Abstract
Microtubule dynamics can be inhibited with sub-second temporal resolution and cellular-scale spatial resolution, by using precise illuminations to optically pattern where and when photoswitchable microtubule-inhibiting chemical reagents exert their latent bioactivity. The recently available reagents (SBTub, PST, STEpo, AzTax, PHTub) now enable researchers to use light to reversibly modulate microtubule-dependent processes in eukaryotes, in 2D and 3D cell culture as well as in vivo, across a variety of model organisms: with applications in fields from cargo transport to cell migration, cell division, and embryonic development.
Here we give an introduction to using these photoswitchable microtubule inhibitors in cells. We describe the theory of small molecule photoswitching, and the unique performance features, usage requirements, and limitations that photoswitchable chemical reagents have; then we summarize the major classes of photoswitchable microtubule inhibitors that are currently available, with the properties that suit them to different applications, and troubleshooting measures for avoiding common mistakes. We outline workflows to establish cellular assays where they are used to optically control microtubule dynamics in a temporally reversible fashion with spatial specificity down to a single selected cell within a field of view. The methods in this chapter also equip the reader to tackle advanced uses of photoswitchable chemical reagents, in 3D culture and in vivo.
Here we give an introduction to using these photoswitchable microtubule inhibitors in cells. We describe the theory of small molecule photoswitching, and the unique performance features, usage requirements, and limitations that photoswitchable chemical reagents have; then we summarize the major classes of photoswitchable microtubule inhibitors that are currently available, with the properties that suit them to different applications, and troubleshooting measures for avoiding common mistakes. We outline workflows to establish cellular assays where they are used to optically control microtubule dynamics in a temporally reversible fashion with spatial specificity down to a single selected cell within a field of view. The methods in this chapter also equip the reader to tackle advanced uses of photoswitchable chemical reagents, in 3D culture and in vivo.
| Original language | English |
|---|---|
| Title of host publication | Microtubules |
| Subtitle of host publication | Methods and Protocols |
| Place of Publication | New York |
| Publisher | Humana Press |
| Chapter | 26 |
| Pages | 403-430 |
| Number of pages | 28 |
| Edition | 1 |
| ISBN (Electronic) | 978-1-0716-1983-4 |
| ISBN (Print) | 978-1-0716-1982-7, 978-1-0716-1985-8 |
| DOIs | |
| Publication status | Published - 28 Apr 2022 |
Publication series
| Name | Methods in Molecular Biology |
|---|---|
| Publisher | Springer |
| Volume | 2430 |
| ISSN (Print) | 1064-3745 |
| ISSN (Electronic) | 1940-6029 |
Bibliographical note
Publisher Copyright:© 2022, The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.
Keywords
- Cell division
- Cell migration
- Cytoskeleton
- Development
- Microtubule dynamics
- Optical control
- Optogenetics
- Photocontrol
- Photopharmaceutical
- Photopharmacology
- Photoswitch
- Tubulin polymerization inhibitor