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Title: In Vivo Photocontrol of Microtubule Dynamics and Integrity, Migration and Mitosis, by the Potent GFP-Imaging-Compatible Photoswitchable Reagents SBTubA4P and SBTub2M
Author: Gao, Li
Meiring, Joyce C. M.
Varady, Adam
Ruider, Iris E.
Heise, Constanze
Wranik, Maximilian
Velasco, Cecilia D.
Taylor, Jennifer A.
Terni, Beatrice
Weinert, Tobias
Standfuss, Jörg
Cabernard, Clemens C.
Llobet Berenguer, Artur, 1972-
Steinmetz, Michel O.
Bausch, Andreas R.
Distel, Martin
Thorn-Seshold, Julia
Akhmanova, Anna
Thorn-Seshold, Oliver
Keywords: Citosquelet
Issue Date: 15-Mar-2022
Publisher: American Chemical Society (ACS)
Abstract: Photoswitchable reagents arc powerful tools for high-precision studies in cell biology. When these reagents are globally administered yet locally photoactivated in two-dimensional (2D) cell cultures, they can exert micron- and millisecond-scale biological control. This gives them great potential for use in biologically more relevant three-dimensional (3D) models and in vivo, particularly for studying systems with inherent spatiotemporal complexity, such as the cytoskeleton. However, due to a combination of photoswitch isomerization under typical imaging conditions, metabolic liabilities, and insufficient water solubility at effective concentrations, the in vivo potential of photoswitchable reagents addressing cytosolic protein targets remains largely unrealized. Here, we optimized the potency and solubility of metabolically stable, druglike colchicinoid microtubule inhibitors based on the styrylbenzothiazole (SBT) scaffold that are nonresponsive to typical fluorescent protein imaging wavelengths and so enable multichannel imaging studies. We applied these reagents both to 3D organoids and tissue explants and to classic model organisms (zebrafish, clawed frog) in one- and two-protein imaging experiments, in which spatiotemporally localized illuminations allowed them to photocontrol microtubule dynamics, network architecture, and microtubule-dependent processes in vivo with cellular precision and second-level resolution. These nanomolar, in vivo capable photoswitchable reagents should open up new dimensions for high-precision cytoskeleton research in cargo transport, cell motility, cell division, and development. More broadly, their design can also inspire similarly capable optical reagents for a range of cytosolic protein targets, thus bringing in vivo photopharmacology one step doser to general realization.
Note: Reproducció del document publicat a:
It is part of: Journal of the American Chemical Society, 2022, vol. 144, num. 12, p. 5614-5628
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ISSN: 0002-7863
Appears in Collections:Articles publicats en revistes (Institut d'lnvestigació Biomèdica de Bellvitge (IDIBELL))

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