Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation

Sneha Sant; Misty R. Jenkins; Pradyot Dash; Katherine A. Watson; Zhongfang Wang; Angela Pizzolla; Marios Koutsakos; Thi H.O. Nguyen; Martha Lappas; Jane Crowe; Tom Loudovaris; Stuart I. Mannering; Glen P. Westall; Tom C. Kotsimbos; Allen C. Cheng; Linda Wakim; Peter C. Doherty; Paul G. Thomas; Liyen Loh; Katherine Kedzierska

doi:10.1002/cti2.1079

Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation

Sneha Sant, Misty R. Jenkins, Pradyot Dash, Katherine A. Watson, Zhongfang Wang, Angela Pizzolla, Marios Koutsakos, Thi H.O. Nguyen, Martha Lappas, Jane Crowe, Tom Loudovaris, Stuart I. Mannering, Glen P. Westall, Tom C. Kotsimbos, Allen C. Cheng, Linda Wakim, Peter C. Doherty, Paul G. Thomas, Liyen Loh, Katherine Kedzierska

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

21 Scopus citations

Abstract

Background: Although γδ T cells comprise up to 10% of human peripheral blood T cells, questions remain regarding their role in disease states and T-cell receptor (TCR) clonal expansions. We dissected anti-viral functions of human γδ T cells towards influenza viruses and defined influenza-reactive γδ TCRs in the context of γδ-TCRs across the human lifespan. Methods: We performed ⁵¹Cr-killing assay and single-cell time-lapse live video microscopy to define mechanisms underlying γδ T-cell-mediated killing of influenza-infected targets. We assessed cytotoxic profiles of γδ T cells in influenza-infected patients and IFN-γ production towards influenza-infected lung epithelial cells. Using single-cell RT-PCR, we characterised paired TCRγδ clonotypes for influenza-reactive γδ T cells in comparison with TCRs from healthy neonates, adults, elderly donors and tissues. Results: We provide the first visual evidence of γδ T-cell-mediated killing of influenza-infected targets and show distinct features to those reported for CD8⁺ T cells. γδ T cells displayed poly-cytotoxic profiles in influenza-infected patients and produced IFN-γ towards influenza-infected cells. These IFN-γ-producing γδ T cells were skewed towards the γ9δ2 TCRs, particularly expressing the public GV9-TCRγ, capable of pairing with numerous TCR-δ chains, suggesting their significant role in γδ T-cell immunity. Neonatal γδ T cells displayed extensive non-overlapping TCRγδ repertoires, while adults had enriched γ9δ2-pairings with diverse CDR3γδ regions. Conversely, the elderly showed distinct γδ-pairings characterised by large clonal expansions, a profile also prominent in adult tissues. Conclusion: Human TCRγδ repertoire is shaped by age, tissue compartmentalisation and the individual's history of infection, suggesting that these somewhat enigmatic γδ T cells indeed respond to antigen challenge.

Original language	English (US)
Article number	e1079
Journal	Clinical and Translational Immunology
Volume	8
Issue number	9
DOIs	https://doi.org/10.1002/cti2.1079
State	Published - Jan 2019
Externally published	Yes

Keywords

human tissues
human γδ T cells
influenza virus infection
paired TCRγδ repertoire
public GV9-TCRγ clonotype

ASJC Scopus subject areas

Nursing(all)
Immunology and Allergy
Immunology

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10.1002/cti2.1079

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Sant, S., Jenkins, M. R., Dash, P., Watson, K. A., Wang, Z., Pizzolla, A., Koutsakos, M., Nguyen, T. H. O., Lappas, M., Crowe, J., Loudovaris, T., Mannering, S. I., Westall, G. P., Kotsimbos, T. C., Cheng, A. C., Wakim, L., Doherty, P. C., Thomas, P. G., Loh, L., & Kedzierska, K. (2019). Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation. Clinical and Translational Immunology, 8(9), [e1079]. https://doi.org/10.1002/cti2.1079

Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation. / Sant, Sneha; Jenkins, Misty R.; Dash, Pradyot; Watson, Katherine A.; Wang, Zhongfang; Pizzolla, Angela; Koutsakos, Marios; Nguyen, Thi H.O.; Lappas, Martha; Crowe, Jane; Loudovaris, Tom; Mannering, Stuart I.; Westall, Glen P.; Kotsimbos, Tom C.; Cheng, Allen C.; Wakim, Linda; Doherty, Peter C.; Thomas, Paul G.; Loh, Liyen; Kedzierska, Katherine.

