Heritable maintenance of chromatin modifications confers transcriptional memory of interferon-γ signaling.

Interferon-γ (IFNγ) transiently activates genes related to inflammation and innate immunity. A subset of targets retain a mitotically heritable memory of prior IFNγ exposure, resulting in hyperactivation upon re-exposure through poorly understood mechanisms. Here, we discover that the transcriptionally permissive chromatin marks H3K4me1, H3K14ac and H4K16ac are established during IFNγ priming and are selectively maintained on a cluster of guanylate-binding protein (GBP) genes in dividing human cells in the absence of transcription. The histone acetyltransferase KAT7 is required for H3K14ac deposition at GBP genes and for accelerated GBP reactivation upon re-exposure to IFNγ. In naive cells, the GBP cluster is maintained in a low-level repressive chromatin state, marked by H3K27me3, limiting priming through a PRC2-dependent mechanism. Unexpectedly, IFNγ priming results in transient accumulation of this repressive mark despite active gene expression. However, during the memory phase, H3K27 methylation is selectively depleted from primed GBP genes, facilitating hyperactivation. Furthermore, we identified a cis-regulatory element that forms transient, long-range contacts across the GBP cluster and acts as a repressor, curbing hyperactivation of previously IFNγ-primed cells. Our results provide insight into the chromatin basis for the long-term transcriptional memory of IFNγ signaling, which might contribute to enhanced innate immunity.