Excess microtubule and F-actin formation mediates shortening and loss of primary cilia in response to a hyperosmotic milieu
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Abstract
The primary cilium is a small organelle protruding from the cell surface that receives signals from the extracellular milieu. Although dozens of studies have reported that several genetic factors can impair the structure of primary cilia, evidence for environmental stimuli affecting primary cilia structures is limited. Here, we investigated an extracellular stress that affected primary cilia morphology and its underlying mechanisms. Hyperosmotic shock induced reversible shortening and disassembly of the primary cilia of murine intramedullary collecting duct cells. The shortening of primary cilia caused by hyperosmotic shock followed delocalization of the pericentriolar material (PCM). Excessive microtubule and F-actin formation in the cytoplasm coincided with the hyperosmotic shock-induced changes to primary cilia and the PCM. Treatment with a microtubule-disrupting agent, nocodazole, partially prevented the hyperosmotic shock-induced disassembly of primary cilia and almost completely prevented delocalization of the PCM. An actin polymerization inhibitor, latrunculin A, also partially prevented the hyperosmotic shock-induced shortening and disassembly of primary cilia and almost completely prevented delocalization of the PCM. We demonstrate that hyperosmotic shock induces reversible morphological changes in primary cilia and the PCM in a manner dependent on excessive formation of microtubule and F-actin.
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PTX failed to prevent the hyperosmotic shock-induced loss of primary cilia at any PTX concentration we tested
What is the percentage of ciliated cells and cilia length with PTX treatment in the iso-osmotic conditions? If hyperosmotic cilium changes are accompanied by excess MT formation, prevented by MT depolymerization, and both hyperosmotic and PTX treated cells promote cytoplasmic MT bundling/polymerization, what is the effect of PTX-associated MT polymerization (without hyperosmotic shock) on cilium frequency and length, and ODF2-positive cells under these experimental conditions? This would tell you if the excessive microtubules alone vs other factors caused by hyperosmotic shock were drivers of ciliary shortening/loss.
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