Measurement of Microtubule Stability in Mammalian Cells.

The microtubule cytoskeleton is essential for various biological processes such as the intracellular distribution of molecules and organelles, cell morphogenesis, chromosome segregation, and specification of the location of contractile ring formation. Distinct cell types contain microtubules with different extents of stability. For example, microtubules in neurons are highly stabilized to support organelle (or vesicular) transport over large distances, and microtubules in motile cells are more dynamic. In some cases, such as the mitotic spindle, both dynamic and stable microtubules coexist. Alteration of microtubule stability is connected to disease states, making understanding microtubule stability an important area of research. Methods to measure microtubule stability in mammalian cells are described here. Together, these approaches allow microtubule stability to be measured qualitatively or semiquantitatively following staining for post-translational modifications of tubulin or treating cells with microtubule destabilizing agents such as nocodazole. Microtubule stability can also be measured quantitatively by performing fluorescence recovery after photobleaching or fluorescence photoactivation of tubulin in live cells. These methods should be helpful for those seeking to understand microtubule dynamics and stabilization. © 2023 Wiley Periodicals LLC. Basic Protocol 1: Fixing and staining cells for tubulin post-translational modifications Basic Protocol 2: Evaluating microtubule stability following treatment with nocodazole in live or fixed cells Basic Protocol 3: Measurement of microtubule dynamic turnover by quantification of fluorescence recovery after photobleaching Basic Protocol 4: Measurement of microtubule dynamic turnover by quantification of dissipation of fluorescence after photoactivation.

A OneStep Solution to Fix and Stain Cells for Correlative Live and Fixed Microscopy.

Correlating the location of subcellular structures with dynamic cellular behaviors is difficult when working with organisms that lack the molecular genetic tools needed for expressing fluorescent protein fusions. Here, we describe a protocol for fixing, permeabilizing, and staining cells in a single step while imaging on a microscope. In contrast to traditional, multi-step fixing and staining protocols that take hours, the protocol outlined here achieves satisfactory staining within minutes. This approach takes advantage of well-characterized small molecules that stain specific subcellular structures, including nuclei, mitochondria, and actin networks. Direct visualization of the entire process allows for rapid optimization of cell fixation and staining, as well as straightforward identification of fixation artifacts. Moreover, live imaging prior to fixation reveals the dynamic history of cellular features, making it particularly useful for model systems without the capacity for expressing fluorescent protein fusions. © 2021 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol: Fixing, permeabilizing, and staining mammalian cells in one step on the microscope.