RAD-TGTs: high-throughput measurement of cellular mechanotype via rupture and delivery of DNA tension probes

Matthew R. Pawlak; Adam T. Smiley; Maria Paz Ramirez; Marcus D. Kelly; Ghaidan A. Shamsan; Sarah M. Anderson; Branden A. Smeester; David A. Largaespada; David J. Odde; Wendy R. Gordon

doi:10.1038/s41467-023-38157-6

RAD-TGTs: high-throughput measurement of cellular mechanotype via rupture and delivery of DNA tension probes

Matthew R. Pawlak, Adam T. Smiley, Maria Paz Ramirez, Marcus D. Kelly, Ghaidan A. Shamsan, Sarah M. Anderson, Branden A. Smeester, David A. Largaespada, David J. Odde, Wendy R. Gordon

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Abstract

Mechanical forces drive critical cellular processes that are reflected in mechanical phenotypes, or mechanotypes, of cells and their microenvironment. We present here “Rupture And Deliver” Tension Gauge Tethers (RAD-TGTs) in which flow cytometry is used to record the mechanical history of thousands of cells exerting forces on their surroundings via their propensity to rupture immobilized DNA duplex tension probes. We demonstrate that RAD-TGTs recapitulate prior DNA tension probe studies while also yielding a gain of fluorescence in the force-generating cell that is detectable by flow cytometry. Furthermore, the rupture propensity is altered following disruption of the cytoskeleton using drugs or CRISPR-knockout of mechanosensing proteins. Importantly, RAD-TGTs can differentiate distinct mechanotypes among mixed populations of cells. We also establish oligo rupture and delivery can be measured via DNA sequencing. RAD-TGTs provide a facile and powerful assay to enable high-throughput mechanotype profiling, which could find various applications, for example, in combination with CRISPR screens and -omics analysis.

Original language	English (US)
Article number	2468
Journal	Nature communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-38157-6
State	Published - Dec 2023

Bibliographical note

Funding Information:
W.R.G. acknowledges funding from the NIH R35GM119483 and U54 CA210190. W.R.G. is a Pew Biomedical Scholar. M.D.K. acknowledges a Cancer Center Training grant (T32CA009138). D.J.O. acknowledges funding from NIH grants: U54 CA210190, P01 CA254849, and U54 CA268069.

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© 2023, The Author(s).

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title = "RAD-TGTs: high-throughput measurement of cellular mechanotype via rupture and delivery of DNA tension probes",

abstract = "Mechanical forces drive critical cellular processes that are reflected in mechanical phenotypes, or mechanotypes, of cells and their microenvironment. We present here “Rupture And Deliver” Tension Gauge Tethers (RAD-TGTs) in which flow cytometry is used to record the mechanical history of thousands of cells exerting forces on their surroundings via their propensity to rupture immobilized DNA duplex tension probes. We demonstrate that RAD-TGTs recapitulate prior DNA tension probe studies while also yielding a gain of fluorescence in the force-generating cell that is detectable by flow cytometry. Furthermore, the rupture propensity is altered following disruption of the cytoskeleton using drugs or CRISPR-knockout of mechanosensing proteins. Importantly, RAD-TGTs can differentiate distinct mechanotypes among mixed populations of cells. We also establish oligo rupture and delivery can be measured via DNA sequencing. RAD-TGTs provide a facile and powerful assay to enable high-throughput mechanotype profiling, which could find various applications, for example, in combination with CRISPR screens and -omics analysis.",

author = "Pawlak, {Matthew R.} and Smiley, {Adam T.} and Ramirez, {Maria Paz} and Kelly, {Marcus D.} and Shamsan, {Ghaidan A.} and Anderson, {Sarah M.} and Smeester, {Branden A.} and Largaespada, {David A.} and Odde, {David J.} and Gordon, {Wendy R.}",

note = "Funding Information: W.R.G. acknowledges funding from the NIH R35GM119483 and U54 CA210190. W.R.G. is a Pew Biomedical Scholar. M.D.K. acknowledges a Cancer Center Training grant (T32CA009138). D.J.O. acknowledges funding from NIH grants: U54 CA210190, P01 CA254849, and U54 CA268069. Publisher Copyright: {\textcopyright} 2023, The Author(s).",

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AU - Pawlak, Matthew R.

AU - Smiley, Adam T.

AU - Ramirez, Maria Paz

AU - Kelly, Marcus D.

AU - Shamsan, Ghaidan A.

AU - Anderson, Sarah M.

AU - Smeester, Branden A.

AU - Largaespada, David A.

AU - Odde, David J.

AU - Gordon, Wendy R.

N1 - Funding Information: W.R.G. acknowledges funding from the NIH R35GM119483 and U54 CA210190. W.R.G. is a Pew Biomedical Scholar. M.D.K. acknowledges a Cancer Center Training grant (T32CA009138). D.J.O. acknowledges funding from NIH grants: U54 CA210190, P01 CA254849, and U54 CA268069. Publisher Copyright: © 2023, The Author(s).

PY - 2023/12

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N2 - Mechanical forces drive critical cellular processes that are reflected in mechanical phenotypes, or mechanotypes, of cells and their microenvironment. We present here “Rupture And Deliver” Tension Gauge Tethers (RAD-TGTs) in which flow cytometry is used to record the mechanical history of thousands of cells exerting forces on their surroundings via their propensity to rupture immobilized DNA duplex tension probes. We demonstrate that RAD-TGTs recapitulate prior DNA tension probe studies while also yielding a gain of fluorescence in the force-generating cell that is detectable by flow cytometry. Furthermore, the rupture propensity is altered following disruption of the cytoskeleton using drugs or CRISPR-knockout of mechanosensing proteins. Importantly, RAD-TGTs can differentiate distinct mechanotypes among mixed populations of cells. We also establish oligo rupture and delivery can be measured via DNA sequencing. RAD-TGTs provide a facile and powerful assay to enable high-throughput mechanotype profiling, which could find various applications, for example, in combination with CRISPR screens and -omics analysis.

AB - Mechanical forces drive critical cellular processes that are reflected in mechanical phenotypes, or mechanotypes, of cells and their microenvironment. We present here “Rupture And Deliver” Tension Gauge Tethers (RAD-TGTs) in which flow cytometry is used to record the mechanical history of thousands of cells exerting forces on their surroundings via their propensity to rupture immobilized DNA duplex tension probes. We demonstrate that RAD-TGTs recapitulate prior DNA tension probe studies while also yielding a gain of fluorescence in the force-generating cell that is detectable by flow cytometry. Furthermore, the rupture propensity is altered following disruption of the cytoskeleton using drugs or CRISPR-knockout of mechanosensing proteins. Importantly, RAD-TGTs can differentiate distinct mechanotypes among mixed populations of cells. We also establish oligo rupture and delivery can be measured via DNA sequencing. RAD-TGTs provide a facile and powerful assay to enable high-throughput mechanotype profiling, which could find various applications, for example, in combination with CRISPR screens and -omics analysis.

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RAD-TGTs: high-throughput measurement of cellular mechanotype via rupture and delivery of DNA tension probes

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