organization. Simple epithelia divide symmetrically in the plane of the monolayer to preserve organ structure during epithelial morphogenesis and tissue turnover. For this to occur, mitotic spindles must be stringently oriented in the Z-axis, thereby establishing the perpendicular division plane between daughter cells. Spatial cues are thought to play important roles in spindle orientation, notably during asymmetric cell division. The molecular nature of the cortical cues that guide the spindle during symmetric cell division, however, is poorly understood. Here we show directly for the first time that cadherin adhesion receptors are required for planar spindle orientation in mammalian epithelia. Importantly, spindle orientation was disrupted without affecting tissue cohesion or epithelial polarity. This suggests that cadherin receptors can serve as cues for spindle orientation during symmetric cell division. We further show that disrupting cadherin function perturbed the cortical localization of APC, a microtubule-interacting protein that was required for planar spindle orientation. Together, these findings establish a novel morphogenetic function for cadherin adhesion receptors to guide spindle orientation during symmetric cell division.

Published

2009

85. The Neurotransmitter VIP Expands the Pool of Symmetrically Dividing Postnatal Dentate Gyrus Precursors via VPAC2 Receptors or Directs Them Toward a Neuronal Fate via VPAC1 receptors

Author

Christopher Abbosh, W. John Sheward, Anthony J. Harmar, Malik Zaben, William P. Gray, Anan Shtaya, and Ashley K. Pringle

Subjects

Male, Receptors, Vasoactive Intestinal Polypeptide, Type I, Nerve Tissue Proteins, Symmetric cell division, Biology, Hippocampal formation, Cell fate determination, Nestin, Mice, Intermediate Filament Proteins, Neurotransmitter receptor, medicine, Animals, Cell Lineage, Rats, Wistar, Receptor, Cells, Cultured, Cell Proliferation, Mice, Knockout, Neurons, Stem Cells, Dentate gyrus, Neurogenesis, Cell Differentiation, Cell Biology, Anatomy, Granule cell, Rats, Phenotype, medicine.anatomical_structure, Animals, Newborn, nervous system, Dentate Gyrus, Receptors, Vasoactive Intestinal Peptide, Type II, Molecular Medicine, Female, Neuroscience, Cell Division, Vasoactive Intestinal Peptide, Developmental Biology

Abstract

The controlled production of neurons in the postnatal dentate gyrus and thoughout life is important for hippocampal learning and memory. The mechanisms underlying the necessary coupling of neuronal activity to neural stem/progenitor cell (NSPC) function remain poorly understood. Within the dentate subgranular stem cell niche, local interneurons appear to play an important part in this excitation-neurogenesis coupling via GABAergic transmission, which promotes neuronal differentiation and integration. Here we show that vasoactive intestinal polypeptide, a neuropeptide coreleased with GABA under specific firing conditions, is uniquely trophic for proliferating postnatal nestin-positive dentate NSPCs, mediated via the VPAC2 receptor. We also show that VPAC2 receptor activation shifts the fate of symmetrically dividing NSPCs toward a nestin-only phenotype, independent of the trophic effect. In contrast, selective VPAC1 receptor activation shifts NSPC fate toward granule cell neurogenesis without any trophism. We confirm a trophic role for VPAC2 receptors in vivo, showing reduced progeny survival and dentate neurogenesis in adult Vipr2−/− mice. We also show a specific reduction in type 2 nestin-positive precursors in vivo, consistent with a role for VPAC2 in maintaining this cell population. This work provides the first evidence of differential fate modulation of neurogenesis by neurotransmitter receptor subtypes and extends the fate-determining effects of neurotransmitters to maintaining the nestin-positive pool of NSPCs. This differential receptor effect may support the independent pharmacological manipulation of precursor pool expansion and neurogenic instruction for therapeutic application in the treatment of cognitive deficits associated with a decline in neurogenesis.

