Mouse respiratory cilia with the asymmetric axonemal structure on sparsely distributed ciliary cells can generate overall directional flow

Mucociliary clearance on the surface of the tracheal lumen is an important component of lung defense against dust mites and viruses. However, the axonemal structure that achieves effective ciliary motion, and the mechanisms by which discretely distributed ciliary cells generate directional flow are unknown. In this study, we examined individual ciliary motion with 7- to 9-nm spatial precision by labeling the ciliary tip with quantum dots and detected an asymmetric beating pattern. Cryo-electron tomography revealed that the densities of two inner dynein arms were missing from at least 2 doublet microtubules in the axonemal structure. Although the flow directions generated by individual ciliated cells were unsteady and diverse, the time- and space-averaged velocity field was found to be directional. These results indicate that the asymmetric ciliary motion is driven by the asymmetric axonemal structure, and it generates overall directional flow from the lungs to the oropharynx on sparsely distributed ciliated cells.From the Clinical EditorThe authors of this study utilized quantum dots in determining the kinetics of ciliary motion in mouse respiratory cilia with 7- to 9-nm spatial precision.

Graphical AbstractThe fluid flow with effective ciliary motion on the surface of the tracheal lumen is an important part of lung defense against dust mites, viruses, or other harmful substances. In this article, the authors examined the axonemal structure by cryo-electron tomography. The densities of two inner dynein arm subspecies were missing from at least two doublet microtubules, indicating that the asymmetric axonemal structure contributes to asymmetric ciliary motion, generates overall directional flow from the lungs to the oropharynx in airway.Figure optionsDownload high-quality image (369 K)Download as PowerPoint slide