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Histone acetyltransferases (HATs) GCN5 and PCAF (GCN5/PCAF) and CBP and p300 (CBP/p300) are transcription co‐activators. However, how these two distinct families of HATs regulate gene activation remains unclear. Here, we show deletion of GCN5/PCAF in cells specifically and dramatically reduces acetylation on histone H3K9 (H3K9ac) while deletion of CBP/p300 specifically and dramatically reduces acetylations on H3K18 and H3K27 (H3K18/27ac). A ligand for nuclear receptor (NR) PPARδ induces sequential enrichment of H3K18/27ac, RNA polymerase II (Pol II) and H3K9ac on PPARδ target gene Angptl4 promoter, which correlates with a robust Angptl4 expression. Inhibiting transcription elongation blocks ligand‐induced H3K9ac, but not H3K18/27ac, on the Angptl4 promoter. Finally, we show GCN5/PCAF and GCN5/PCAF‐mediated H3K9ac correlate with, but are surprisingly dispensable for, NR target gene activation. In contrast, CBP/p300 and their HAT activities are essential for ligand‐induced Pol II recruitment on, and activation of, NR target genes. These results highlight the substrate and site specificities of HATs in cells, demonstrate the distinct roles of GCN5/PCAF‐ and CBP/p300‐mediated histone acetylations in gene activation, and suggest an important role of CBP/p300‐mediated H3K18/27ac in NR‐dependent transcription. In general, histone acetylation correlates with gene activation; however, it is not clear if it is a cause or consequence of increased transcription. Here, the related histone acetyltransferases CBP and p300, which acetylate H3K18 and H3K27, are shown to be required for the induction of PPARδ target genes, while GCN5/PCAF‐mediated H3K9 acetylation is dispensable.

B-cell non-Hodgkin’s lymphoma comprises biologically and clinically distinct diseases the pathogenesis of which is associated with genetic lesions affecting oncogenes and tumour-suppressor genes. We report here that the two most common types—follicular lymphoma and diffuse large B-cell lymphoma—harbour frequent structural alterations inactivating CREBBP and, more rarely, EP300 , two highly related histone and non-histone acetyltransferases (HATs) that act as transcriptional co-activators in multiple signalling pathways. Overall, about 39% of diffuse large B-cell lymphoma and 41% of follicular lymphoma cases display genomic deletions and/or somatic mutations that remove or inactivate the HAT coding domain of these two genes. These lesions usually affect one allele, suggesting that reduction in HAT dosage is important for lymphomagenesis. We demonstrate specific defects in acetylation-mediated inactivation of the BCL6 oncoprotein and activation of the p53 tumour suppressor. These results identify CREBBP/EP300 mutations as a major pathogenetic mechanism shared by common forms of B-cell non-Hodgkin’s lymphoma, with direct implications for the use of drugs targeting acetylation/deacetylation mechanisms. CREBBP and EP300 mutations in B-cell lymphoma In three different subtypes of B-cell lymphomas, two papers report frequent somatic mutations in the genes CREBBP and EP300 , which are present in primary tumours or acquired at relapse. These genes encode related acetyltransferases that mainly function to regulate gene expression by acetylating histones and other transcriptional regulators. The mutations disrupt these activities and thus alter chromatin regulation of gene expression, as well as proliferation and potentially the response to anticancer drugs. These studies may provide a rationale for the use of histone deacetylase inhibitors in certain B-cell lymphomas. In three different subtypes of B-cell lymphomas, two papers now report frequent somatic mutations in CREBBP and EP300 , present in primary tumours or acquired at relapse. These genes encode related acetyltransferases that mainly function to regulate gene expression by acetylating histones and other transcriptional regulators. The mutations found inactivate these activities and thus alter chromatin regulation of gene expression, as well as proliferation and potentially the response to therapeutic drugs.

Autism spectrum disorders (ASDs) are a group of neurodevelopmental afflictions characterized by repetitive behaviors, deficits in social interaction, and impaired communication skills. For most ASD patients, the underlying causes are unknown. Genetic mutations have been identified in about 25 percent of ASD cases, including mutations in epigenetic regulators, suggesting that dysregulated chromatin or DNA function is a critical component of ASD. Mutations in the histone acetyltransferase CREB binding protein (CBP, CREBBP) cause Rubinstein-Taybi Syndrome (RTS), a developmental disorder that includes ASD-like symptoms. Recently, genomic studies involving large numbers of ASD patient families have theoretically modeled CBP and its paralog p300 (EP300) as critical hubs in ASD-associated protein and gene interaction networks, and have identified de novo missense mutations in highly conserved residues of the CBP acetyltransferase and CH1 domains. Here we provide animal model evidence that supports this notion that CBP and its CH1 domain are relevant to autism. We show that mice with a deletion mutation in the CBP CH1 (TAZ1) domain (CBPΔCH1/ΔCH1) have an RTS-like phenotype that includes ASD-relevant repetitive behaviors, hyperactivity, social interaction deficits, motor dysfunction, impaired recognition memory, and abnormal synaptic plasticity. Our results therefore indicate that loss of CBP CH1 domain function contributes to RTS, and possibly ASD, and that this domain plays an essential role in normal motor function, cognition and social behavior. Although the key physiological functions affected by ASD-associated mutation of epigenetic regulators have been enigmatic, our findings are consistent with theoretical models involving CBP and p300 in ASD, and with a causative role for recently described ASD-associated CBP mutations.

