Smad4-p65 interactions drive BMP-mediated protection against inflammatory cell death [RNA-Seq]

Inflammation-induced osteoblast death undermines bone homeostasis and can aggravate bone-destructive diseases, yet how pro-survival BMP signaling intersects with inflammatory TNF–NF-?B signaling remains poorly defined. Here we show that BMP4 protects mouse osteoblasts from TNF-a–triggered apoptosis and cytotoxic death and that this cytoprotection requires both Smad4 and NF-?B p65. Integrative epigenomic profiling (ChIP-seq/ATAC-seq/RNA-seq) reveals extensive Smad4–p65 co-occupancy and identifies Samd9l as a prominent TNF-a–inducible gene that is selectively repressed by BMP4. Two Smad4/p65-bound distal elements physically contact the Samd9l promoter, exhibit TNF-responsive enhancer activity, and are required for Samd9l induction, as demonstrated by 4C-seq and CRISPR/dCas9-based chromatin closing/opening. Functionally, Samd9l depletion attenuates TNF-a–driven caspase activation and cytotoxicity in osteoblasts and enhances BMP2-driven ectopic bone formation in vivo. Cross-species mapping suggests that the two mouse regulatory elements converge into a single promoter-proximal composite element at the human SAMD9L locus, supporting a conserved inflammatory control node. Together, these findings define a BMP4–Smad4 mechanism that reshapes NF-?B enhancer outputs to limit osteoblast death and nominate the SAMD9L regulatory circuit as a therapeutic entry point for inflammatory bone loss. Overall design: Examination of the effects of TNFa and/or BMP4 on gene expression in murine osteoblastic cells