An integrated single-cell reference atlas of the human endometrium

Magda Marečková(Wellcome Sanger Institute), Luz García‐Alonso(Wellcome Sanger Institute), Marie Moullet(Wellcome Sanger Institute), Valentina Lorenzi(European Bioinformatics Institute), Robert Petryszak(Wellcome Sanger Institute), Carmen Sancho‐Serra(Wellcome Sanger Institute), Ágnes Oszlánczi(Wellcome Sanger Institute), Cecilia Mazzeo(Wellcome Sanger Institute), Frederick C.K. Wong(Wellcome Sanger Institute), Iva Kelava(Wellcome Sanger Institute), Sophie Hoffman(Wellcome Sanger Institute), Michał Krassowski(Centre for Human Genetics), Kurtis Garbutt(University of Oxford), Kezia Gaitskell(John Radcliffe Hospital), Slaveya Yancheva(John Radcliffe Hospital), Ee Von Woon(Chelsea and Westminster Hospital), Victoria Male(Imperial College London), Ingrid Granne(University of Oxford), Karin Hellner(University of Oxford), Krishnaa T. Mahbubani(University of Cambridge), Kourosh Saeb‐Parsy(University of Cambridge), Mohammad Lotfollahi(Wellcome/MRC Cambridge Stem Cell Institute), Elena Prigmore(Wellcome Sanger Institute), Jennifer H. Southcombe(University of Oxford), Rebecca Dragovic(University of Oxford), Christian M. Becker(University of Oxford), Krina T. Zondervan(Centre for Human Genetics), Roser Vento‐Tormo(Wellcome Sanger Institute)
Nature Genetics
August 28, 2024
10.1038/s41588-024-01873-w
Cited by 140Open Access
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Abstract

The complex and dynamic cellular composition of the human endometrium remains poorly understood. Previous endometrial single-cell atlases profiled few donors and lacked consensus in defining cell types. We introduce the Human Endometrial Cell Atlas (HECA), a high-resolution single-cell reference atlas (313,527 cells) combining published and new endometrial single-cell transcriptomics datasets of 63 women with and without endometriosis. HECA assigns consensus and identifies previously unreported cell types, mapped in situ using spatial transcriptomics and validated using a new independent single-nuclei dataset (312,246 nuclei, 63 donors). In the functionalis, we identify intricate stromal-epithelial cell coordination via transforming growth factor beta (TGFβ) signaling. In the basalis, we define signaling between fibroblasts and an epithelial population expressing progenitor markers. Integration of HECA with large-scale endometriosis genome-wide association study data pinpoints decidualized stromal cells and macrophages as most likely dysregulated in endometriosis. The HECA is a valuable resource for studying endometrial physiology and disorders, and for guiding microphysiological in vitro systems development.

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