Donor dendritic cell–derived exosomes promote allograft-targeting immune response
Quan Liu, … , Adriana T. Larregina, Adrian E. Morelli
Quan Liu, … , Adriana T. Larregina, Adrian E. Morelli
Published June 27, 2016
Citation Information: J Clin Invest. 2016;126(8):2805-2820. https://doi.org/10.1172/JCI84577.
View: Text | PDF
Research Article

Donor dendritic cell–derived exosomes promote allograft-targeting immune response

Abstract

The immune response against transplanted allografts is one of the most potent reactions mounted by the immune system. The acute rejection response has been attributed to donor dendritic cells (DCs), which migrate to recipient lymphoid tissues and directly activate alloreactive T cells against donor MHC molecules. Here, using a murine heart transplant model, we determined that only a small number of donor DCs reach lymphoid tissues and investigated how this limited population of donor DCs efficiently initiates the alloreactive T cell response that causes acute rejection. In our mouse model, efficient passage of donor MHC molecules to recipient conventional DCs (cDCs) was dependent on the transfer of extracellular vesicles (EVs) from donor DCs that migrated from the graft to lymphoid tissues. These EVs shared characteristics with exosomes and were internalized or remained attached to the recipient cDCs. Recipient cDCs that acquired exosomes became activated and triggered full activation of alloreactive T cells. Depletion of recipient cDCs after cardiac transplantation drastically decreased presentation of donor MHC molecules to directly alloreactive T cells and delayed graft rejection in mice. These findings support a key role for transfer of donor EVs in the generation of allograft-targeting immune responses and suggest that interrupting this process has potential to dampen the immune response to allografts.

Authors

Quan Liu, Darling M. Rojas-Canales, Sherrie J. Divito, William J. Shufesky, Donna Beer Stolz, Geza Erdos, Mara L.G. Sullivan, Gregory A. Gibson, Simon C. Watkins, Adriana T. Larregina, Adrian E. Morelli

×

Figure 6

Recipient cDCs acquire clusters of donor-derived exosomes in vivo.

Options: View larger image (or click on image) Download as PowerPoint
Recipient cDCs acquire clusters of donor-derived exosomes in vivo. (A) T...
(A) Time-lapse analysis (confocal) of transfer of RFP-tagged exosome clusters from a migrating CD63-RFP BALB/c DC (blue nucleus + RFP-exosomes) to a lymph node cDC (YFP+, in green). Scale bar: 1 μm. (B) Side view of A. The arrow indicates internalized RFP-tagged EVs. (C) Left: 3D panoramic view (confocal) of a lymph node of a CD11c-YFP B6 mouse injected with CD63-RFP BALB/c DCs. Right: RFP-exosome clusters in relationship to host YFP+ cDCs, on the same image analyzed with Imaris X64. Red dots: RFP-exosomes on YFP+ B6 cDCs. Yellow dots: RFP-exosomes internalized by YFP+ B6 cDCs. Blue dots: RFP-exosomes in CD63-RFP BALB/c DCs, free or captured by YFP cells. (D) 3D view (multiphoton) of the spleen of a CD11c-YFP B6 mouse injected i.v. with CD63-RFP BALB/c DCs. Arrow: interaction between injected CD63-RFP BALB/c DCs and host YFP+ cDCs. Scale bar: 15 μm. (E) Analysis (Imaris X64) of transfer (arrows) of RFP-exosome clusters from a CD63-RFP BALB/c DC to host YFP+ cDCs (in green) in the spleen. In AE, results are representative of 4 independent experiments.