Published

2009

86. ADP-Ribosylation Factor 1 Regulates Asymmetric Cell Division in Female Meiosis in the Mouse1

Author

Jianjun Hu, Xinzheng Guo, Johne X. Liu, Shufang Wang, and Shaorong Gao

Subjects

Genetics, Germinal vesicle, Cell division, Symmetric cell division, Cell Biology, General Medicine, Biology, Oocyte, Cell biology, Polar body, medicine.anatomical_structure, Reproductive Medicine, Meiosis, Asymmetric cell division, medicine, Cytokinesis

Abstract

Mouse oocytes undergo two successive meiotic divisions to generate one large egg with two small polar bodies. The divisions are essential for preserving the maternal resources to support embryonic development. Although previous studies have shown that some small guanosine triphosphatases, such as RAC, RAN, and CDC42, play important roles in cortical polarization and spindle pole anchoring, no oocytes undergo cytokinesis when the mutant forms of these genes are expressed in mouse oocytes. Here, we show that the ADP-ribosylation factor 1 (ARF1) plays an important role in regulating asymmetric cell division in mouse oocyte meiosis. Microinjection of mRNA of a dominant negative mutant form of Arf1 (Arf1T31N) into fully grown germinal vesicle oocytes led to symmetric cell division in meiosis I, generating two metaphase II (MII) oocytes of equal size. Subsequently, the two MII oocytes of equal size underwent the second round of symmetric cell division to generate a four-cell embryo (zygote) when activa...

Published

2009

87. Promotion of Initiated Cells by Radiation-Induced Cell Inactivation

Author

W. F. Heidenreich and H. G. Paretzke

Subjects

Neoplasms, Radiation-Induced, Time Factors, Radiation, Cell, Biophysics, Clone (cell biology), Cell replacement, Dose-Response Relationship, Radiation, Nanotechnology, Symmetric cell division, Radiation induced, Biology, medicine.disease_cause, Cell biology, medicine.anatomical_structure, medicine, Humans, Radiology, Nuclear Medicine and imaging, Carcinogenesis, Monte Carlo Method, Mathematics

Abstract

Heidenreich, W. F. and Paretzke, H. G. Promotion of Initiated Cells by Radiation-Induced Cell Inactivation. Radiat. Res. 170, 613–617 (2008). Cells on the way to carcinogenesis can have a growth advantage relative to normal cells. It has been hypothesized that a radiation-induced growth advantage of these initiated cells might be induced by an increased cell replacement probability of initiated cells after inactivation of neighboring cells by radiation. Here Monte Carlo simulations extend this hypothesis for larger clones: The effective clonal expansion rate decreases with clone size. This effect is stronger for the two-dimensional than for the three-dimensional situation. The clones are irregular, far from a circular shape. An exposure-rate dependence of the effective clonal expansion rate could come in part from a minimal recovery time of the initiated cells for symmetric cell division.

Published

2008

88. Simulation of proliferation and differentiation of cells in a stem-cell niche

Author

Vladimir P. Zhdanov

Subjects

Statistics and Probability, Ecological niche, Cell division, Niche, Subventricular zone, Symmetric cell division, Adhesion, Biology, Condensed Matter Physics, Cell biology, medicine.anatomical_structure, medicine, Stem cell, Tissue homeostasis

Abstract

Stem-cell niches represent microscopic compartments formed of environmental cells that nurture stem cells and enable them to maintain tissue homeostasis. The spatio–temporal kinetics of proliferation and differentiation of cells in such niches depend on the specifics of the niche structure and on adhesion and communication between cells and may also be influenced by spatial constraints on cell division. We propose a generic lattice model, taking all these factors into account, and systematically illustrate their role. The model is motivated by the experimental data available for the niches located in the subventricular zone of adult mammalian brain. The general conclusions drawn from our Monte Carlo simulations are applicable to other niches as well. One of our main findings is that the kinetics under consideration are highly stochastic due to a relatively small number of cells proliferating and differentiating in a niche and the autocatalytic character of the symmetric cell division. In particular, the kinetics exhibit huge stochastic bursts especially if the adhesion between cells is taken into account. In addition, the results obtained show that despite the small number of cells present in stem-cell niches, their arrangement can be predetermined to appreciable extent provided that the adhesion of different cells is different so that they tend to segregate.

