Impaired cell fate through gain-of-function mutations in a chromatin reader.

Modifications of histone proteins have essential roles in normal development and human disease. Recognition of modified histones by 'reader' proteins is a key mechanism that mediates the function of histone modifications, but how the dysregulation of these readers might contribute to disease remains poorly understood. We previously identified the ENL protein as a reader of histone acetylation via its YEATS domain, linking it to the expression of cancer-driving genes in acute leukaemia1. Recurrent hotspot mutations have been found in the ENL YEATS domain in Wilms tumour2,3, the most common type of paediatric kidney cancer. Here we show, using human and mouse cells, that these mutations impair cell-fate regulation by conferring gain-of-function in chromatin recruitment and transcriptional control. ENL mutants induce gene-expression changes that favour a premalignant cell fate, and, in an assay for nephrogenesis using murine cells, result in undifferentiated structures resembling those observed in human Wilms tumour. Mechanistically, although bound to largely similar genomic loci as the wild-type protein, ENL mutants exhibit increased occupancy at a subset of targets, leading to a marked increase in the recruitment and activity of transcription elongation machinery that enforces active transcription from target loci. Furthermore, ectopically expressed ENL mutants exhibit greater self-association and form discrete and dynamic nuclear puncta that are characteristic of biomolecular hubs consisting of local high concentrations of regulatory factors. Such mutation-driven ENL self-association is functionally linked to enhanced chromatin occupancy and gene activation. Collectively, our findings show that hotspot mutations in a chromatin-reader domain drive self-reinforced recruitment, derailing normal cell-fate control during development and leading to an oncogenic outcome.

Synthesis of ADP-Ribosylated Histones Reveals Site-Specific Impacts on Chromatin Structure and Function.

ADP-ribosylation of nuclear proteins is a critical feature of various DNA damage repair pathways. Histones, particularly H3 and H2B, are major targets of ADP-ribosylation and are primarily modified on serine with a single ADP-ribose unit following DNA damage. While the overall impact of PARP1-dependent poly-ADP-ribosylation is heavily investigated, very little is known about the specific roles of histone ADP-ribosylation. Here, we report the development of an efficient and modular semisynthetic route to full-length ADP-ribosylated histones H3 and H2B, chemically installed at specific serine residues. The modified histones were used to generate various chemically defined ADP-ribosylated chromatin substrates, which were employed in biophysical assays. These studies revealed that ADP-ribosylation of serine-6 of histone H2B (H2BS6ADPr) inhibits chromatin folding and higher-order organization; notably, this effect was enhanced by ADP-ribosylation of H3S10. In addition, ADP-ribosylated nucleosomes were utilized in biochemical experiments employing a panel of lysine methyltransferase enzymes, revealing a context-dependent inhibition of histone H3K9 methylation. The availability of designer ADP-ribosylated chromatin described here is expected to facilitate further biochemical and structural studies regarding the roles of histone ADP-ribosylation in the DNA damage response.