An integrative epigenome-based strategy for unbiased functional profiling of clinical kinase inhibitors.

More than 500 kinases are implicated in the control of most cellular process in mammals, and deregulation of their activity is linked to cancer and inflammatory disorders. 80 clinical kinase inhibitors (CKIs) have been approved for clinical use and hundreds are in various stages of development. However, CKIs inhibit other kinases in addition to the intended target(s), causing both enhanced clinical effects and undesired side effects that are only partially predictable based on in vitro selectivity profiling.

Novel insights into the role of acetyl-CoA producing enzymes in epigenetic regulation.

Inflammation-dependent changes in gene expression programs in innate immune cells, such as macrophages, involve extensive reprogramming of metabolism. This reprogramming is essential for the production of metabolites required for chromatin modifications, such as acetyl-CoA, and regulate their usage and availability impacting the macrophage epigenome. One of the most transcriptionally induced proinflammatory mediator is nitric oxide (NO), which has been shown to inhibit key metabolic enzymes involved in the production of these metabolites.

Clonal hematopoiesis, inflammation, and cardiovascular disorders: a mitochondrial connection.

Mutations in two antagonistic regulators of DNA methylation, DNMT3A and TET2, are associated with clonal hematopoiesis and increased risk of cardiovascular disorders. Recently, Cobo et al. traced the mechanistic bases for such links to loss of mitochondrial integrity, cytoplasmic dispersion of mitochondrial DNA, and the subsequent activation of interferon-stimulated genes (ISGs) in macrophages.

H3K9 trimethylation in active chromatin restricts the usage of functional CTCF sites in SINE B2 repeats.

Six methyltransferases divide labor in establishing genomic profiles of histone H3 lysine 9 methylation (H3K9me), an epigenomic modification controlling constitutive heterochromatin, gene repression, and silencing of retroelements. Among them, SETDB1 is recruited to active chromatin domains to silence the expression of endogenous retroviruses. In the context of experiments aimed at determining the impact of SETDB1 on stimulus-inducible gene expression in macrophages, we found that loss of H3K9me3 caused by SETDB1 depletion was associated with increased recruitment of CTCF to >1600 DNA binding motifs contained within SINE B2 repeats, a previously unidentified target of SETDB1-mediated repression.

Integration of transcriptional and metabolic control in macrophage activation.

Macrophages react to microbial and endogenous danger signals by activating a broad panel of effector and homeostatic responses. Such responses entail rapid and stimulus-specific changes in gene expression programs accompanied by extensive rewiring of metabolism, with alterations in chromatin modifications providing one layer of integration of transcriptional and metabolic regulation. A systematic and mechanistic understanding of the mutual influences between signal-induced metabolic changes and gene expression is still lacking.