Adult blood cell production or definitive hematopoiesis requires the transcription factor c-Myb. The closely related KAT3 histone acetyltransferases CBP (CREBBP) and p300 (EP300) bind c-Myb through their KIX domains and mice homozygous for a p300 KIX domain mutation exhibit multiple blood defects. Perplexingly, mice homozygous for the same KIX domain mutation in CBP have normal blood. Here we test the hypothesis that the CBP KIX domain contributes subordinately to hematopoiesis via a genetic interaction with c-Myb. We assessed hematopoiesis in mice bearing compound mutations of c-Myb and/or the KIX domains of CBP and p300, and measured the effect of KIX domain mutations on c-Myb-dependent gene expression. We found that in the context of a p300 KIX mutation, the CBP KIX domain mutation affects platelets, B cells, T cells, and red cells. Gene interaction (epistasis) analysis provides mechanistic evidence that blood defects in KIX mutant mice are consistent with reduced c-Myb and KIX interaction. Lastly, we demonstrated that the CBP and p300 KIX domains contribute to both c-Myb-dependent gene activation and repression. Together these results suggest that the KIX domains of CBP, and especially p300, are principal mediators of c-Myb-dependent gene activation and repression that is required for definitive hematopoiesis.

Significance Catecholamines regulate adipocyte function in part by CREB activation. Obesity displays enhanced cyclic AMP response element binding protein (CREB) activity despite reduced catecholamine signals. We report that obesity promotes CREB binding protein (CBP)-mediated CREB acetylation at Lys136 in the adipose tissue by means of reduced SirT1 levels. CREB Lys136 acetylation promotes binding with the bromodomain (BRD) of CBP, which can also bind phosphorylated Ser133, through its KIX domain, upon hormonal signals. This double recognition is reflected in potentiated CBP recruitment at promoters when CREB is doubly modified. Structural data show the formation of a ternary complex between CBP BRD and KIX domains when bound to phospho-Ser133 and acetylated-Lys136 CREB. Disruption of the BRD:CREB interaction with a small molecule reduced the enhanced CREB activity associated with acetylation. In the fasted state, increases in catecholamine signaling promote adipocyte function via the protein kinase A-mediated phosphorylation of cyclic AMP response element binding protein (CREB). CREB activity is further up-regulated in obesity, despite reductions in catecholamine signaling, where it contributes to the development of insulin resistance. Here we show that obesity promotes the CREB binding protein (CBP)-mediated acetylation of CREB at Lys136 in adipose. Under lean conditions, CREB acetylation was low due to an association with the energy-sensing NAD ⁺-dependent deacetylase SirT1; amounts of acetylated CREB were increased in obesity, when SirT1 undergoes proteolytic degradation. Whereas CREB phosphorylation stimulated an association with the KIX domain of CBP, Lys136 acetylation triggered an interaction with the CBP bromodomain (BRD) that augmented recruitment of this coactivator to the promoter. Indeed, coincident Ser133 phosphorylation and Lys136 acetylation of CREB stimulated the formation of a ternary complex with the KIX and BRD domains of CBP by NMR analysis. As disruption of the CREB:BRD complex with a CBP-specific BRD inhibitor blocked effects of CREB acetylation on target gene expression, our results demonstrate how changes in nutrient status modulate cellular gene expression in response to hormonal signals.

MED23, a subunit of the Mediator coactivator complex, is important for the expression of a subset of MAPK/ERK pathway-responsive genes, the constituents of which vary between cell types for reasons that are not completely clear. MAPK/ERK pathway-dependent processes are essential for T-cell development and function, but whether MED23 has a role in this context is unknown. We generated Med23 conditional knockout mice and induced Med23 deletion in early T-cell development using the lineage specific Lck-Cre transgene. While the total cell number and distribution of cell populations in the thymuses of Med23flox/flox;Lck-Cre mice were essentially normal, MED23 null T-cells failed to efficiently populate the peripheral lymphoid organs. MED23 null thymocytes displayed decreased expression of the MAPK/ERK-responsive genes Egr1, Egr2, as well as of the membrane glycoprotein Cd52 (CAMPATH-1). MED23 null CD4 single-positive thymocytes also showed decreased expression of KLF2 (LKLF), a T-cell master regulatory transcription factor. Indeed, similarities between the phenotypes of mice lacking MED23 or KLF2 in T-cells suggest that KLF2 deficiency in MED23 null T-cells is one of their key defects. Mechanistic experiments using MED23 null MEFs further suggest that MED23 is required for full activity of the MAPK-responsive transcription factor MEF2, which has previously been shown to mediate Klf2 expression. In summary, our data indicate that MED23 has critical roles in enabling T-cells to populate the peripheral lymphoid organs, possibly by potentiating MEF2-dependent expression of the T-cell transcription factor KLF2.