In: Clinical and Translational Immunology, Vol. 8, No. 9, e1079, 01.2019.

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

Sant, S, Jenkins, MR, Dash, P, Watson, KA, Wang, Z, Pizzolla, A, Koutsakos, M, Nguyen, THO, Lappas, M, Crowe, J, Loudovaris, T, Mannering, SI, Westall, GP, Kotsimbos, TC, Cheng, AC, Wakim, L, Doherty, PC, Thomas, PG, Loh, L & Kedzierska, K 2019, 'Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation', Clinical and Translational Immunology, vol. 8, no. 9, e1079. https://doi.org/10.1002/cti2.1079

Sant, Sneha ; Jenkins, Misty R. ; Dash, Pradyot ; Watson, Katherine A. ; Wang, Zhongfang ; Pizzolla, Angela ; Koutsakos, Marios ; Nguyen, Thi H.O. ; Lappas, Martha ; Crowe, Jane ; Loudovaris, Tom ; Mannering, Stuart I. ; Westall, Glen P. ; Kotsimbos, Tom C. ; Cheng, Allen C. ; Wakim, Linda ; Doherty, Peter C. ; Thomas, Paul G. ; Loh, Liyen ; Kedzierska, Katherine. / Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation. In: Clinical and Translational Immunology. 2019 ; Vol. 8, No. 9.

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title = "Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation",

abstract = "Background: Although γδ T cells comprise up to 10% of human peripheral blood T cells, questions remain regarding their role in disease states and T-cell receptor (TCR) clonal expansions. We dissected anti-viral functions of human γδ T cells towards influenza viruses and defined influenza-reactive γδ TCRs in the context of γδ-TCRs across the human lifespan. Methods: We performed 51Cr-killing assay and single-cell time-lapse live video microscopy to define mechanisms underlying γδ T-cell-mediated killing of influenza-infected targets. We assessed cytotoxic profiles of γδ T cells in influenza-infected patients and IFN-γ production towards influenza-infected lung epithelial cells. Using single-cell RT-PCR, we characterised paired TCRγδ clonotypes for influenza-reactive γδ T cells in comparison with TCRs from healthy neonates, adults, elderly donors and tissues. Results: We provide the first visual evidence of γδ T-cell-mediated killing of influenza-infected targets and show distinct features to those reported for CD8+ T cells. γδ T cells displayed poly-cytotoxic profiles in influenza-infected patients and produced IFN-γ towards influenza-infected cells. These IFN-γ-producing γδ T cells were skewed towards the γ9δ2 TCRs, particularly expressing the public GV9-TCRγ, capable of pairing with numerous TCR-δ chains, suggesting their significant role in γδ T-cell immunity. Neonatal γδ T cells displayed extensive non-overlapping TCRγδ repertoires, while adults had enriched γ9δ2-pairings with diverse CDR3γδ regions. Conversely, the elderly showed distinct γδ-pairings characterised by large clonal expansions, a profile also prominent in adult tissues. Conclusion: Human TCRγδ repertoire is shaped by age, tissue compartmentalisation and the individual's history of infection, suggesting that these somewhat enigmatic γδ T cells indeed respond to antigen challenge.",

keywords = "human tissues, human γδ T cells, influenza virus infection, paired TCRγδ repertoire, public GV9-TCRγ clonotype",

author = "Sneha Sant and Jenkins, {Misty R.} and Pradyot Dash and Watson, {Katherine A.} and Zhongfang Wang and Angela Pizzolla and Marios Koutsakos and Nguyen, {Thi H.O.} and Martha Lappas and Jane Crowe and Tom Loudovaris and Mannering, {Stuart I.} and Westall, {Glen P.} and Kotsimbos, {Tom C.} and Cheng, {Allen C.} and Linda Wakim and Doherty, {Peter C.} and Thomas, {Paul G.} and Liyen Loh and Katherine Kedzierska",

