Mouse mammary epithelial cells possess a remarkable ability to regenerate the entire mammary gland through precisely regulated differentiation, involving complex molecular, morphological, and functional changes. Here, we performed comprehensive transcriptomic profiling of HC11 mouse mammary epithelial cells undergoing lactogenic differentiation using RNA sequencing and integrative bioinformatics. We identified 566 differentially expressed genes, reflecting extensive transcriptional reprogramming and activation of biosynthetic, metabolic, and secretory programs. Strong up-regulation of terminal and lactogenic differentiation markers, including Wap, Csn2, Lpl, Cd36, Lalba, Btn1a1, Xdh, Gata3, and Cebpb, signified maturation into a secretory phenotype. Functional evaluation via gene set enrichment analysis revealed transcriptional enrichment of mTOR, prolactin, insulin, ErbB, and autophagy-associated pathways, consistent with anabolic readiness and terminal differentiation. Conversely, p53, Wnt, and FoxO pathways were down-regulated, marking a transition from proliferation to differentiation. Transcription factors (FoxO1, Zbtb16, and Srebf1) and epigenetic regulators (Gadd45a and Hist1h1e) exhibited dynamic changes, underscoring coordinated transcriptional and chromatin remodeling. Gene set enrichment and protein-protein interaction analyses identified 10 hub genes, Agt, Ccnd1, Igf1, Mki67, Myc, Calm4, Rasgrp1, Cd69, Il6, and Pecam1, as central drivers of differentiation. Clustering of uniquely regulated genes further implicated roles in milk synthesis, protease activity, and lineage stabilization. Together, these findings define a transcriptional framework for lactogenic differentiation in the HC11 cell line model and provide a basis for future mechanistic studies.
Copyright © 2026 Waqar Ahmad et al.