cilia and flagella

Separating cilia with a oh-so-thin blade

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Multiple beating cilia need some form of coupling to synchronise. In groups of cells, hydrodynamic coupling can be enough… but for single cells, it seems to be essential to have internal mechanical connections. In this case, does hydrodynamics play any role at all? In a new paper, just out in Physical Review Letters (Editors’ Suggestion!), we use a tip-less AFM cantilever (sub-micron thin!) to block hydrodynamic coupling between the two flagella of a single Chlamydomonas cell. The results highlight a striking difference between wild type, with its two different flagella, and the flagellar dominance mutant ptx1. This work was spearheaded by Luc Zorrilla (who’s just defended his thesis!), in collaboration with Antoine Allard (LOMA, U. Bordeaux) and Krish Desai (former MPhys student, Physics Department, U. Warwick).

Eukaryotic flagella synchronise through hydrodynamics

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Two cells synch

Article published on eLife. See also accompanying Insight by B. Friederich and I. Riedel-Kruse.

After many years working on Chlamydomonas, we finally graduated to multiple cells… But from a different organism: Volvox carteri. This multicellular relative of Chlamy has thousands of biflagellate somatic cells on its surface, which can be easily extracted from the colony and keep on beating for several hours. We grabbed two with independent micropipettes and showed that below a critical separation, the cells synchronise their beating. Synchronisation has a purely hydrodynamic origin. At the same time, their interaction changes the waveform of their flagella. Flagellar elasticity cooperates with hydrodynamic stresses to generate synchrony as predicted a few years ago!