ALBERT

Description: Publication date: Available online 3 October 2013 Source: Cell Reports Author(s): Tamás Schauer , Petra C. Schwalie , Ava Handley , Carla E. Margulies , Paul Flicek , Andreas G. Ladurner Chromatin organization and gene activity are responsive to developmental and environmental cues. Although many genes are transcribed throughout development and across cell types, much of gene regulation is highly cell-type specific. To readily track chromatin features at the resolution of cell types within complex tissues, we developed and validated chromatin affinity purification from specific cell types by chromatin immunoprecipitation (CAST-ChIP), a broadly applicable biochemical procedure. RNA polymerase II (Pol II) CAST-ChIP identifies ∼1,500 neuronal and glia-specific genes in differentiated cells within the adult Drosophila brain. In contrast, the histone H2A.Z is distributed similarly across cell types and throughout development, marking cell-type-invariant Pol II-bound regions. Our study identifies H2A.Z as an active chromatin signature that is refractory to changes across cell fates. Thus, CAST-ChIP powerfully identifies cell-type-specific as well as cell-type-invariant chromatin states, enabling the systematic dissection of chromatin structure and gene regulation within complex tissues such as the brain. Graphical abstract Teaser Much gene regulation is cell-type specific, but there are few tools that allow the genome-wide tracking of chromatin features and transcriptional states at the resolution of cell types within complex tissues. Margulies, Flicek, Ladurner, and colleagues developed and validated CAST-ChIP, a biochemical procedure that profiles chromatin-associated proteins in cell types of the Drosophila brain. CAST-ChIP identified 1,500 neuron- and glia-specific genes and revealed that histone H2A.Z marks cell-type-invariant domains. CAST-ChIP enables the systematic dissection of gene regulation in cell types.