Published

2008

89. Beyond the plasma membrane: New functions for heterotrimeric G-protein signaling in asymmetric and symmetric cell division

Author

Hyeseon Cho and John H. Kehrl

Subjects

GTPase-activating protein, G protein, Cell Membrane, Symmetric cell division, Cell Biology, Biology, Heterotrimeric GTP-Binding Proteins, Microtubules, Actins, Cell biology, Midbody, G beta-gamma complex, Drosophila melanogaster, Heterotrimeric G protein, Animals, Humans, cAMP-dependent pathway, Caenorhabditis elegans, Molecular Biology, Cell Division, Cytokinesis, Signal Transduction, Developmental Biology

Abstract

Plasma membrane heterotrimeric G proteins transduce extracellular signals from seven transmembrane receptors to downstream effectors. In addition, G proteins and their regulators localize at multiple intracellular sites and play crucial roles in cell division. In model organisms such as Caenorhabditis elegans and Drosophila receptor-independent heterotrimeric G protein function is vital for the orientation of mitotic spindle, generation of microtubule pulling force, aster-induced cytokinesis, and centration of the nucleus-centrosome complex. This new paradigm is now being extended to mammalian cells. Mammalian G protein signaling components localize in centrosomes and at the midbody, and altered function or expression of these proteins can cause cell division defects. Here, we highlight the role and possible mechanisms of G protein signaling in mammalian cell division in conjunction with recent findings in model organisms. Together the evidence argues for a more direct role of non-canonical heterotrimeric G protein signaling in microtubule- and actin cytoskeleton-mediated cellular processes.

Published

2008

90. Mechanisms of Asymmetric Stem Cell Division

Author

Juergen A. Knoblich

Subjects

Cell division, Biochemistry, Genetics and Molecular Biology(all), Stem Cells, Cellular differentiation, Cell Polarity, Symmetric cell division, Spindle Apparatus, Cell fate determination, Biology, General Biochemistry, Genetics and Molecular Biology, Cell biology, Asymmetric cell division, Animals, Humans, Stem cell, Progenitor cell, Cell Division, Asymmetric stem cell division

Abstract

Stem cells self-renew but also give rise to daughter cells that are committed to lineage-specific differentiation. To achieve this remarkable task, they can undergo an intrinsically asymmetric cell division whereby they segregate cell fate determinants into only one of the two daughter cells. Alternatively, they can orient their division plane so that only one of the two daughter cells maintains contact with the niche and stem cell identity. These distinct pathways have been elucidated mostly in Drosophila. Although the molecules involved are highly conserved in vertebrates, the way they act is tissue specific and sometimes very different from invertebrates.

Published

2008

91. The linear and rotational motions of the fission yeast nucleus are governed by the stochastic dynamics of spatially distributed microtubules

Author

Yuan Lin, T. H. Hui, Chuanhai Fu, and Fan Zheng

Subjects

0301 basic medicine, Cell division, Fission, Biomedical Engineering, Biophysics, Symmetric cell division, Nanotechnology, Biology, Microtubules, Models, Biological, Quantitative Biology::Subcellular Processes, 03 medical and health sciences, 0302 clinical medicine, Stochastic dynamics, Microtubule, Cell Movement, Schizosaccharomyces, medicine, Orthopedics and Sports Medicine, Cytoskeleton, Cell Nucleus, Rehabilitation, 030104 developmental biology, medicine.anatomical_structure, High temporal resolution, Restoring force, Biological system, Nucleus, 030217 neurology & neurosurgery, Cell Division

Abstract

Dynamic nuclei are involved in a wide variety of fundamental biological processes including cell migration, cell division and fertilization. Here, we develop a mathematical model, in combination with live-cell imaging at high temporal resolution, to quantitatively elucidate how the linear and rotational motions of the nucleus are governed by the stochastic dynamics of the microtubule cytoskeleton. Our simulation and experimental results demonstrate that microtubule rescue and catastrophe frequencies are the decisive factors in regulating the nuclear movement. Lower rescue and catastrophe frequencies can lead to significantly larger angular and translational oscillations of the nucleus. In addition, our model also suggests that the stochastic dynamics of individual spatially distributed microtubules works collectively as a restoring force to maintain nuclear centering and hence ensures symmetric cell division, in excellent agreement with direct experimental observations.

