Germline T cell receptor exchange results in physiological T cell development and function

Meagan R Rollins; Jackson Raynor; Ebony A Miller; Jonah Z. Butler; Ellen J. Spartz; Walker S Lahr; Yun You; Adam L. Burrack; Branden S. Moriarity; Beau R. Webber; Ingunn M. Stromnes

doi:10.1038/s41467-023-36180-1

Germline T cell receptor exchange results in physiological T cell development and function

Meagan R Rollins, Jackson Raynor, Ebony A Miller, Jonah Z. Butler, Ellen J. Spartz, Walker S Lahr, Yun You, Adam L. Burrack, Branden S. Moriarity, Beau R. Webber, Ingunn M. Stromnes

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1 Scopus citations

Abstract

T cell receptor (TCR) transgenic mice represent an invaluable tool to study antigen-specific immune responses. In the pre-existing models, a monoclonal TCR is driven by a non-physiologic promoter and randomly integrated into the genome. Here, we create a highly efficient methodology to develop T cell receptor exchange (TRex) mice, in which TCRs, specific to the self/tumor antigen mesothelin (Msln), are integrated into the Trac locus, with concomitant Msln disruption to circumvent T cell tolerance. We show that high affinity TRex thymocytes undergo all sequential stages of maturation, express the exogenous TCR at DN4, require MHC class I for positive selection and undergo negative selection only when both Msln alleles are present. By comparison of TCRs with the same specificity but varying affinity, we show that Trac targeting improves functional sensitivity of a lower affinity TCR and confers resistance to T cell functional loss. By generating P14 TRex mice with the same specificity as the widely used LCMV-P14 TCR transgenic mouse, we demonstrate increased avidity of Trac-targeted TCRs over transgenic TCRs, while preserving physiologic T cell development. Together, our results support that the TRex methodology is an advanced tool to study physiological antigen-specific T cell behavior.

Original language	English (US)
Article number	528
Journal	Nature communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-36180-1
State	Published - Dec 2023

Bibliographical note

Funding Information:
We thank Kris Hogquist and Maude Ashby for helpful discussions on thymocyte development. We thank Sathi Wijeyesinghe for the providing the P14 TCR DNA sequence. We thank Andrew Soerens, Ph.D. for assistance in generation of the Msln monomer. We thank Zoe Schmiechen for providing expertise for ViSNE analysis and Iris Wang and Bryan Sanchez for assistance with animal husbandry. We acknowledge the University of Minnesota Mouse Genetics Laboratory, Flow Cytometry Core, Research Animal Resource (RAR), and the Center for Immunology (CFI) imaging core. A CFI New Mouse Award (to I.M.S.), U of M Brainstorm award (to I.M.S. and B.R.W.) and NIH R03-AI144840 (to B.R.W. and B.S.M.) provided financial support. M.R.R. is supported by National Institutes of Health (NIH) T32 AI 007313 and the U of M Dennis Watson Fellowship. E.J.S. is supported by NIH T35 AI118620 and the AOA Carolyn L. Kuckein Student Research Fellowship. A.L.B. is supported by a computational training award from the American Association of Immunologists. I.M.S. is supported by NIH R01 CA249393, R01 CA255039, NIH P01 CA254849, DOD W81XWH2110525, AACR Pancreatic Cancer Action Network Career Development Award (17-20-25-STRO), an AACR Pancreatic Cancer Action Network Catalyst Award (19-35-STRO), an American Cancer Society RSG RSG-21-102-01-IBC, and pilot awards from the Masonic Cancer Center and Cancer Research Training Initiative (University of Minnesota Medical School). 406-414

