Fetoplacental extracellular vesicles deliver conceptus-derived antigens to maternal secondary lymphoid tissues for immune recognition
Juliana S. Powell, Adriana T. Larregina, William J. Shufesky, Mara L.G. Sullivan, Donna Beer Stolz, Stephen J. Gould, Geoffrey Camirand, Sergio D. Catz, Simon C. Watkins, Yoel Sadovsky, Adrian E. Morelli
Juliana S. Powell, Adriana T. Larregina, William J. Shufesky, Mara L.G. Sullivan, Donna Beer Stolz, Stephen J. Gould, Geoffrey Camirand, Sergio D. Catz, Simon C. Watkins, Yoel Sadovsky, Adrian E. Morelli
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Research Article Immunology Reproductive biology

Fetoplacental extracellular vesicles deliver conceptus-derived antigens to maternal secondary lymphoid tissues for immune recognition

Abstract

Pregnancy is an immunological paradox where despite a competent maternal immune system, regulatory mechanisms at the fetoplacental interface and maternal secondary lymphoid tissues (SLTs) circumvent rejection of semi-allogeneic concepti. Small extracellular vesicles (sEVs) are a vehicle for intercellular communication; nevertheless, the role of fetoplacental sEVs in transport of antigens to maternal SLTs has not been conclusively demonstrated. Using mice in which the conceptus generates fluoroprobe-tagged sEVs shed by the plasma membrane or released from the endocytic compartment, we show that fetoplacental sEVs are delivered to immune cells in the maternal spleen. Injection of sEVs from placentas of females impregnated with Act-mOVA B6 males elicited suboptimal activation of OVA-specific CD8+ OT-I T cells in virgin females as occurs during pregnancy. Furthermore, when OVA+ concepti were deficient in Rab27a, a protein required for sEV secretion, OT-I cell proliferation in the maternal spleen was decreased. Proteomics analysis revealed that mouse trophoblast sEVs were enriched in antiinflammatory and immunosuppressive mediators. Translational relevance was tested in humanized mice injected using sEVs from cultures of human trophoblasts. Our findings show that sEVs deliver fetoplacental antigens to the mother’s SLTs that are recognized by maternal T cells. Alterations of such a mechanism may lead to pregnancy disorders.

Authors

Juliana S. Powell, Adriana T. Larregina, William J. Shufesky, Mara L.G. Sullivan, Donna Beer Stolz, Stephen J. Gould, Geoffrey Camirand, Sergio D. Catz, Simon C. Watkins, Yoel Sadovsky, Adrian E. Morelli

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Figure 10

Human trophoblast sEVs are captured by human immune cells in vivo.

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Human trophoblast sEVs are captured by human immune cells in vivo. (A) D...
(A) Diagram depicting the generation of PHT cultures and purification of sEVs from PHT culture supernatants. The CM-DiI–labeled PHT-derived sEVs were i.v. injected in huMice, and the traffic of the injected EVs to spleen, bone marrow, liver, lung, and thymus was analyzed 18 hours later. (B) Percentages of human leukocyte chimerism in huMice analyzed in the spleen by flow cytometry at the endpoint of the experiments (14–16 weeks after injection of human CD34 hematopoietic stem cells). Each dot represents 1 huMouse. (C) Detection by fluorescence microscopy in human macrophages of spleen, liver, and bone marrow of CM-DiI (red) PHT sEVs injected i.v. in huMice. Representative of 6 huMice. Original magnification, ×200. (D) Representative ImageStream images of human B cells, cDC2s, and cDC1s carrying CM-DiI PHT sEVs, likely as sEV clusters detectable by the ImageStream analyzer. Original magnification, ×60, out of 20,000 cells analyzed per huMouse spleen. ImageStream analysis was done 18 hours after i.v. injection of the sEVs. (E) Pooled data from the ImageStream analysis shown in D with percentages of human T cells, B cells, and cDCs with CM-DiI content in splenocytes of huMice untreated or i.v. injected with CM-DiI PHT sEVs. Each dot represents 1 huMouse. In E, comparisons by 2-tailed Student’s test. Error bars: means ± SD. *P < 0.05, **P < 0.01.