The pipe and the pinwheel: Is pressure an effective stimulus for the 9 + 0 primary cilium?

Andrew Bell

doi:10.1016/j.cellbi.2008.03.001

The pipe and the pinwheel: Is pressure an effective stimulus for the 9 + 0 primary cilium?

Andrew Bell^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

20 Citations (Scopus)

Abstract

Almost universally, the effective stimulus for mammalian 9 + 0 primary cilia has been taken to be bending. In this article I point out that in several physiological contexts there is great advantage in detecting pressure differences across the cell wall, i.e. axially directed forces pushing fluid to and fro through the hollow cilium and its basal body beneath. The form of the cilium - a fluid-filled pipe that connects to an intricate pinwheel-shaped basal body - is well configured for detecting fluid flow. Pressure-detection calls for compressible elements within the cell, but it effectively matches form and function in a range of cases. The "pipe and pinwheel" scheme suggests that the bulbous swellings commonly found near the tip of some primary cilia are compliant, pressure-sensitive elements which act like the bulb of an eye-dropper. In looking exclusively at the bending of cilia, we might be missing aspects of a dual-stimulus system. Crown

Original language	English
Pages (from-to)	462-468
Number of pages	7
Journal	Cell Biology International
Volume	32
Issue number	4
DOIs	https://doi.org/10.1016/j.cellbi.2008.03.001
Publication status	Published - Apr 2008

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10.1016/j.cellbi.2008.03.001

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abstract = "Almost universally, the effective stimulus for mammalian 9 + 0 primary cilia has been taken to be bending. In this article I point out that in several physiological contexts there is great advantage in detecting pressure differences across the cell wall, i.e. axially directed forces pushing fluid to and fro through the hollow cilium and its basal body beneath. The form of the cilium - a fluid-filled pipe that connects to an intricate pinwheel-shaped basal body - is well configured for detecting fluid flow. Pressure-detection calls for compressible elements within the cell, but it effectively matches form and function in a range of cases. The {"}pipe and pinwheel{"} scheme suggests that the bulbous swellings commonly found near the tip of some primary cilia are compliant, pressure-sensitive elements which act like the bulb of an eye-dropper. In looking exclusively at the bending of cilia, we might be missing aspects of a dual-stimulus system. Crown",

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AB - Almost universally, the effective stimulus for mammalian 9 + 0 primary cilia has been taken to be bending. In this article I point out that in several physiological contexts there is great advantage in detecting pressure differences across the cell wall, i.e. axially directed forces pushing fluid to and fro through the hollow cilium and its basal body beneath. The form of the cilium - a fluid-filled pipe that connects to an intricate pinwheel-shaped basal body - is well configured for detecting fluid flow. Pressure-detection calls for compressible elements within the cell, but it effectively matches form and function in a range of cases. The "pipe and pinwheel" scheme suggests that the bulbous swellings commonly found near the tip of some primary cilia are compliant, pressure-sensitive elements which act like the bulb of an eye-dropper. In looking exclusively at the bending of cilia, we might be missing aspects of a dual-stimulus system. Crown

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KW - Bowden cable

KW - Flagellar pore complex

KW - Kinetosome

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JO - Cell Biology International

JF - Cell Biology International

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The pipe and the pinwheel: Is pressure an effective stimulus for the 9 + 0 primary cilium?

Abstract

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