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 3

Fetoplacental Ags are relayed to maternal immune cells via sEVs.

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Fetoplacental Ags are relayed to maternal immune cells via sEVs. (A) Mic...
(A) Microscopy of expression of mOVA on cryosections of placentas of BALB/c females impregnated with mOVA B6 males. Dotted line: limit between the junctional zone and the labyrinth. Representative of 6–8 placentas from 3 pregnant females. Original magnification, ×200. (B) Detection of mOVA by IEM on sections of placentas of BALB/c females mated with mOVA B6 males. Asterisk, cell membrane invaginations in trophoblast cells. Original magnification, ×20,000, ×80,000. TC, trophoblast cell; MBS, maternal blood space; Desm, desmosome. (C) Detection by microscopy of mOVA on cryosections of spleens of BALB/c females impregnated with heterozygous mOVA B6 males. Representative of spleens from 4 pregnant mice per time point. Original magnification, ×200. (D) IEM of OVA Ag (6 nm gold) on sEVs captured by an FDC identified by expression of CD21/35 (10 nm gold, red circles) in the spleen of a BALB/c female mated with an mOVA B6 male and analyzed on E17.5. Fetoplacental sEVs expressing OVA in the endocytic compartment (pseudocolored) of the FDC. ROIs: detail of OVA Ag (6 nm gold, arrows) on fetoplacental sEVs internalized by the FDC. Original magnification, ×20,000, ×80,000. N, nucleus. (E) IEM of fetoplacental sEVs bearing paternal mOVA (6 nm gold, arrow) within interconnected vesicles of MZ CD169+ macrophages (20 nm gold, red circle) in the spleen of a BALB/c female mated with a mOVA B6 male and analyzed on E17.5. Original magnification, ×20,000, ×80,000.