Published

2015

92. Gαs regulates asymmetric cell division of cortical progenitors by controlling Numb mediated Notch signaling suppression

Author

Renbing He, Jianchao Zhang, Ke Liu, Quan Lin, Minyan Zhu, Hongchang Li, Huashun Li, Zhihao Ding, Yang Hong, Ximing Shao, Lee S. Weinstein, and Yanxia Wei

Subjects

Cerebral Cortex, Gs alpha subunit, Receptors, Notch, General Neuroscience, Neurogenesis, Notch signaling pathway, Membrane Proteins, Symmetric cell division, Neocortex, Nerve Tissue Proteins, Cell fate determination, Biology, Cell biology, Mice, Neural Stem Cells, NUMB, Asymmetric cell division, Chromogranins, GTP-Binding Protein alpha Subunits, Gs, Animals, Progenitor cell, Cell Division, Cell Proliferation, Signal Transduction

Abstract

Asymmetric cell division, which plays fundamental roles in generating cell diversity during development, requires elaborate interactions between extrinsic cues and intrinsic cues. However, the precise nature of this type of interaction and its involving signaling mechanisms are poorly understood. Here, we demonstrate that Gαs is present in the proliferative region of ventricular zone in mouse developing neocortex and co-localizes with intrinsic cell fate determinant protein Numb in dividing apical progenitors. Targeted ablation of Gαs subunit in the cortical progenitor causes an alteration from asymmetric to symmetric cell division, consequently leading to increased progenitor proliferation. Mechanistically, we show that Gαs deletion significantly reduces Numb expression and activates notch signaling. Therefore, these results reveal a novel role of Gαs in control of neural progenitor asymmetric cell division via suppressing Numb mediated Notch signaling inhibition.

Published

2015

93. Expression Pattern and Localization Dynamics of Guanine Nucleotide Exchange Factor RIC8 during Mouse Oogenesis

Author

Andres Salumets, Sirje Lulla, Katrin Ruisu, Tambet Tõnissoo, Alar Karis, Margus Pooga, Keiu Kask, Merly Saare, and Riho Meier

Subjects

Blastomeres, Cytoplasm, lcsh:Medicine, Symmetric cell division, Biology, Cell cycle phase, 03 medical and health sciences, Polar body, Mice, 0302 clinical medicine, Oogenesis, medicine, Asymmetric cell division, Animals, Guanine Nucleotide Exchange Factors, lcsh:Science, Mitosis, 030304 developmental biology, Cell Nucleus, 0303 health sciences, Multidisciplinary, lcsh:R, Cell Cycle, Oocyte, Cell biology, Spindle apparatus, medicine.anatomical_structure, Gene Expression Regulation, Fertilization, Oocytes, lcsh:Q, Female, 030217 neurology & neurosurgery, Cytokinesis, Research Article

Abstract

Targeting of G proteins to the cell cortex and their activation is one of the triggers of both asymmetric and symmetric cell division. Resistance to inhibitors of cholinesterase 8 (RIC8), a guanine nucleotide exchange factor, activates a certain subgroup of G protein α-subunits in a receptor independent manner. RIC8 controls the asymmetric cell division in Caenorhabditis elegans and Drosophila melanogaster, and symmetric cell division in cultured mammalian cells, where it regulates the mitotic spindle orientation. Although intensely studied in mitosis, the function of RIC8 in mammalian meiosis has remained unknown. Here we demonstrate that the expression and subcellular localization of RIC8 changes profoundly during mouse oogenesis. Immunofluorescence studies revealed that RIC8 expression is dependent on oocyte growth and cell cycle phase. During oocyte growth, RIC8 is abundantly present in cytoplasm of oocytes at primordial, primary and secondary preantral follicle stages. Later, upon oocyte maturation RIC8 also populates the germinal vesicle, its localization becomes cell cycle dependent, and it associates with chromatin and the meiotic spindle. After fertilization, RIC8 protein converges to the pronuclei and is also detectable at high levels in the nucleolus precursor bodies of both maternal and paternal pronucleus. During first cleavage of zygote RIC8 localizes in the mitotic spindle and cell cortex of forming blastomeres. In addition, we demonstrate that RIC8 co-localizes with its interaction partners Gαi1/2:GDP and LGN in meiotic/mitotic spindle, cell cortex and polar bodies of maturing oocytes and zygotes. Downregulation of Ric8 by siRNA leads to interferred translocation of Gαi1/2 to cortical region of maturing oocytes and reduction of its levels. RIC8 is also expressed at high level in female reproductive organs e.g. oviduct. Therefore we suggest a regulatory function for RIC8 in mammalian gametogenesis and fertility.

