High-throughput genome-wide phenotypic screening via immunomagnetic cell sorting

Barbara Mair; Peter M. Aldridge; Randy S. Atwal; David Philpott; Meng Zhang; Sanna N. Masud; Mahmoud Labib; Amy H.Y. Tong; Edward H. Sargent; Stéphane Angers; Jason Moffat; Shana O. Kelley

doi:10.1038/s41551-019-0454-8

High-throughput genome-wide phenotypic screening via immunomagnetic cell sorting

Barbara Mair, Peter M. Aldridge, Randy S. Atwal, David Philpott, Meng Zhang, Sanna N. Masud, Mahmoud Labib, Amy H.Y. Tong, Edward H. Sargent, Stéphane Angers, Jason Moffat^*, Shana O. Kelley

^*Corresponding author for this work

Chemistry

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

69 Scopus citations

Abstract

Genome-scale functional genetic screens are used to identify key genetic regulators of a phenotype of interest. However, the identification of genetic modifications that lead to a phenotypic change requires sorting large numbers of cells, which increases operational times and costs and limits cell viability. Here, we introduce immunomagnetic cell sorting facilitated by a microfluidic chip as a rapid and scalable high-throughput method for loss-of-function phenotypic screening using CRISPR–Cas9. We used the method to process an entire genome-wide screen containing more than 10⁸ cells in less than 1 h—considerably surpassing the throughput achieved by fluorescence-activated cell sorting, the gold-standard technique for phenotypic cell sorting—while maintaining high levels of cell viability. We identified modulators of the display of CD47, which is a negative regulator of phagocytosis and an important cell-surface target for immuno-oncology drugs. The top hit of the screen, the glutaminyl cyclase QPCTL, was validated and shown to modify the N-terminal glutamine of CD47. The method presented could bridge the gap between fluorescence-activated cell sorting and less flexible yet higher-throughput systems such as magnetic-activated cell sorting.

Original language	English (US)
Pages (from-to)	796-805
Number of pages	10
Journal	Nature Biomedical Engineering
Volume	3
Issue number	10
DOIs	https://doi.org/10.1038/s41551-019-0454-8
State	Published - Oct 1 2019

Funding

We thank members of the Kelley, Moffat, Angers and C. Boone and B. Andrews laboratories for helpful discussions; K. Chan for TKOv3 library virus preparation; M. Usaj for help with data analysis; P. Mero for administrative assistance; J. Tomic for help with tissue culture; E. Cohen, M. Soste and F. Soares for technical assistance; D. White and J. Warzyszynska for flow cytometry assistance; and staff at the Centre for Applied Genomics (TCAG) at the Hospital for Sick Children (SickKids) for sequencing. This work was supported by grants from the Canadian Institutes for Health Research (to J.M., S.O.K. and S.A.) and the University of Toronto’s Medicine by Design initiative, which receives funding from the Canada First Research Excellence Fund (to S.O.K., J.M. and S.A). J.M. is a Canada Research Chair in Functional Genomics.

ASJC Scopus subject areas

Bioengineering
Biotechnology
Biomedical Engineering
Medicine (miscellaneous)
Computer Science Applications

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abstract = "Genome-scale functional genetic screens are used to identify key genetic regulators of a phenotype of interest. However, the identification of genetic modifications that lead to a phenotypic change requires sorting large numbers of cells, which increases operational times and costs and limits cell viability. Here, we introduce immunomagnetic cell sorting facilitated by a microfluidic chip as a rapid and scalable high-throughput method for loss-of-function phenotypic screening using CRISPR–Cas9. We used the method to process an entire genome-wide screen containing more than 108 cells in less than 1 h—considerably surpassing the throughput achieved by fluorescence-activated cell sorting, the gold-standard technique for phenotypic cell sorting—while maintaining high levels of cell viability. We identified modulators of the display of CD47, which is a negative regulator of phagocytosis and an important cell-surface target for immuno-oncology drugs. The top hit of the screen, the glutaminyl cyclase QPCTL, was validated and shown to modify the N-terminal glutamine of CD47. The method presented could bridge the gap between fluorescence-activated cell sorting and less flexible yet higher-throughput systems such as magnetic-activated cell sorting.",

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AU - Moffat, Jason

AU - Kelley, Shana O.

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High-throughput genome-wide phenotypic screening via immunomagnetic cell sorting

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