Reconstruction of the three-dimensional beat pattern underlying swimming 
behaviors of sperm

Gong, A.; Rode, S.; Gompper, G.; Kaupp, Ulrich Benjamin; Elgeti, J.; Friedrich, B. M.; Alvarez, Luis

doi:10.1140/epje/s10189-021-00076-z

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Reconstruction of the three-dimensional beat pattern underlying swimming behaviors of sperm

MPS-Authors

Gong, A.
Center of Advanced European Studies and Research (caesar), Max Planck Society;

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Kaupp, Ulrich Benjamin
Department of Molecular Sensory Systems, Center of Advanced European Studies and Research (caesar), Max Planck Society;

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Alvarez, Luis
Department of Molecular Sensory Systems, Center of Advanced European Studies and Research (caesar), Max Planck Society;
Max Planck Research Group Neural Information Flow, Center of Advanced European Studies and Research (caesar), Max Planck Society;

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Gong2021_Article_ReconstructionOfTheThree-dimen.pdf
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Citation

Gong, A., Rode, S., Gompper, G., Kaupp, U. B., Elgeti, J., Friedrich, B. M., et al. (2021). Reconstruction of the three-dimensional beat pattern underlying swimming behaviors of sperm. The European Physical Journal E, 44(7): 87. doi:10.1140/epje/s10189-021-00076-z.

Cite as: https://hdl.handle.net/21.11116/0000-0008-D5CF-F

Abstract

The eukaryotic flagellum propels sperm cells and simultaneously detects physical and chemical cues that modulate the waveform of the flagellar beat. Most previous studies have characterized the flagellar beat and swimming trajectories in two space dimensions (2D) at a water/glass interface. Here, using refined holographic imaging methods, we report high-quality recordings of three-dimensional (3D) flagellar bending waves. As predicted by theory, we observed that an asymmetric and planar flagellar beat results in a circular swimming path, whereas a symmetric and non-planar flagellar beat results in a twisted-ribbon swimming path. During swimming in 3D, human sperm flagella exhibit torsion waves characterized by maxima at the low curvature regions of the flagellar wave. We suggest that these torsion waves are common in nature and that they are an intrinsic property of beating axonemes. We discuss how 3D beat patterns result in twisted-ribbon swimming paths. This study provides new insight into the axoneme dynamics, the 3D flagellar beat, and the resulting swimming behavior.