Quantitative mapping of fluorescently tagged cellular proteins using FCS-calibrated four-dimensional imaging
Quantitative mapping of fluorescently tagged cellular proteins using FCS-calibrated four-dimensional imaging
The ability to tag a protein at its endogenous locus with a fluorescent protein (FP) enables quantitative understanding of protein dynamics at the physiological level. Genome-editing technology has now made this powerful approach routinely applicable to mammalian cells and many other model systems, thereby opening up the possibility to systematically and quantitatively map the cellular proteome in four dimensions. 3D time-lapse confocal microscopy (4D imaging) is an essential tool for investigating spatial and temporal protein dynamics; however, it lacks the required quantitative power to make the kind of absolute and comparable measurements required for systems analysis. In contrast, fluorescence correlation spectroscopy (FCS) provides quantitative proteomic and biophysical parameters such as protein concentration, hydrodynamic radius, and oligomerization but lacks the capability for high-throughput application in 4D spatial and temporal imaging. Here we present an automated experimental and computational workflow that integrates both methods and delivers quantitative 4D imaging data in high throughput. These data are processed to yield a calibration curve relating the fluorescence intensities (FIs) of image voxels to the absolute protein abundance. The calibration curve allows the conversion of the arbitrary FIs to protein amounts for all voxels of 4D imaging stacks. Using our workflow, users can acquire and analyze hundreds of FCS-calibrated image series to map their proteins of interest in four dimensions. Compared with other protocols, the current protocol does not require additional calibration standards and provides an automated acquisition pipeline for FCS and imaging data. The protocol can be completed in 1 d.
1445-1464
Politi, Antonio Z
871fe135-9a46-4bb8-b438-6584dfabfb77
Cai, Yin
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Walther, Nike
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Hossain, M Julius
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Koch, Birgit
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Wachsmuth, Malte
b44304b0-9abd-45a6-843c-bcf34546ed55
Ellenberg, Jan
7b8ab9a9-8076-4db1-b7a2-8445accc9b54
24 June 2018
Politi, Antonio Z
871fe135-9a46-4bb8-b438-6584dfabfb77
Cai, Yin
5910c9ad-90b1-47aa-8900-1b6f918b202e
Walther, Nike
2fb252f0-1e43-4a3c-9f4d-8da537217307
Hossain, M Julius
bba1b875-7604-462b-a55b-ba0b54f728e8
Koch, Birgit
6462697f-31fc-4642-8cef-8c86a9d1cf91
Wachsmuth, Malte
b44304b0-9abd-45a6-843c-bcf34546ed55
Ellenberg, Jan
7b8ab9a9-8076-4db1-b7a2-8445accc9b54
Politi, Antonio Z, Cai, Yin, Walther, Nike, Hossain, M Julius, Koch, Birgit, Wachsmuth, Malte and Ellenberg, Jan
(2018)
Quantitative mapping of fluorescently tagged cellular proteins using FCS-calibrated four-dimensional imaging.
Nature Protocols, 13, .
(doi:10.1038/nprot.2018.040).
Abstract
The ability to tag a protein at its endogenous locus with a fluorescent protein (FP) enables quantitative understanding of protein dynamics at the physiological level. Genome-editing technology has now made this powerful approach routinely applicable to mammalian cells and many other model systems, thereby opening up the possibility to systematically and quantitatively map the cellular proteome in four dimensions. 3D time-lapse confocal microscopy (4D imaging) is an essential tool for investigating spatial and temporal protein dynamics; however, it lacks the required quantitative power to make the kind of absolute and comparable measurements required for systems analysis. In contrast, fluorescence correlation spectroscopy (FCS) provides quantitative proteomic and biophysical parameters such as protein concentration, hydrodynamic radius, and oligomerization but lacks the capability for high-throughput application in 4D spatial and temporal imaging. Here we present an automated experimental and computational workflow that integrates both methods and delivers quantitative 4D imaging data in high throughput. These data are processed to yield a calibration curve relating the fluorescence intensities (FIs) of image voxels to the absolute protein abundance. The calibration curve allows the conversion of the arbitrary FIs to protein amounts for all voxels of 4D imaging stacks. Using our workflow, users can acquire and analyze hundreds of FCS-calibrated image series to map their proteins of interest in four dimensions. Compared with other protocols, the current protocol does not require additional calibration standards and provides an automated acquisition pipeline for FCS and imaging data. The protocol can be completed in 1 d.
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e-pub ahead of print date: 24 May 2018
Published date: 24 June 2018
Identifiers
Local EPrints ID: 458237
URI: http://eprints.soton.ac.uk/id/eprint/458237
ISSN: 1754-2189
PURE UUID: 0158eb7a-595a-4223-8f39-b227028e6d60
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Date deposited: 01 Jul 2022 16:59
Last modified: 17 Mar 2024 04:12
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Contributors
Author:
Antonio Z Politi
Author:
Yin Cai
Author:
Nike Walther
Author:
M Julius Hossain
Author:
Birgit Koch
Author:
Malte Wachsmuth
Author:
Jan Ellenberg
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