note = "Funding Information: We thank ImmunoID facility for FACS sorting and Ms S Gonzalez for technical assistance. The clinical research midwives G Christophers, G Pell, and R Murdoch for sample collection; and the Obstetrics and Midwifery staff of the Mercy Hospital for Women for their co‐operation. The Australian National Health and Medical Research Council (NHMRC) NHMRC Program Grant (1071916) to KK supported this work. ML is supported by a Research Fellowship from the Department of Obstetrics and Gynaecology (University of Melbourne) and a Faculty Fellowship from the University of Melbourne. SS was a recipient Victoria India Doctoral Scholarship and Melbourne International Fee Remission Scholarship, University of Melbourne. MK is a recipient of Melbourne International Research Scholarship and Melbourne International Fee Remission Scholarship. MRJ is a NHMRC CDA Research Fellow. KK is a NHMRC Senior Research Level B Fellow (#1102792). Funding Information: We thank ImmunoID facility for FACS sorting and Ms S Gonzalez for technical assistance. The clinical research midwives G Christophers, G Pell, and R Murdoch for sample collection; and the Obstetrics and Midwifery staff of the Mercy Hospital for Women for their co-operation. The Australian National Health and Medical Research Council (NHMRC) NHMRC Program Grant (1071916) to KK supported this work. ML is supported by a Research Fellowship from the Department of Obstetrics and Gynaecology (University of Melbourne) and a Faculty Fellowship from the University of Melbourne. SS was a recipient Victoria India Doctoral Scholarship and Melbourne International Fee Remission Scholarship, University of Melbourne. MK is a recipient of Melbourne International Research Scholarship and Melbourne International Fee Remission Scholarship. MRJ is a NHMRC CDA Research Fellow. KK is a NHMRC Senior Research Level B Fellow (#1102792). Publisher Copyright: {\textcopyright} 2019 The Authors. Clinical & Translational Immunology published by John Wiley & Sons Australia, Ltd on behalf of Australian and New Zealand Society for Immunology Inc.",

year = "2019",

month = jan,

doi = "10.1002/cti2.1079",

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volume = "8",

journal = "Clinical and Translational Immunology",

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TY - JOUR

T1 - Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation

AU - Sant, Sneha

AU - Jenkins, Misty R.

AU - Dash, Pradyot

AU - Watson, Katherine A.

AU - Wang, Zhongfang

AU - Pizzolla, Angela

AU - Koutsakos, Marios

AU - Nguyen, Thi H.O.

AU - Lappas, Martha

AU - Crowe, Jane

AU - Loudovaris, Tom

AU - Mannering, Stuart I.

AU - Westall, Glen P.

AU - Kotsimbos, Tom C.

AU - Cheng, Allen C.

AU - Wakim, Linda

AU - Doherty, Peter C.

AU - Thomas, Paul G.

AU - Loh, Liyen

AU - Kedzierska, Katherine

N1 - Funding Information: We thank ImmunoID facility for FACS sorting and Ms S Gonzalez for technical assistance. The clinical research midwives G Christophers, G Pell, and R Murdoch for sample collection; and the Obstetrics and Midwifery staff of the Mercy Hospital for Women for their co‐operation. The Australian National Health and Medical Research Council (NHMRC) NHMRC Program Grant (1071916) to KK supported this work. ML is supported by a Research Fellowship from the Department of Obstetrics and Gynaecology (University of Melbourne) and a Faculty Fellowship from the University of Melbourne. SS was a recipient Victoria India Doctoral Scholarship and Melbourne International Fee Remission Scholarship, University of Melbourne. MK is a recipient of Melbourne International Research Scholarship and Melbourne International Fee Remission Scholarship. MRJ is a NHMRC CDA Research Fellow. KK is a NHMRC Senior Research Level B Fellow (#1102792). Funding Information: We thank ImmunoID facility for FACS sorting and Ms S Gonzalez for technical assistance. The clinical research midwives G Christophers, G Pell, and R Murdoch for sample collection; and the Obstetrics and Midwifery staff of the Mercy Hospital for Women for their co-operation. The Australian National Health and Medical Research Council (NHMRC) NHMRC Program Grant (1071916) to KK supported this work. ML is supported by a Research Fellowship from the Department of Obstetrics and Gynaecology (University of Melbourne) and a Faculty Fellowship from the University of Melbourne. SS was a recipient Victoria India Doctoral Scholarship and Melbourne International Fee Remission Scholarship, University of Melbourne. MK is a recipient of Melbourne International Research Scholarship and Melbourne International Fee Remission Scholarship. MRJ is a NHMRC CDA Research Fellow. KK is a NHMRC Senior Research Level B Fellow (#1102792). Publisher Copyright: © 2019 The Authors. Clinical & Translational Immunology published by John Wiley & Sons Australia, Ltd on behalf of Australian and New Zealand Society for Immunology Inc.