Funding Information:
We thank Kris Hogquist and Maude Ashby for helpful discussions on thymocyte development. We thank Sathi Wijeyesinghe for the providing the P14 TCR DNA sequence. We thank Andrew Soerens, Ph.D. for assistance in generation of the Msln406-414 monomer. We thank Zoe Schmiechen for providing expertise for ViSNE analysis and Iris Wang and Bryan Sanchez for assistance with animal husbandry. We acknowledge the University of Minnesota Mouse Genetics Laboratory, Flow Cytometry Core, Research Animal Resource (RAR), and the Center for Immunology (CFI) imaging core. A CFI New Mouse Award (to I.M.S.), U of M Brainstorm award (to I.M.S. and B.R.W.) and NIH R03-AI144840 (to B.R.W. and B.S.M.) provided financial support. M.R.R. is supported by National Institutes of Health (NIH) T32 AI 007313 and the U of M Dennis Watson Fellowship. E.J.S. is supported by NIH T35 AI118620 and the AOA Carolyn L. Kuckein Student Research Fellowship. A.L.B. is supported by a computational training award from the American Association of Immunologists. I.M.S. is supported by NIH R01 CA249393, R01 CA255039, NIH P01 CA254849, DOD W81XWH2110525, AACR Pancreatic Cancer Action Network Career Development Award (17-20-25-STRO), an AACR Pancreatic Cancer Action Network Catalyst Award (19-35-STRO), an American Cancer Society RSG RSG-21-102-01-IBC, and pilot awards from the Masonic Cancer Center and Cancer Research Training Initiative (University of Minnesota Medical School).

Publisher Copyright:
© 2023, The Author(s).

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Research Support, Non-U.S. Gov't
Research Support, N.I.H., Extramural
Research Support, U.S. Gov't, Non-P.H.S.

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title = "Germline T cell receptor exchange results in physiological T cell development and function",

abstract = "T cell receptor (TCR) transgenic mice represent an invaluable tool to study antigen-specific immune responses. In the pre-existing models, a monoclonal TCR is driven by a non-physiologic promoter and randomly integrated into the genome. Here, we create a highly efficient methodology to develop T cell receptor exchange (TRex) mice, in which TCRs, specific to the self/tumor antigen mesothelin (Msln), are integrated into the Trac locus, with concomitant Msln disruption to circumvent T cell tolerance. We show that high affinity TRex thymocytes undergo all sequential stages of maturation, express the exogenous TCR at DN4, require MHC class I for positive selection and undergo negative selection only when both Msln alleles are present. By comparison of TCRs with the same specificity but varying affinity, we show that Trac targeting improves functional sensitivity of a lower affinity TCR and confers resistance to T cell functional loss. By generating P14 TRex mice with the same specificity as the widely used LCMV-P14 TCR transgenic mouse, we demonstrate increased avidity of Trac-targeted TCRs over transgenic TCRs, while preserving physiologic T cell development. Together, our results support that the TRex methodology is an advanced tool to study physiological antigen-specific T cell behavior.",

author = "Rollins, {Meagan R} and Jackson Raynor and Miller, {Ebony A} and Butler, {Jonah Z.} and Spartz, {Ellen J.} and Lahr, {Walker S} and Yun You and Burrack, {Adam L.} and Moriarity, {Branden S.} and Webber, {Beau R.} and Stromnes, {Ingunn M.}",

