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Reorganization of complex ciliary flows around regenerating Stentor coeruleus (2020)

Wan, Kirsty Y. ; Hürlimann, Sylvia K. ; Fenix, Aidan M. ; [et al.]

The Royal Society

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Publication Date: 2022-10-27

Description: © The Author(s), 2020. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Wan, K. Y., Hurlimann, S. K., Fenix, A. M., McGillivary, R. M., Makushok, T., Burns, E., Sheung, J. Y., & Marshall, W. F. Reorganization of complex ciliary flows around regenerating Stentor coeruleus. Philosophical Transactions of the Royal Society of London.Series B, Biological Sciences, 375(1792), (2020): 20190167, doi: 10.1098/rstb.2019.0167.

Description: The phenomenon of ciliary coordination has garnered increasing attention in recent decades and multiple theories have been proposed to explain its occurrence in different biological systems. While hydrodynamic interactions are thought to dictate the large-scale coordinated activity of epithelial cilia for fluid transport, it is rather basal coupling that accounts for synchronous swimming gaits in model microeukaryotes such as Chlamydomonas. Unicellular ciliates present a fascinating yet understudied context in which coordination is found to persist in ciliary arrays positioned across millimetre scales on the same cell. Here, we focus on the ciliate Stentor coeruleus, chosen for its large size, complex ciliary organization, and capacity for cellular regeneration. These large protists exhibit ciliary differentiation between cortical rows of short body cilia used for swimming, and an anterior ring of longer, fused cilia called the membranellar band (MB). The oral cilia in the MB beat metachronously to produce strong feeding currents. Remarkably, upon injury, the MB can be shed and regenerated de novo. Here, we follow and track this developmental sequence in its entirety to elucidate the emergence of coordinated ciliary beating: from band formation, elongation, curling and final migration towards the cell anterior. We reveal a complex interplay between hydrodynamics and ciliary restructuring in Stentor, and highlight for the first time the importance of a ring-like topology for achieving long-range metachronism in ciliated structures.

Description: We gratefully acknowledge financial support from the Marine Biology Laboratory at Woods Hole, MA, NIH grant no. R35 GM097017 (W.F.M.) and the University of Exeter, UK (K.Y.W.).

Keywords: Metachronal waves ; Ciliary flows ; Regeneration ; Stentor ; Morphogenesis ; Cilia coordination

Repository Name: Woods Hole Open Access Server

Type: Article

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