Your search keyword '"cell division timing"' showing total 7 results

1. Systems‐level quantification of division timing reveals a common genetic architecture controlling asynchrony and fate asymmetry

Author

Vincy Wing Sze Ho, Ming‐Kin Wong, Xiaomeng An, Daogang Guan, Jiaofang Shao, Hon Chun Kaoru Ng, Xiaoliang Ren, Kan He, Jinyue Liao, Yingjin Ang, Long Chen, Xiaotai Huang, Bin Yan, Yiji Xia, Leanne Lai Hang Chan, King Lau Chow, Hong Yan, and Zhongying Zhao

Subjects

asynchrony of cell division, automated lineaging, C. elegans, cell cycle length, cell division timing, Biology (General), QH301-705.5, Medicine (General), R5-920

Abstract

Abstract Coordination of cell division timing is crucial for proper cell fate specification and tissue growth. However, the differential regulation of cell division timing across or within cell types during metazoan development remains poorly understood. To elucidate the systems‐level genetic architecture coordinating division timing, we performed a high‐content screening for genes whose depletion produced a significant reduction in the asynchrony of division between sister cells (ADS) compared to that of wild‐type during Caenorhabditis elegans embryogenesis. We quantified division timing using 3D time‐lapse imaging followed by computer‐aided lineage analysis. A total of 822 genes were selected for perturbation based on their conservation and known roles in development. Surprisingly, we find that cell fate determinants are not only essential for establishing fate asymmetry, but also are imperative for setting the ADS regardless of cellular context, indicating a common genetic architecture used by both cellular processes. The fate determinants demonstrate either coupled or separate regulation between the two processes. The temporal coordination appears to facilitate cell migration during fate specification or tissue growth. Our quantitative dataset with cellular resolution provides a resource for future analyses of the genetic control of spatial and temporal coordination during metazoan development.

Published

2015

2. Systems-level quantification of division timing reveals a common genetic architecture controlling asynchrony and fate asymmetry.

Author

Ho, Vincy Wing Sze, Wong, Ming‐Kin, An, Xiaomeng, Guan, Daogang, Shao, Jiaofang, Ng, Hon Chun Kaoru, Ren, Xiaoliang, He, Kan, Liao, Jinyue, Ang, Yingjin, Chen, Long, Huang, Xiaotai, Yan, Bin, Xia, Yiji, Chan, Leanne Lai Hang, Chow, King Lau, Yan, Hong, and Zhao, Zhongying

Subjects

*CELL division, *CELL differentiation, *TISSUES, *GROWTH factors, *CELL migration

Abstract

Coordination of cell division timing is crucial for proper cell fate specification and tissue growth. However, the differential regulation of cell division timing across or within cell types during metazoan development remains poorly understood. To elucidate the systems-level genetic architecture coordinating division timing, we performed a high-content screening for genes whose depletion produced a significant reduction in the asynchrony of division between sister cells ( ADS) compared to that of wild-type during Caenorhabditis elegans embryogenesis. We quantified division timing using 3D time-lapse imaging followed by computer-aided lineage analysis. A total of 822 genes were selected for perturbation based on their conservation and known roles in development. Surprisingly, we find that cell fate determinants are not only essential for establishing fate asymmetry, but also are imperative for setting the ADS regardless of cellular context, indicating a common genetic architecture used by both cellular processes. The fate determinants demonstrate either coupled or separate regulation between the two processes. The temporal coordination appears to facilitate cell migration during fate specification or tissue growth. Our quantitative dataset with cellular resolution provides a resource for future analyses of the genetic control of spatial and temporal coordination during metazoan development. [ABSTRACT FROM AUTHOR]

Published

2015

3. Ecological behavior of the dinoflagellate Ceratium furca in Jangmok harbor of Jinhae Bay, Korea.

Author

Baek, Seung Ho, Shin, Hyeon Ho, Choi, Hyun-Woo, Shimode, Shinji, Hwang, Ok Myung, Shin, Kyoungsoon, and Kim, Young-Ok

Subjects

*DINOFLAGELLATES, *CELL division, *TURBULENCE, *AMMONIUM, *ORTHOPHOSPHATES, *FUNGI

Abstract

The rhythmic migration pattern of the dinoflagellate Ceratium furca is a result of ecological adaptation to avoid high irradiance. The high proportions of dividing cells at deeper depths are likely to be an ecological response to maintain their population away from the turbulence in the near-surface layer. [ABSTRACT FROM AUTHOR]

Published

2011

4. Chlamydomonas reinhardtii: duration of its cell cycle and phases at growth rates affected by temperature.

Author

Vítová, Milada, Bišová, Kateřina, Hlavová, Monika, Kawano, Shigeyuki, Zachleder, Vilém, and Čížková, Mária

Subjects

CHLAMYDOMONAS reinhardtii, PLANT cell cycle, GROWTH of plant cells & tissues, EFFECT of temperature on plants, CELL division

Abstract

Synchronized cultures of the green alga Chlamydomonas reinhardtii were grown photoautotrophically under a wide range of environmental conditions including temperature (15-37°C), different mean light intensities (132, 150, 264 μmol m s), different illumination regimes (continuous illumination or alternation of light/dark periods of different durations), and culture methods (batch or continuous culture regimes). These variable experimental approaches were chosen in order to assess the role of temperature in the timing of cell division, the length of the cell cycle and its pre- and post-commitment phases. Analysis of the effect of temperature, from 15 to 37°C, on synchronized cultures showed that the length of the cell cycle varied markedly from times as short as 14 h to as long as 36 h. We have shown that the length of the cell cycle was proportional to growth rate under any given combination of growth conditions. These findings were supported by the determination of the temperature coefficient ( Q), whose values were above the level expected for temperature-compensated processes. The data presented here show that cell cycle duration in C. reinhardtii is a function of growth rate and is not controlled by a temperature independent endogenous timer or oscillator, including a circadian one. [ABSTRACT FROM AUTHOR]