note = "Funding Information: We thank Kris Hogquist and Maude Ashby for helpful discussions on thymocyte development. We thank Sathi Wijeyesinghe for the providing the P14 TCR DNA sequence. We thank Andrew Soerens, Ph.D. for assistance in generation of the Msln monomer. We thank Zoe Schmiechen for providing expertise for ViSNE analysis and Iris Wang and Bryan Sanchez for assistance with animal husbandry. We acknowledge the University of Minnesota Mouse Genetics Laboratory, Flow Cytometry Core, Research Animal Resource (RAR), and the Center for Immunology (CFI) imaging core. A CFI New Mouse Award (to I.M.S.), U of M Brainstorm award (to I.M.S. and B.R.W.) and NIH R03-AI144840 (to B.R.W. and B.S.M.) provided financial support. M.R.R. is supported by National Institutes of Health (NIH) T32 AI 007313 and the U of M Dennis Watson Fellowship. E.J.S. is supported by NIH T35 AI118620 and the AOA Carolyn L. Kuckein Student Research Fellowship. A.L.B. is supported by a computational training award from the American Association of Immunologists. I.M.S. is supported by NIH R01 CA249393, R01 CA255039, NIH P01 CA254849, DOD W81XWH2110525, AACR Pancreatic Cancer Action Network Career Development Award (17-20-25-STRO), an AACR Pancreatic Cancer Action Network Catalyst Award (19-35-STRO), an American Cancer Society RSG RSG-21-102-01-IBC, and pilot awards from the Masonic Cancer Center and Cancer Research Training Initiative (University of Minnesota Medical School). 406-414 Funding Information: We thank Kris Hogquist and Maude Ashby for helpful discussions on thymocyte development. We thank Sathi Wijeyesinghe for the providing the P14 TCR DNA sequence. We thank Andrew Soerens, Ph.D. for assistance in generation of the Msln406-414 monomer. We thank Zoe Schmiechen for providing expertise for ViSNE analysis and Iris Wang and Bryan Sanchez for assistance with animal husbandry. We acknowledge the University of Minnesota Mouse Genetics Laboratory, Flow Cytometry Core, Research Animal Resource (RAR), and the Center for Immunology (CFI) imaging core. A CFI New Mouse Award (to I.M.S.), U of M Brainstorm award (to I.M.S. and B.R.W.) and NIH R03-AI144840 (to B.R.W. and B.S.M.) provided financial support. M.R.R. is supported by National Institutes of Health (NIH) T32 AI 007313 and the U of M Dennis Watson Fellowship. E.J.S. is supported by NIH T35 AI118620 and the AOA Carolyn L. Kuckein Student Research Fellowship. A.L.B. is supported by a computational training award from the American Association of Immunologists. I.M.S. is supported by NIH R01 CA249393, R01 CA255039, NIH P01 CA254849, DOD W81XWH2110525, AACR Pancreatic Cancer Action Network Career Development Award (17-20-25-STRO), an AACR Pancreatic Cancer Action Network Catalyst Award (19-35-STRO), an American Cancer Society RSG RSG-21-102-01-IBC, and pilot awards from the Masonic Cancer Center and Cancer Research Training Initiative (University of Minnesota Medical School). Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = dec,

doi = "10.1038/s41467-023-36180-1",

language = "English (US)",

volume = "14",

journal = "Nature communications",

issn = "2041-1723",

publisher = "Nature Research",

number = "1",

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TY - JOUR

T1 - Germline T cell receptor exchange results in physiological T cell development and function

AU - Rollins, Meagan R

AU - Raynor, Jackson

AU - Miller, Ebony A

AU - Butler, Jonah Z.

AU - Spartz, Ellen J.

AU - Lahr, Walker S

AU - You, Yun

AU - Burrack, Adam L.

AU - Moriarity, Branden S.

AU - Webber, Beau R.

AU - Stromnes, Ingunn M.