Published

2015

94. OCT4 Activity during Conversion of Human Intermediately Reprogrammed Stem Cells to iPS Cells through MET

Author

Kunio Hirano, Rika Teshigawara, Shogo Nagata, Takashi Tada, and Justin F. X. Ainscough

Subjects

Homeobox protein NANOG, fungi, Symmetric cell division, Biology, Cell biology, SOX2, KLF4, embryonic structures, Mesenchymal–epithelial transition, biological phenomena, cell phenomena, and immunity, Stem cell, Induced pluripotent stem cell, Molecular Biology, Reprogramming, reproductive and urinary physiology, Developmental Biology

Abstract

To facilitate understanding the mechanisms of somatic reprogramming to human induced Pluripotent Stem Cells (iPSCs), we have established intermediately Reprogrammed Stem Cells (iRSCs), human mesenchymal cells that express exogenous Oct4/Sox2/Klf4/c-Myc (OSKM) and endogenous SOX2/NANOG. iRSCs can be stably maintained at low density. At high density, however, they are induced to enter Mesenchymal-to-Epithelial Transition (MET), resulting in reprogramming to an iPSC state. Morphological changes through MET correlate with silencing of exogenous OSKM, and up-regulation of endogenous OCT4. A CRISPR/Cas9-mediated GFP knock-in visualized the temporal regulation of endogenous OCT4 in cells converting from iRSC to iPSC state. OCT4 activation coincident with OSKM silencing occurred prior to entering MET. Notably, OCT4 instability was frequently observed in cells of developing post-MET colonies until a late stage (>200 cells), demonstrating that OCT4-activated post-MET cells switched from asymmetric to symmetric cell division in late stage reprogramming.

Published

2015

95. Constructing Circuits: Neurogenesis and Migration in the Developing Neocortex

Author

Arnold R. Kriegstein

Subjects

Interneuron, Ganglionic eminence, Models, Neurological, Subventricular zone, Neocortex, Symmetric cell division, Biology, Cell Movement, Interneurons, medicine, Humans, gamma-Aminobutyric Acid, Neurons, Epilepsy, Pyramidal Cells, Stem Cells, Neurogenesis, Neural stem cell, Neuroepithelial cell, Corticogenesis, medicine.anatomical_structure, nervous system, Neurology, Astrocytes, Neurology (clinical), Neuroglia, Neuroscience, Cell Division

Abstract

Our knowledge of the proliferation, migration, and differentiation of neurons has changed dramatically over the last 10 years. Whereas traditionally it was thought that glial and neuronal cells were separate cell lines with different lineages, we now know that this is not true. Radial glia are a type of neural stem cell that generate excitatory pyramidal neurons directly through asymmetric cell division in the ventricular zone (VZ) of the telencephalon and indirectly through the symmetric division of daughter intermediate precursor cells that divide in the subventricular zone (SVZ). Moreover, pyramidal neurons, once thought to migrate only along radial guide fibers to the developing layers of the cortex, have been shown to proceed through four distinct stages of migration during which they change shape, direction, and speed. Gamma-aminobutyric acid (GABAergic) inhibitory interneurons, on the other hand, are generated not in the cortex, but in the medial ganglionic eminence and migrate tangentially to their final cortical destinations. Evidence suggests that GABA activation may play a role in coordinating the generation and migration of both pyramidal and interneuron populations. At the end of neurogenesis, radial glial cells translocate to the cortex and transform into astrocytes. Although they do not actively divide in the adult brain, astrocytes may retain the potential to generate new neurons. These new findings have increased our understanding of the mechanisms underlying certain developmental disorders and, in doing so, reveal potentially useful modes of therapeutic intervention.

Published

2005

96. Regulation of symmetric bacterial cell division by MinE

Author

Natalie K. Goto and Houman Ghasriani

Subjects

Cell division, Inhibitor complex, Cell, Symmetric cell division, Biology, Division (mathematics), Bacterial cell structure, Cell biology, medicine.anatomical_structure, MINC, Botany, medicine, General Agricultural and Biological Sciences, computer, computer.programming_language

Abstract

Symmetric cell division in Gram-negative bacteria requires the concerted action of three Min proteins that together ensure exclusive formation of the cell division septum at the mid-point of the cell. We have recently described the structure and dynamic properties of MinE, the protein responsible for directing the cell division inhibitor complex formed by the MinC and MinD proteins away from the middle of the cell. An unexpected feature of this structure was the location of MinD-binding residues at buried, non-accessible sites in the dimeric interface. Here we elaborate on the potential role of conformational changes that might be involved to allow access to these residues, along with the interesting questions raised by these features of the MinE structure.

