Mitotic cell rounding

Cell shape changes as a function of mitotic phase. Shown is an example of a HeLa cell cultured on a glass surface. For visualization of DNA and mitotic phase assignment, the cell expresses Histone H2B-GFP to provide fluorescent labeling of chromosomes. Transmitted light (DIC), fluorescence (GFP), and merged images are shown every 4 minutes as the cell transitions from G2 phase through mitosis to telophase/G1 phase.

Mitotic cell rounding is a shape change that occurs in most animal cells that undergo mitosis. Cells abandon the spread or elongated shape characteristic of interphase and contract into a spherical morphology during mitosis. The phenomena is seen both in artificial cultures in vitro and naturally forming tissue in vivo.

Early observations

In 1935, one of the first published accounts of mitotic rounding in live tissue described cell rounding in the pseudostratified epithelium of the mammalian neural tube.[1] Sauer noticed that cells in mitosis rounded up to the apical, or luminal, surface of the columnar epithelium before dividing and returning to their elongated morphology.

Significance

For a long time it was not clear why cells became round in mitosis. Recent studies in the epithelia and epidermis of various organisms, however, show that mitotic cell rounding might serve several important functions.[2]

Thus mitotic cell rounding is involved in tissue organization and homeostasis.

Mechanisms

To understand the physical mechanisms of how cells round up in mitosis researchers have conducted mechanical measurements with cultured cells in vitro. The forces that drive cell rounding have recently been characterized by researchers from the groups of Professors Tony Hyman and Daniel Muller, who used flat atomic force microscopy cantilevers to constrain mitotic cells and measure the response force.[10][11] More than 90% of the forces are generated by the collective activity of myosin II molecular motors in the actin cortex.[10][11] As a result, the surface tension and effective stiffness of the actin cortex increase as has been consistently observed in mitotic cells.[12][13][14] This in turn yields an increase in intracellular hydrostatic pressure due to the Law of Laplace, which relates surface tension of a fluid interface to the differential pressure sustained across that interface.[15] The increase in hydrostatic pressure is important because it produces the outward force necessary to push and rounds up against external objects or impediments, such as flexible cantilever[10][11] or soft gel[8] (in vitro examples), or surrounding extracellular matrix and neighboring cells[7] (in vivo examples). In HeLa cells in vitro, the force generated by a half-deformed mitotic cell is on the order of 50 to 100 nanonewtons.[10][11] Internal hydrostatic pressure has been measured to increase from below 100 pascals in interphase to 3 to 10 fold that in mitosis.[10][11][15]

In similar in vitro experiments, it was found that the threshold forces required to prevent mitosis are in excess of 100 nN.[9] At threshold forces the cell suffers a loss of cortical F-actin uniformity, which further amplifies the susceptibility to applied force. These effects potentiate distortion of cell dimensions and subsequent perturbation of mitotic progression via spindle defects.[8][9]

Release of stable focal adhesions is another important aspect of mitotic rounding. Cells that are genetically perturbed to manifest constitutively active adhesion regulators are unable to properly remodel their focal adhesions and facilitate the generation of a uniform actomyosin cortex.[8][16] Overall, the biochemical events governing the morphological and mechanical changes in mitotic cells are orchestrated by the mitotic master regulator Cdk1.[11][17]