The C‐terminal activation domain (C‐TAD) of the hypoxia‐inducible transcription factors HIF‐1α and HIF‐2α binds the CH1 domains of the related transcriptional coactivators CREB‐binding protein (CBP) and p300, an oxygen‐regulated interaction thought to be highly essential for hypoxia‐responsive transcription. The role of the CH1 domain in vivo is unknown, however. We created mutant mice bearing deletions in the CH1 domains (ΔCH1) of CBP and p300 that abrogate their interactions with the C‐TAD, revealing that the CH1 domains of CBP and p300 are genetically non‐redundant and indispensable for C‐TAD transactivation function. Surprisingly, the CH1 domain was only required for an average of ∼35–50% of global HIF‐1‐responsive gene expression, whereas another HIF transactivation mechanism that is sensitive to the histone deacetylase inhibitor trichostatin A (TSA S ) accounts for ∼70%. Both pathways are required for greater than 90% of the response for some target genes. Our findings suggest that a novel functional interaction between the protein acetylases CBP and p300, and deacetylases, is essential for nearly all HIF‐responsive transcription.

The coactivators CBP (Cre-element binding protein (CREB)-binding protein) and its paralogue p300 are thought to supply adaptor molecule and protein acetyltransferase functions to many transcription factors that regulate gene expression 1 . Normal development requires CBP and p300, and mutations in these genes are found in haematopoietic and epithelial tumours 2 , 3 , 4 , 5 , 6 . It is unclear, however, which functions of CBP and p300 are essential in vivo . Here we show that the protein-binding KIX domains of CBP and p300 have nonredundant functions in mice. In mice homozygous for point mutations in the KIX domain of p300 designed to disrupt the binding surface for the transcription factors c-Myb and CREB 7 , 8 , 9 , multilineage defects occur in haematopoiesis, including anaemia, B-cell deficiency, thymic hypoplasia, megakaryocytosis and thrombocytosis. By contrast, age-matched mice homozygous for identical mutations in the KIX domain of CBP are essentially normal. There is a synergistic genetic interaction between mutations in c-Myb and mutations in the KIX domain of p300, which suggests that the binding of c-Myb to this domain of p300 is crucial for the development and function of megakaryocytes. Thus, conserved domains in two highly related coactivators have contrasting roles in haematopoiesis.

CREBBP and EP300 mutations in B-cell lymphoma In three different subtypes of B-cell lymphomas, two papers report frequent somatic mutations in the genes CREBBP and EP300 , which are present in primary tumours or acquired at relapse. These genes encode related acetyltransferases that mainly function to regulate gene expression by acetylating histones and other transcriptional regulators. The mutations disrupt these activities and thus alter chromatin regulation of gene expression, as well as proliferation and potentially the response to anticancer drugs. These studies may provide a rationale for the use of histone deacetylase inhibitors in certain B-cell lymphomas. In three different subtypes of B-cell lymphomas, two papers now report frequent somatic mutations in CREBBP and EP300 , present in primary tumours or acquired at relapse. These genes encode related acetyltransferases that mainly function to regulate gene expression by acetylating histones and other transcriptional regulators. The mutations found inactivate these activities and thus alter chromatin regulation of gene expression, as well as proliferation and potentially the response to therapeutic drugs. Relapsed acute lymphoblastic leukaemia (ALL) is a leading cause of death due to disease in young people, but the biological determinants of treatment failure remain poorly understood. Recent genome-wide profiling of structural DNA alterations in ALL have identified multiple submicroscopic somatic mutations targeting key cellular pathways 1 , 2 , and have demonstrated substantial evolution in genetic alterations from diagnosis to relapse 3 . However, DNA sequence mutations in ALL have not been analysed in detail. To identify novel mutations in relapsed ALL, we resequenced 300 genes in matched diagnosis and relapse samples from 23 patients with ALL. This identified 52 somatic non-synonymous mutations in 32 genes, many of which were novel, including the transcriptional coactivators CREBBP and NCOR1 , the transcription factors ERG , SPI1 , TCF4 and TCF7L2 , components of the Ras signalling pathway, histone genes, genes involved in histone modification ( CREBBP and CTCF) , and genes previously shown 1 , 2 to be targets of recurring DNA copy number alteration in ALL. Analysis of an extended cohort of 71 diagnosis–relapse cases and 270 acute leukaemia cases that did not relapse found that 18.3% of relapse cases had sequence or deletion mutations of CREBBP , which encodes the transcriptional coactivator and histone acetyltransferase CREB-binding protein (CREBBP, also known as CBP) 4 . The mutations were either present at diagnosis or acquired at relapse, and resulted in truncated alleles or deleterious substitutions in conserved residues of the histone acetyltransferase domain. Functionally, the mutations impaired histone acetylation and transcriptional regulation of CREBBP targets, including glucocorticoid responsive genes. Several mutations acquired at relapse were detected in subclones at diagnosis, suggesting that the mutations may confer resistance to therapy. These results extend the landscape of genetic alterations in leukaemia, and identify mutations targeting transcriptional and epigenetic regulation as a mechanism of resistance in ALL.