N1 - Funding Information: We thank Kris Hogquist and Maude Ashby for helpful discussions on thymocyte development. We thank Sathi Wijeyesinghe for the providing the P14 TCR DNA sequence. We thank Andrew Soerens, Ph.D. for assistance in generation of the Msln monomer. We thank Zoe Schmiechen for providing expertise for ViSNE analysis and Iris Wang and Bryan Sanchez for assistance with animal husbandry. We acknowledge the University of Minnesota Mouse Genetics Laboratory, Flow Cytometry Core, Research Animal Resource (RAR), and the Center for Immunology (CFI) imaging core. A CFI New Mouse Award (to I.M.S.), U of M Brainstorm award (to I.M.S. and B.R.W.) and NIH R03-AI144840 (to B.R.W. and B.S.M.) provided financial support. M.R.R. is supported by National Institutes of Health (NIH) T32 AI 007313 and the U of M Dennis Watson Fellowship. E.J.S. is supported by NIH T35 AI118620 and the AOA Carolyn L. Kuckein Student Research Fellowship. A.L.B. is supported by a computational training award from the American Association of Immunologists. I.M.S. is supported by NIH R01 CA249393, R01 CA255039, NIH P01 CA254849, DOD W81XWH2110525, AACR Pancreatic Cancer Action Network Career Development Award (17-20-25-STRO), an AACR Pancreatic Cancer Action Network Catalyst Award (19-35-STRO), an American Cancer Society RSG RSG-21-102-01-IBC, and pilot awards from the Masonic Cancer Center and Cancer Research Training Initiative (University of Minnesota Medical School). 406-414 Funding Information: We thank Kris Hogquist and Maude Ashby for helpful discussions on thymocyte development. We thank Sathi Wijeyesinghe for the providing the P14 TCR DNA sequence. We thank Andrew Soerens, Ph.D. for assistance in generation of the Msln406-414 monomer. We thank Zoe Schmiechen for providing expertise for ViSNE analysis and Iris Wang and Bryan Sanchez for assistance with animal husbandry. We acknowledge the University of Minnesota Mouse Genetics Laboratory, Flow Cytometry Core, Research Animal Resource (RAR), and the Center for Immunology (CFI) imaging core. A CFI New Mouse Award (to I.M.S.), U of M Brainstorm award (to I.M.S. and B.R.W.) and NIH R03-AI144840 (to B.R.W. and B.S.M.) provided financial support. M.R.R. is supported by National Institutes of Health (NIH) T32 AI 007313 and the U of M Dennis Watson Fellowship. E.J.S. is supported by NIH T35 AI118620 and the AOA Carolyn L. Kuckein Student Research Fellowship. A.L.B. is supported by a computational training award from the American Association of Immunologists. I.M.S. is supported by NIH R01 CA249393, R01 CA255039, NIH P01 CA254849, DOD W81XWH2110525, AACR Pancreatic Cancer Action Network Career Development Award (17-20-25-STRO), an AACR Pancreatic Cancer Action Network Catalyst Award (19-35-STRO), an American Cancer Society RSG RSG-21-102-01-IBC, and pilot awards from the Masonic Cancer Center and Cancer Research Training Initiative (University of Minnesota Medical School). Publisher Copyright: © 2023, The Author(s).

PY - 2023/12

Y1 - 2023/12

N2 - T cell receptor (TCR) transgenic mice represent an invaluable tool to study antigen-specific immune responses. In the pre-existing models, a monoclonal TCR is driven by a non-physiologic promoter and randomly integrated into the genome. Here, we create a highly efficient methodology to develop T cell receptor exchange (TRex) mice, in which TCRs, specific to the self/tumor antigen mesothelin (Msln), are integrated into the Trac locus, with concomitant Msln disruption to circumvent T cell tolerance. We show that high affinity TRex thymocytes undergo all sequential stages of maturation, express the exogenous TCR at DN4, require MHC class I for positive selection and undergo negative selection only when both Msln alleles are present. By comparison of TCRs with the same specificity but varying affinity, we show that Trac targeting improves functional sensitivity of a lower affinity TCR and confers resistance to T cell functional loss. By generating P14 TRex mice with the same specificity as the widely used LCMV-P14 TCR transgenic mouse, we demonstrate increased avidity of Trac-targeted TCRs over transgenic TCRs, while preserving physiologic T cell development. Together, our results support that the TRex methodology is an advanced tool to study physiological antigen-specific T cell behavior.

AB - T cell receptor (TCR) transgenic mice represent an invaluable tool to study antigen-specific immune responses. In the pre-existing models, a monoclonal TCR is driven by a non-physiologic promoter and randomly integrated into the genome. Here, we create a highly efficient methodology to develop T cell receptor exchange (TRex) mice, in which TCRs, specific to the self/tumor antigen mesothelin (Msln), are integrated into the Trac locus, with concomitant Msln disruption to circumvent T cell tolerance. We show that high affinity TRex thymocytes undergo all sequential stages of maturation, express the exogenous TCR at DN4, require MHC class I for positive selection and undergo negative selection only when both Msln alleles are present. By comparison of TCRs with the same specificity but varying affinity, we show that Trac targeting improves functional sensitivity of a lower affinity TCR and confers resistance to T cell functional loss. By generating P14 TRex mice with the same specificity as the widely used LCMV-P14 TCR transgenic mouse, we demonstrate increased avidity of Trac-targeted TCRs over transgenic TCRs, while preserving physiologic T cell development. Together, our results support that the TRex methodology is an advanced tool to study physiological antigen-specific T cell behavior.

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Germline T cell receptor exchange results in physiological T cell development and function

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