References

  1. Sauer, F.C. (October 1935). "Mitosis in the neural tube". Journal of Comparative Neurology. 62 (2): 377–405. doi:10.1002/cne.900620207.
  2. 1 2 Cadart, Clotilde; Zlotek-Zlotkiewicz, Ewa; Le Berre, Mael; Piel, Matthieu; Matthews, Helen K (28 April 2014). "Exploring the function of cell shape and size during mitosis". Developmental Cell. 29 (2): 159–169. doi:10.1016/j.devcel.2014.04.009. PMID 24780736.
  3. Meyer, Emily J; Ikmi, Aissam; Gibson, Matthew C (22 March 2011). "Interkinetic nuclear migration is a broadly conserved feature of cell division in pseudostratified epithelia". Current Biology. 21 (6): 485–491. doi:10.1016/j.cub.2011.02.002. PMID 21376598.
  4. Luxenburg, Chen; Pasolli, H Amalia; Williams, Scott E; Fuchs, E (20 February 2011). "Developmental roles for Srf, cortical cytoskeleton and cell shape in epidermal spindle orientation". Nature Cell Biology. 13: 203–214. doi:10.1038/ncb2163. PMID 21336301.
  5. 1 2 Nakajima, Yu-ichiro; Meyer, Emily J; Kroesen, Amanda; McKinney, Sean A; Gibson, Matthew C (21 July 2013). "Epithelial junctions maintain tissue architecture by directing planar spindle orientation". Nature. 500: 359–362. doi:10.1038/nature12335. PMID 23873041.
  6. Kondo, Takefumi; Hayashi, Shigeo (13 January 2013). "Mitotic cell rounding accelerates epithelial invagination". Nature. 494: 125–129. doi:10.1038/nature11792.
  7. 1 2 Hoijman, Esteban; Rubbini, Davide; Colombelli, Julien; Alsina, Berta (16 June 2015). "Mitotic cell rounding and epithelial thinning regulate lumen growth and shape". Nature Communications. 6: 7355. doi:10.1038/ncomms8355.
  8. 1 2 3 4 Lancaster, Oscar M; La Berre, Mael; Dimitracopoulos, Andrea; Bonazzi, Daria; Zlotek-Zlotkiewicz, Ewa; Picone, Remigio; Duke, Thomas; Piel, Matthieu; Baum, Buzz (13 May 2013). "Mitotic rounding alters cell geometry to ensure efficient bipolar spindle formation". Developmental Cell. 25 (3): 270–283. doi:10.1016/j.devcel.2013.03.014. PMID 23623611.
  9. 1 2 3 Cattin, Cedric J; Düggelin, Marcel; Martinez-Martin, David; Gerber, Christoph; Mueller, Daniel J; Stewart, Martin P (2015). "Mechanical control of mitotic progression in single animal cells". Proceedings of the National Academy of Sciences. 112: 201502029. doi:10.1073/pnas.1502029112.
  10. 1 2 3 4 5 Stewart, Martin P; Helenius, Jonne; Toyoda, Yusuke; Ramanathan, Subramanian P; Muller, Daniel J; Hyman, Anthony A (2 January 2011). "Hydrostatic pressure and the actomyosin cortex drive mitotic cell rounding". Nature. 469: 226–230. doi:10.1038/nature09642. PMID 21196934.
  11. 1 2 3 4 5 6 Ramanathan, Subramanian P; Helenius, Jonne; Stewart, Martin P; Cattin, Cedric J; Hyman, Anthony A; Muller, Daniel J (26 January 2015). "Cdk1-dependent mitotic enrichment of cortical myosin II promotes cell rounding against confinement". Nature Cell Biology. 17: 148–159. doi:10.1038/ncb3098. PMID 25621953.
  12. Maddox, Amy S; Burridge, Keith (20 January 2003). "RhoA is required for cortical retraction and rigidity during mitotic cell rounding". Journal of Cell Biology. 160: 255–265. doi:10.1083/jcb.200207130. PMID 12538643.
  13. Kunda, Patricia; Pelling, Andrew E; Liu, Tao; Baum, Buzz (22 January 2008). "Moesin Controls Cortical Rigidity, Cell Rounding, and Spindle Morphogenesis during Mitosis". Current Biology. 18 (2): 91–101. doi:10.1016/j.cub.2007.12.051.
  14. Matthews, Helen K; Delabre, Ulysse; Rohn, Jennifer L; Guck, Jochen; Kunda, Patricia; Baum, Buzz (14 August 2012). "Changes in Ect2 localization couple actomyosin-dependent cell shape changes to mitotic progression". Developmental Cell. 23 (2): 371–383. doi:10.1016/j.devcel.2012.06.003. PMID 22898780.
  15. 1 2 Fischer-Friedrich, Elisabeth; Hyman, Anthony A; Jülicher, Frank; Müller, Daniel J; Helenius, Jonne (29 August 2014). "Quantification of surface tension and internal pressure generated by single mitotic cells". Scientific Reports. 4: 6213. doi:10.1038/srep06213. PMID 25169063.
  16. Dao, Vi Thuy; Dupuy, Aurélien Guy; Gavet, Olivier; Caron, Emmanuelle; de Gunzburg, Jean (15 August 2009). "Dynamic changes in Rap1 activity are required for cell retraction and spreading during mitosis". Journal of Cell Science. 122: 2996–3004. doi:10.1242/jcs.041301.
  17. Clark, Andrew G; Paluch, Ewa (21 April 2011). "Mechanics and Regulation of Cell Shape During the Cell Cycle". Cell Cycle in Development: 31–77. doi:10.1007/978-3-642-19065-0_3.

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