Role of progesterone action in inguinal hernia formation via skeletal muscle fibrosis and atrophy
Tianming You, Mehrdad Zandigohar, Tanvi Potluri, Natalie Piehl, John S. Coon V, Elizabeth Baker, Maya Kafali, Yang Dai, Jonah J. Stulberg, David J. Escobar, Richard L. Lieber, Hong Zhao, Serdar E. Bulun
Tianming You, Mehrdad Zandigohar, Tanvi Potluri, Natalie Piehl, John S. Coon V, Elizabeth Baker, Maya Kafali, Yang Dai, Jonah J. Stulberg, David J. Escobar, Richard L. Lieber, Hong Zhao, Serdar E. Bulun
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Research Article Cell biology Endocrinology Muscle biology

Role of progesterone action in inguinal hernia formation via skeletal muscle fibrosis and atrophy

Abstract

More than 1 in 4 men will undergo surgery for inguinal hernia, which is commonly associated with fibrotic degeneration of the lower abdominal muscle (LAM) in the groin region. Utilizing a male mouse model expressing the human aromatase gene (Aromhum), previous studies showed that locally produced estradiol acting via estrogen receptor α in LAM fibroblasts leads to fibrosis, myofiber atrophy, and hernia development. Here, we found that upregulation of progesterone receptor (PGR) in a LAM fibroblast population mediates this estrogenic effect. A PGR-selective progesterone antagonist in Aromhum mice decreased LAM fibrosis and atrophy, preventing hernia formation and stopping progression of existing hernias. Addition of progesterone to estradiol treatment was essential for early-onset development of LAM fibrosis and large hernias in wild-type mice, which was averted by a progesterone antagonist. Single-nuclei multiomics sequencing of herniated LAM revealed a unique population of Pgr-expressing fibroblasts that promotes fibrosis and myofiber atrophy through TGF-β2 signaling. Multiomics findings were validated in vivo in herniated LAM tissues of both mice and adult men. Our findings suggest an important and rare pathologic role of progesterone signaling in males and provide evidence for progesterone antagonists as a nonsurgical alternative for inguinal hernia management.

Authors

Tianming You, Mehrdad Zandigohar, Tanvi Potluri, Natalie Piehl, John S. Coon V, Elizabeth Baker, Maya Kafali, Yang Dai, Jonah J. Stulberg, David J. Escobar, Richard L. Lieber, Hong Zhao, Serdar E. Bulun

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Figure 6

Pgr+ fibroblasts, Pgr fibroblasts, and mesothelial-like cells may contribute to atrophy of myofibers in EP LAM.

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Pgr+ fibroblasts, Pgr– fibroblasts, and mesothelial-like cells may cont...
(AC) Visualization of cell-cell communication using CellChat, comparing communication networks between Vehicle (Veh), E2 + P4 (EP), and E2 + P4 + RU486 (EPR) LAM. Circle plots visualizing networks with outgoing communication from (A) Pgr+ fibroblasts, (B) Pgr fibroblasts, and (C) mesothelial-like cells to type I/IIa/IIb myofibers. Interactions between pairs of cell types are depicted by a line connecting the 2 cell types, with line thickness indicating the strength of the interaction. (D) Signaling pathways enriched in Veh, EP, and EPR LAM within the communication network between non-myofibers (Pgr+ fibroblasts, Pgr fibroblasts, mesothelial-like cells) and type I/IIa/IIb myofibers. Black arrow emphasizes the TGF-β pathway. (E) Relative contribution of TGF-β pathway ligand-receptor pairs in Veh (red), EP (green), and EPR (blue) LAM. Upregulated Tgfb2-(Tgfbr1+Tgfbr2) interaction in EP LAM is highlighted (black arrow). (F) Xenium-based spatial transcriptomics of Veh, EP, and EPR LAM showing expression of Tgfbr2 and muscle atrophy markers (Fbxo32, Trim63) in type I (Myh7+; pink dashed circle) and type II myofibers (Myh2+, orange dashed circle). Upper row images show expression of cell-type marker genes, while lower row images show expression of Tgfbr2 and muscle atrophy marker genes (Fbxo32, Trim63). The software uses DAPI to determine the extent of the nucleus (light blue staining). Colored dots, each representing an individual mRNA transcript of a gene, are emphasized with similarly colored arrows. Scale bars: 20 μm. n = 3–4/group.