NKG2D blockade impairs tissue-resident memory T cell accumulation and reduces chronic lung allograft dysfunction
Kaveh Moghbeli, Madeline A. Lipp, Marta Bueno, Andrew Craig, Michelle Rojas, Minahal Abbas, Zachary I. Lakkis, Byron Chuan, John Sembrat, Kentaro Noda, Daniel J. Kass, Kong Chen, Li Fan, Tim Oury, Zihe Zhou, Xingan Wang, John F. McDyer, Oliver Eickelberg, Mark E. Snyder
Kaveh Moghbeli, Madeline A. Lipp, Marta Bueno, Andrew Craig, Michelle Rojas, Minahal Abbas, Zachary I. Lakkis, Byron Chuan, John Sembrat, Kentaro Noda, Daniel J. Kass, Kong Chen, Li Fan, Tim Oury, Zihe Zhou, Xingan Wang, John F. McDyer, Oliver Eickelberg, Mark E. Snyder
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Research Article Immunology Transplantation

NKG2D blockade impairs tissue-resident memory T cell accumulation and reduces chronic lung allograft dysfunction

Abstract

Chronic lung allograft dysfunction (CLAD) substantially limits long-term survival following lung transplantation. To identify potential targets for CLAD prevention, T cells from explanted CLAD lungs and lung-draining lymph nodes, as well as diseased and nondiseased controls were isolated and single-cell RNA sequencing and TCR sequencing were performed. TCR sequencing revealed a clonally expanded population of CD8+ tissue-resident memory T cells (TRMs) with high cytotoxic potential, including upregulation of KLRK1, encoding the co-receptor NKG2D. These cytotoxic CD8+ TRMs accumulated around the CLAD airways and had a 100-fold increase in clonal overlap with lung-draining lymph nodes when compared with non-CLAD lungs. Using a murine model of orthotopic lung transplantation, we confirmed that cytotoxic CD8+ TRM accumulation was due to chronic rejection and not transplantation alone. Furthermore, blocking NKG2D in vivo attenuated the airway remodeling following transplantation and diminished airway accumulation of CD8+ T cells. Our findings support NKG2D as a potential therapeutic target for CLAD, affecting cytotoxic CD8+ TRM accumulation.

Authors

Kaveh Moghbeli, Madeline A. Lipp, Marta Bueno, Andrew Craig, Michelle Rojas, Minahal Abbas, Zachary I. Lakkis, Byron Chuan, John Sembrat, Kentaro Noda, Daniel J. Kass, Kong Chen, Li Fan, Tim Oury, Zihe Zhou, Xingan Wang, John F. McDyer, Oliver Eickelberg, Mark E. Snyder

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Figure 2

CLAD lungs and HLNs contain increased clusters of CD8+ T cells.

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CLAD lungs and HLNs contain increased clusters of CD8+ T cells. (A) Repr...
(A) Representative immunofluorescence images of lungs from CLAD (top row) and control (bottom row). Scale bars: 250 μm (6 left images) and 50 μm (4 right images). (B and C) Normalized CD8+ (B) and CD4+ (C) T cell counts per 500 mm2 in lung CLAD and control samples; dotted line represents threshold of 180 cells per mm2 of lung. (D) Normalized CD8+ (top) and CD4+ (bottom) T cell counts per 500 mm2 in HLN CLAD and control samples. (D) Representative HLN immunofluorescence images from CLAD (top row) and 1 control (bottom row). Scale bars: 250 μm (8 left images) and 50 μm (2 right images). (E and F) Normalized CD8+ (E) and CD4+ (F) T cell counts per 500 mm2 in HLN CLAD and control samples; dotted line represents threshold of 500 cells per mm2.