Published

2011

97. SC-21TRIM3, A HUMAN ORTHOLOG OF DROSOPHILA BRAT, MAINTAINS ASYMMETRIC CELL DIVISION OF GLIOMA STEM CELLS BY REGULATING c-MYC AND NOTCH1

Author

Daniel J. Brat, Gang Chen, Jun Kong, and Subhas Mukherjee

Subjects

Homeobox protein NANOG, Cancer Research, Cellular differentiation, Symmetric cell division, Biology, Stem cell marker, Cell biology, Abstracts, Oncology, Neuroblast, Neurosphere, Asymmetric cell division, Neurology (clinical), Stem cell

Abstract

Glioma stem cells, capable of self-renewal and multipotent differentiation, influence neoplastic growth by a dynamic balance between symmetric and asymmetric cell division. Growth is favored by a shift to symmetric division in which greater numbers of self-renewing cells emerge, as opposed to asymmetric division, which generates one stem and one differentiated cell. Drosophila Brain Tumor (Brat) protein is a critical driver of asymmetric division and differentiation, and neuroblast cells devoid of Brat undergo symmetric cell division to generate self-renewing cells that result in the brat mutant phenotype. Using a brat RNAi driven by the neuroblast specific promoter inscuteable in Drosophila model, we demonstrated accumulation of proliferative neuroblasts using inscuteable driven RFP. brat RNAi driven with eyeless promoter in Drosophila eye also induced eye overgrowth. Reduced Brat in these settings was associated with upregulation of Notch protein, suggesting a suppressive role on Notch signaling by Brat. Brat also has been shown to promote asymmetric cell division through post-transcriptional suppression of dMyc, although detailed mechanisms are lacking. We have shown that TRIM3, a human ortholog of Drosophila brat, is deleted in more than 25% of glioblastomas (GBMs). We have demonstrated that expression of TRIM3 in GBM-derived neurospheres significantly reduces proliferation, neurosphere formation, and the expression of stem cell markers CD133, NESTIN and NANOG. In GBM stem cells, expression of TRIM3 leads to a greater percentage undergoing asymmetric cell division. As with Brat in Drosophila, TRIM3 suppresses c-MYC expression and activity. We provide evidence that TRIM3, an E3 ubiquitin ligase, binds with and ubiquitinates c-MYC protein, resulting in its degradation. Subsequent attenuation of c-MYC expression inhibits proliferation and self-renewal. Altogether, our current data support a critical role of TRIM3 in maintaining asymmetric cell division of glioma stem cells by regulating c-MYC and NOTCH1.

Published

2014

98. Mammalian aPKC/Par polarity complex mediated regulation of epithelial division orientation and cell fate

Author

Susanne Vorhagen and Carien M. Niessen

Subjects

Mammals, Cell division, Cell growth, Morphogenesis, Cell Polarity, Symmetric cell division, Cell Cycle Proteins, Epithelial Cells, Cell Biology, Biology, Cell fate determination, Cell biology, Cell polarity, Asymmetric cell division, Animals, Humans, Progenitor cell, Cell Division, Protein Kinase C

Abstract

Oriented cell division is a key regulator of tissue architecture and crucial for morphogenesis and homeostasis. Balanced regulation of proliferation and differentiation is an essential property of tissues not only to drive morphogenesis but also to maintain and restore homeostasis. In many tissues orientation of cell division is coupled to the regulation of differentiation producing daughters with similar (symmetric cell division, SCD) or differential fate (asymmetric cell division, ACD). This allows the organism to generate cell lineage diversity from a small pool of stem and progenitor cells. Division orientation and/or the ratio of ACD/SCD need to be tightly controlled. Loss of orientation or an altered ratio can promote overgrowth, alter tissue architecture and induce aberrant differentiation, and have been linked to morphogenetic diseases, cancer and aging. A key requirement for oriented division is the presence of a polarity axis, which can be established through cell intrinsic and/or extrinsic signals. Polarity proteins translate such internal and external cues to drive polarization. In this review we will focus on the role of the polarity complex aPKC/Par3/Par6 in the regulation of division orientation and cell fate in different mammalian epithelia. We will compare the conserved function of this complex in mitotic spindle orientation and distribution of cell fate determinants and highlight common and differential mechanisms in which this complex is used by tissues to adapt division orientation and cell fate to the specific properties of the epithelium.

