Cell fixation by light-triggered release of glutaraldehyde

Korwin M. Schelkle; Christopher Schmid; Klaus Yserentant; Markus Bender; Irene Wacker; Martin Petzoldt; Manuel Hamburger; Dirk-Peter Herten; Richard Wombacher; Rasmus R. Schröder; Uwe H. F. Bunz

doi:10.1002/anie.201612112

Cell fixation by light-triggered release of glutaraldehyde

Korwin M. Schelkle, Christopher Schmid, Klaus Yserentant, Markus Bender, Irene Wacker, Martin Petzoldt, Manuel Hamburger, Dirk-Peter Herten, Richard Wombacher, Rasmus R. Schröder, Uwe H. F. Bunz

Cardiovascular Sciences

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

5 Citations (Scopus)

279 Downloads (Pure)

Abstract

Chemical fixation of living cells for microscopy is commonly achieved by crosslinking of intracellular proteins with dialdehydes prior to examination. We herein report a photocleavable protecting group for glutaraldehyde that results in a light‐triggered and membrane‐permeable fixative, which is nontoxic prior to photocleavage. Lipophilic ester groups allow for diffusion across the cell membrane and intracellular accumulation after enzymatic hydrolysis. Irradiation with UV light releases glutaraldehyde. The in situ generated fixative crosslinks intracellular proteins and preserves and stabilizes the cell so that it is ready for microscopy. In contrast to conventional glutaraldehyde fixation, tissue autofluorescence does not increase after fixation. Caged glutaraldehyde may in future enable functional experiments on living cells under a light microscope in which events of interest can be stopped in spatially confined volumes at defined time points. Samples with individually stopped events could then later be analyzed in ultrastructural studies.

Original language	English
Pages (from-to)	4724-4728
Number of pages	5
Journal	Angewandte Chemie (International Edition)
Volume	56
Issue number	17
Early online date	22 Mar 2017
DOIs	https://doi.org/10.1002/anie.201612112
Publication status	Published - 18 Apr 2017

Keywords

cell fixation
glutaraldehyde
microscopy
mitochondrial motion
photocleavage

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10.1002/anie.201612112Licence: None: All rights reserved

Schelkle_et_al_Cell_fixation_by_light-triggered_release_of_glutaraldehyde_Angewandte_Chemie_(International_Edition)_2017
This is the peer reviewed version of the following article: K. M. Schelkle, C. Schmid, K. Yserentant, M. Bender, I. Wacker, M. Petzoldt, M. Hamburger, D.-P. Herten, R. Wombacher, R. R. Schröder, U. H. F. Bunz, Angew. Chem. Int. Ed. 2017, 56, 4724., which has been published in final form at https://onlinelibrary.wiley.com/doi/full/10.1002/anie.201612112. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived Versions.
Accepted author manuscript, 1.37 MBLicence: Other (please specify with Rights Statement)

https://onlinelibrary.wiley.com/doi/full/10.1002/anie.201612112Licence: None: All rights reserved

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title = "Cell fixation by light-triggered release of glutaraldehyde",

abstract = "Chemical fixation of living cells for microscopy is commonly achieved by crosslinking of intracellular proteins with dialdehydes prior to examination. We herein report a photocleavable protecting group for glutaraldehyde that results in a light‐triggered and membrane‐permeable fixative, which is nontoxic prior to photocleavage. Lipophilic ester groups allow for diffusion across the cell membrane and intracellular accumulation after enzymatic hydrolysis. Irradiation with UV light releases glutaraldehyde. The in situ generated fixative crosslinks intracellular proteins and preserves and stabilizes the cell so that it is ready for microscopy. In contrast to conventional glutaraldehyde fixation, tissue autofluorescence does not increase after fixation. Caged glutaraldehyde may in future enable functional experiments on living cells under a light microscope in which events of interest can be stopped in spatially confined volumes at defined time points. Samples with individually stopped events could then later be analyzed in ultrastructural studies.",

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AU - Schelkle, Korwin M.

AU - Schmid, Christopher

AU - Yserentant, Klaus

AU - Bender, Markus

AU - Wacker, Irene

AU - Petzoldt, Martin

AU - Hamburger, Manuel

AU - Herten, Dirk-Peter

AU - Wombacher, Richard

AU - Schröder, Rasmus R.

AU - Bunz, Uwe H. F.

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N2 - Chemical fixation of living cells for microscopy is commonly achieved by crosslinking of intracellular proteins with dialdehydes prior to examination. We herein report a photocleavable protecting group for glutaraldehyde that results in a light‐triggered and membrane‐permeable fixative, which is nontoxic prior to photocleavage. Lipophilic ester groups allow for diffusion across the cell membrane and intracellular accumulation after enzymatic hydrolysis. Irradiation with UV light releases glutaraldehyde. The in situ generated fixative crosslinks intracellular proteins and preserves and stabilizes the cell so that it is ready for microscopy. In contrast to conventional glutaraldehyde fixation, tissue autofluorescence does not increase after fixation. Caged glutaraldehyde may in future enable functional experiments on living cells under a light microscope in which events of interest can be stopped in spatially confined volumes at defined time points. Samples with individually stopped events could then later be analyzed in ultrastructural studies.

AB - Chemical fixation of living cells for microscopy is commonly achieved by crosslinking of intracellular proteins with dialdehydes prior to examination. We herein report a photocleavable protecting group for glutaraldehyde that results in a light‐triggered and membrane‐permeable fixative, which is nontoxic prior to photocleavage. Lipophilic ester groups allow for diffusion across the cell membrane and intracellular accumulation after enzymatic hydrolysis. Irradiation with UV light releases glutaraldehyde. The in situ generated fixative crosslinks intracellular proteins and preserves and stabilizes the cell so that it is ready for microscopy. In contrast to conventional glutaraldehyde fixation, tissue autofluorescence does not increase after fixation. Caged glutaraldehyde may in future enable functional experiments on living cells under a light microscope in which events of interest can be stopped in spatially confined volumes at defined time points. Samples with individually stopped events could then later be analyzed in ultrastructural studies.

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KW - microscopy

KW - mitochondrial motion

KW - photocleavage

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Cell fixation by light-triggered release of glutaraldehyde

Abstract

Keywords

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