STAT1 is required to establish but not maintain interferon-γ-induced transcriptional memory.

Exposure of human cells to interferon-γ (IFNγ) results in a mitotically heritable yet reversible state called long-term transcriptional memory. We previously identified the clustered GBP genes as strongly primed by IFNγ. Here, we discovered that in primed cells, both interferon-responsive transcription factors STAT1 and IRF1 target chromatin with accelerated kinetics upon re-exposure to IFNγ, specifically at promotors of primed genes.

Centromeres: genetic input to calibrate an epigenetic feedback loop.

Centromeres are chromatin domains maintained by a self-templating feedback loop based on nucleosomes bearing the histone H3 variant CENP-A. The underlying centromeric DNA sequence is largely dispensable, yet paradoxically, it has highly conserved features. Hoffmann et al (2020) now uncover that when the epigenetic chromatin cycle falters, a genetically hardwired mechanism offers robustness to a dynamic epigenetic feedback loop ensuring long-term centromere inheritance.

Enhancer regions show high histone H3.3 turnover that changes during differentiation.

The organization of DNA into chromatin is dynamic; nucleosomes are frequently displaced to facilitate the ability of regulatory proteins to access specific DNA elements. To gain insight into nucleosome dynamics, and to follow how dynamics change during differentiation, we used a technique called time-ChIP to quantitatively assess histone H3.3 turnover genome-wide during differentiation of mouse ESCs.

The quantitative architecture of centromeric chromatin.

The centromere, responsible for chromosome segregation during mitosis, is epigenetically defined by CENP-A containing chromatin. The amount of centromeric CENP-A has direct implications for both the architecture and epigenetic inheritance of centromeres. Using complementary strategies, we determined that typical human centromeres contain ∼400 molecules of CENP-A, which is controlled by a mass-action mechanism.