Published

2014

99. Robustness of differentiation cascades with symmetric stem cell division

Author

Tomás Alarcón and Daniel Sánchez-Taltavull

Subjects

Cell division, Cellular differentiation, Population, Biomedical Engineering, Biophysics, Bioengineering, Symmetric cell division, Biology, Biochemistry, Models, Biological, Biomaterials, Asymmetric cell division, Animals, Humans, education, Symmetric stem cell division, Tissue homeostasis, Research Articles, education.field_of_study, Stochastic Processes, Ecology, Stem Cells, Cell Differentiation, Division (mathematics), Cell biology, Cell Division, Biotechnology

Abstract

Stem cells (SCs) perform the task of maintaining tissue homeostasis by both self-renewal and differentiation. While it has been argued that SCs divide asymmetrically, there is also evidence that SCs undergo symmetric division. Symmetric SC division has been speculated to be key for expanding cell numbers in development and regeneration after injury. However, it might lead to uncontrolled growth and malignancies such as cancer. In order to explore the role of symmetric SC division, we propose a mathematical model of the effect of symmetric SC division on the robustness of a population regulated by a serial differentiation cascade and we show that this may lead to extinction of such population. We examine how the extinction likelihood depends on defining characteristics of the population such as the number of intermediate cell compartments. We show that longer differentiation cascades are more prone to extinction than systems with less intermediate compartments. Furthermore, we have analysed the possibility of mixed symmetric and asymmetric cell division against invasions by mutant invaders in order to find optimal architecture. Our results show that more robust populations are those with unfrequent symmetric behaviour.

Published

2014

100. A plant cell division algorithm based on cell biomechanics and ellipse-fitting

Author

Thijs Defraeye, Solomon Workneh Fanta, Maarten Hertog, Pieter Verboven, Bart Nicolai, Metadel Abera, and Jan Carmeliet

Subjects

Cell division, Differential equation, Division algorithm, Isotropy, Linear elasticity, Mathematical analysis, Plant Development, Symmetric cell division, Plant Science, Articles, Biology, Division (mathematics), Plants, Models, Biological, Biomechanical Phenomena, Position (vector), Cell Wall, Botany, Algorithms, Cell Division, Cell Size

Abstract

Background and aims The importance of cell division models in cellular pattern studies has been acknowledged since the 19th century. Most of the available models developed to date are limited to symmetric cell division with isotropic growth. Often, the actual growth of the cell wall is either not considered or is updated intermittently on a separate time scale to the mechanics. This study presents a generic algorithm that accounts for both symmetrically and asymmetrically dividing cells with isotropic and anisotropic growth. Actual growth of the cell wall is simulated simultaneously with the mechanics. Methods The cell is considered as a closed, thin-walled structure, maintained in tension by turgor pressure. The cell walls are represented as linear elastic elements that obey Hooke's law. Cell expansion is induced by turgor pressure acting on the yielding cell-wall material. A system of differential equations for the positions and velocities of the cell vertices as well as for the actual growth of the cell wall is established. Readiness to divide is determined based on cell size. An ellipse-fitting algorithm is used to determine the position and orientation of the dividing wall. The cell vertices, walls and cell connectivity are then updated and cell expansion resumes. Comparisons are made with experimental data from the literature. Key results The generic plant cell division algorithm has been implemented successfully. It can handle both symmetrically and asymmetrically dividing cells coupled with isotropic and anisotropic growth modes. Development of the algorithm highlighted the importance of ellipse-fitting to produce randomness (biological variability) even in symmetrically dividing cells. Unlike previous models, a differential equation is formulated for the resting length of the cell wall to simulate actual biological growth and is solved simultaneously with the position and velocity of the vertices. Conclusions The algorithm presented can produce different tissues varying in topological and geometrical properties. This flexibility to produce different tissue types gives the model great potential for use in investigations of plant cell division and growth in silico.

Published

2014