A single-cell atlas of the myometrium in human parturition
Roger Pique-Regi, Roberto Romero, Valeria Garcia-Flores, Azam Peyvandipour, Adi L. Tarca, Errile Pusod, Jose Galaz, Derek Miller, Gaurav Bhatti, Robert Para, Tomi Kanninen, Ola Hadaya, Carmen Paredes, Kenichiro Motomura, Jeffrey R. Johnson, Eunjung Jung, Chaur-Dong Hsu, Stanley M. Berry, Nardhy Gomez-Lopez
Roger Pique-Regi, Roberto Romero, Valeria Garcia-Flores, Azam Peyvandipour, Adi L. Tarca, Errile Pusod, Jose Galaz, Derek Miller, Gaurav Bhatti, Robert Para, Tomi Kanninen, Ola Hadaya, Carmen Paredes, Kenichiro Motomura, Jeffrey R. Johnson, Eunjung Jung, Chaur-Dong Hsu, Stanley M. Berry, Nardhy Gomez-Lopez
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Research Article Cell biology Reproductive biology

A single-cell atlas of the myometrium in human parturition

Abstract

Parturition is a well-orchestrated process characterized by increased uterine contractility, cervical ripening, and activation of the chorioamniotic membranes; yet, the transition from a quiescent to a contractile myometrium heralds the onset of labor. However, the cellular underpinnings of human parturition in the uterine tissues are still poorly understood. Herein, we performed a comprehensive study of the human myometrium during spontaneous term labor using single-cell RNA sequencing (scRNA-Seq). First, we established a single-cell atlas of the human myometrium and unraveled the cell type–specific transcriptomic activity modulated during labor. Major cell types included distinct subsets of smooth muscle cells, monocytes/macrophages, stromal cells, and endothelial cells, all of which communicated and participated in immune (e.g., inflammation) and nonimmune (e.g., contraction) processes associated with labor. Furthermore, integrating scRNA-Seq and microarray data with deconvolution of bulk gene expression highlighted the contribution of smooth muscle cells to labor-associated contractility and inflammatory processes. Last, myometrium-derived single-cell signatures can be quantified in the maternal whole-blood transcriptome throughout pregnancy and are enriched in women in labor, providing a potential means of noninvasively monitoring pregnancy and its complications. Together, our findings provide insights into the contributions of specific myometrial cell types to the biological processes that take place during term parturition.

Authors

Roger Pique-Regi, Roberto Romero, Valeria Garcia-Flores, Azam Peyvandipour, Adi L. Tarca, Errile Pusod, Jose Galaz, Derek Miller, Gaurav Bhatti, Robert Para, Tomi Kanninen, Ola Hadaya, Carmen Paredes, Kenichiro Motomura, Jeffrey R. Johnson, Eunjung Jung, Chaur-Dong Hsu, Stanley M. Berry, Nardhy Gomez-Lopez

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Figure 2

SMC population of the human myometrium.

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SMC population of the human myometrium. (A) Diagram illustrating the his...
(A) Diagram illustrating the histological identification of the smooth muscle cell (SMC) population among myometrial cells before and after tissue dissociation (n = 24) for scRNA-Seq experiments. (B) Representative images from various sections of myometrial tissues showing (top) H&E staining, where the cell nuclei and cytoplasm are stained purple and pink, respectively; (middle) 3,3′-diaminobenzidine (DAB) immunohistochemistry staining for smooth muscle actin (brown); and (bottom) Masson’s trichrome staining showing collagen (blue) and muscle fibers (red). Scale bars at 100× original magnification: 100 μm. (C) Representative images of cells obtained after myometrial tissue dissociation stained using (top) H&E and (bottom) DAB immunohistochemistry staining for smooth muscle actin (brown). Scale bars at 200× original magnification: 50 μm. (D) Microscopic visualization of Gel Bead-in-Emulsion (GEM) successfully encapsulating single cells with SMC-like morphology that are within (left) and above (right) the 10x Genomics recommended size threshold. Scale bars at 200× original magnification: 50 μm. (E) Diagram illustrating a SMC above the 10x Genomics recommended size threshold that cannot be successfully encapsulated within the GEM.