PY - 2019/1

Y1 - 2019/1

N2 - Background: Although γδ T cells comprise up to 10% of human peripheral blood T cells, questions remain regarding their role in disease states and T-cell receptor (TCR) clonal expansions. We dissected anti-viral functions of human γδ T cells towards influenza viruses and defined influenza-reactive γδ TCRs in the context of γδ-TCRs across the human lifespan. Methods: We performed 51Cr-killing assay and single-cell time-lapse live video microscopy to define mechanisms underlying γδ T-cell-mediated killing of influenza-infected targets. We assessed cytotoxic profiles of γδ T cells in influenza-infected patients and IFN-γ production towards influenza-infected lung epithelial cells. Using single-cell RT-PCR, we characterised paired TCRγδ clonotypes for influenza-reactive γδ T cells in comparison with TCRs from healthy neonates, adults, elderly donors and tissues. Results: We provide the first visual evidence of γδ T-cell-mediated killing of influenza-infected targets and show distinct features to those reported for CD8+ T cells. γδ T cells displayed poly-cytotoxic profiles in influenza-infected patients and produced IFN-γ towards influenza-infected cells. These IFN-γ-producing γδ T cells were skewed towards the γ9δ2 TCRs, particularly expressing the public GV9-TCRγ, capable of pairing with numerous TCR-δ chains, suggesting their significant role in γδ T-cell immunity. Neonatal γδ T cells displayed extensive non-overlapping TCRγδ repertoires, while adults had enriched γ9δ2-pairings with diverse CDR3γδ regions. Conversely, the elderly showed distinct γδ-pairings characterised by large clonal expansions, a profile also prominent in adult tissues. Conclusion: Human TCRγδ repertoire is shaped by age, tissue compartmentalisation and the individual's history of infection, suggesting that these somewhat enigmatic γδ T cells indeed respond to antigen challenge.

AB - Background: Although γδ T cells comprise up to 10% of human peripheral blood T cells, questions remain regarding their role in disease states and T-cell receptor (TCR) clonal expansions. We dissected anti-viral functions of human γδ T cells towards influenza viruses and defined influenza-reactive γδ TCRs in the context of γδ-TCRs across the human lifespan. Methods: We performed 51Cr-killing assay and single-cell time-lapse live video microscopy to define mechanisms underlying γδ T-cell-mediated killing of influenza-infected targets. We assessed cytotoxic profiles of γδ T cells in influenza-infected patients and IFN-γ production towards influenza-infected lung epithelial cells. Using single-cell RT-PCR, we characterised paired TCRγδ clonotypes for influenza-reactive γδ T cells in comparison with TCRs from healthy neonates, adults, elderly donors and tissues. Results: We provide the first visual evidence of γδ T-cell-mediated killing of influenza-infected targets and show distinct features to those reported for CD8+ T cells. γδ T cells displayed poly-cytotoxic profiles in influenza-infected patients and produced IFN-γ towards influenza-infected cells. These IFN-γ-producing γδ T cells were skewed towards the γ9δ2 TCRs, particularly expressing the public GV9-TCRγ, capable of pairing with numerous TCR-δ chains, suggesting their significant role in γδ T-cell immunity. Neonatal γδ T cells displayed extensive non-overlapping TCRγδ repertoires, while adults had enriched γ9δ2-pairings with diverse CDR3γδ regions. Conversely, the elderly showed distinct γδ-pairings characterised by large clonal expansions, a profile also prominent in adult tissues. Conclusion: Human TCRγδ repertoire is shaped by age, tissue compartmentalisation and the individual's history of infection, suggesting that these somewhat enigmatic γδ T cells indeed respond to antigen challenge.

KW - human tissues

KW - human γδ T cells

KW - influenza virus infection

KW - paired TCRγδ repertoire

KW - public GV9-TCRγ clonotype

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Human γδ T-cell receptor repertoire is shaped by influenza viruses, age and tissue compartmentalisation

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