Published

2011

5. Chlamydomonas reinhardtii: duration of its cell cycle and phases at growth rates affected by light intensity.

Author

Vítová, Milada, Bišová, Kateřina, Umysová, Dáša, Hlavová, Monika, Kawano, Shigeyuki, Zachleder, Vilém, and Č ížkova, Mária

Subjects

CHLAMYDOMONAS reinhardtii, CELL division, CELL proliferation, CELL cycle, BRIGHTNESS perception

Abstract

In the cultures of the alga Chlamydomonas reinhardtii, division rhythms of any length from 12 to 75 h were found at a range of different growth rates that were set by the intensity of light as the sole source of energy. The responses to light intensity differed in terms of altered duration of the phase from the beginning of the cell cycle to the commitment to divide, and of the phase after commitment to cell division. The duration of the pre-commitment phase was determined by the time required to attain critical cell size and sufficient energy reserves (starch), and thus was inversely proportional to growth rate. If growth was stopped by interposing a period of darkness, the pre-commitment phase was prolonged corresponding to the duration of the dark interval. The duration of the post-commitment phase, during which the processes leading to cell division occurred, was constant and independent of growth rate (light intensity) in the cells of the same division number, or prolonged with increasing division number. It appeared that different regulatory mechanisms operated through these two phases, both of which were inconsistent with gating of cell division at any constant time interval. No evidence was found to support any hypothetical timer, suggested to be triggered at the time of daughter cell release. [ABSTRACT FROM AUTHOR]

Published

2011

6. Systems-level quantification of division timing reveals a common genetic architecture controlling asynchrony and fate asymmetry

Author

Long Chen, Hon Chun Kaoru Ng, Zhongying Zhao, Yingjin Ang, Xiaomeng An, Vincy Wing Sze Ho, Bin Yan, Yiji Xia, Daogang Guan, Hong Yan, Xiaoliang Ren, Xiaotai Huang, King Lau Chow, Leanne Lai Hang Chan, Jinyue Liao, Jiaofang Shao, Ming Kin Wong, and Kan He

Subjects

Cell type, Cell division, Cellular differentiation, Embryonic Development, Biology, Cell fate determination, General Biochemistry, Genetics and Molecular Biology, Cell Movement, Animals, cell cycle length, Cell Lineage, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Gene, General Immunology and Microbiology, Applied Mathematics, automated lineaging, Gene Expression Regulation, Developmental, Cell migration, Cell Differentiation, Articles, biology.organism_classification, Genetic architecture, Cell biology, cell division timing, Computational Theory and Mathematics, Evolutionary biology, asynchrony of cell division, C. elegans, General Agricultural and Biological Sciences, Cell Division, Information Systems

Abstract

Coordination of cell division timing is crucial for proper cell fate specification and tissue growth. However, the differential regulation of cell division timing across or within cell types during metazoan development remains poorly understood. To elucidate the systems-level genetic architecture coordinating division timing, we performed a high-content screening for genes whose depletion produced a significant reduction in the asynchrony of division between sister cells (ADS) compared to that of wild-type during Caenorhabditis elegans embryogenesis. We quantified division timing using 3D time-lapse imaging followed by computer-aided lineage analysis. A total of 822 genes were selected for perturbation based on their conservation and known roles in development. Surprisingly, we find that cell fate determinants are not only essential for establishing fate asymmetry, but also are imperative for setting the ADS regardless of cellular context, indicating a common genetic architecture used by both cellular processes. The fate determinants demonstrate either coupled or separate regulation between the two processes. The temporal coordination appears to facilitate cell migration during fate specification or tissue growth. Our quantitative dataset with cellular resolution provides a resource for future analyses of the genetic control of spatial and temporal coordination during metazoan development., link_to_OA_fulltext

Published

2015

7. PLK-1 asymmetry contributes to asynchronous cell division of C. elegans embryos.

Author

Budirahardja, Yemima and Gönczy, Pierre

Subjects

*PROTEIN kinases, *CELL division, *CAENORHABDITIS elegans, *EMBRYOS, *MITOSIS

Abstract

Acquisition of lineage-specific cell cycle duration is an important feature of metazoan development. In Caenorhabditis elegans, differences in cell cycle duration are already apparent in two-cell stage embryos, when the larger anterior blastomere AB divides before the smaller posterior blastomere P1. This time difference is under the control of anterior-posterior (A-P) polarity cues set by the PAR proteins. The mechanisms by which these cues regulate the cell cycle machinery differentially in AB and P1 are incompletely understood. Previous work established that retardation of P1 cell division is due in part to preferential activation of an ATL-1/CHK-1 dependent checkpoint in P1, but how the remaining time difference is controlled is not known. Here, we establish that differential timing relies also on a mechanism that promotes mitosis onset preferentially in AB. The polo-like kinase PLK-1, a positive regulator of mitotic entry, is distributed in an asymmetric manner in two-cell stage embryos, with more protein present in AB than in P1. We find that PLK-1 asymmetry is regulated by A-P polarity cues through preferential protein retention in the embryo anterior. Importantly, mild inactivation of plk-1 by RNAi delays entry into mitosis in P1, but not in AB, in a manner that is independent of ATL-1/CHK-1. Together, our findings support a model in which differential timing of mitotic entry in C. elegans embryos relies on two complementary mechanisms: ATL-1/CHK-1-dependent preferential retardation in P1 and PLK-1-dependent preferential promotion in AB, which together couple polarity cues and cell cycle progression during early development. [ABSTRACT FROM AUTHOR]

Published

2008