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HOXA10-TWIST2 antagonism drives partial epithelial-to-mesenchymal transition for embryo implantation

Nancy Ashary, Sanjana Suresh, Anshul Bhide, S. Shyamal, N Pranya, S Patil, Anuradha Mishra, A Anuradha, Shruti R. Hansda, Harshavardhan BV, Mohit Kumar Jolly, Deepak Modi

2025Cell Death Discovery10 citationsDOIOpen Access PDF

Abstract

In mammalian reproduction, a significant proportion of embryos fail to implant despite a receptive uterus, suggesting that defects in epithelial remodeling at the embryo-uterine interface contribute to implantation failure. The molecular programs enabling such remodeling remain incompletely understood. Here, we identify a conserved transcriptional circuit involving HOXA10 and TWIST2 that regulates epithelial plasticity in the endometrium via partial epithelial-to-mesenchymal transition (pEMT). HOXA10, a transcription factor essential for uterine receptivity, is specifically downregulated in the luminal epithelium at implantation in mice, hamsters, and monkeys. Integrated CUT&RUN and transcriptomic profiling in human endometrial epithelial cells reveal that HOXA10 directly activates epithelial gene networks and represses mesenchymal programs. HOXA10 loss, both in vitro and in vivo, induces a pEMT state with increased cell motility. Mechanistically, HOXA10 represses TWIST2, a core EMT regulator; its derepression promotes mesenchymal gene expression and epithelial cell migration. TWIST2 knockdown restores epithelial identity and impairs implantation. These findings establish a mutually antagonistic HOXA10-TWIST2 circuit as a key regulator of pEMT and epithelial remodeling during implantation.

Topics & Concepts

Cell biologyEpithelial–mesenchymal transitionGene knockdownBiologyTranscription factorTranscriptomeRegulatorEmbryoDecidualizationEpitheliumDerepressionNotch signaling pathwayMesenchymal stem cellRegulation of gene expressionGerm layerStem cellTranscriptional regulationInner cell massCell fate determinationMesodermGene expression profilingChemistryEpigeneticsSignal transductionCellEmbryonic stem cellGene expressionDeciduaDownregulation and upregulationReproductive System and PregnancyGynecological conditions and treatmentsEndometriosis Research and Treatment