Project description:Somatic mutations of the KMT2D methyltransferase gene represent a common genetic lesion in multiple cancer types. In diffuse large B cell lymphoma (DLBCL) and follicular lymphoma (FL), these mutations are highly recurrent and occur early during tumorigenesis, suggesting a central role in transformation. Here we show that FL/DLBCL-associated KMT2D mutations impair its enzymatic activity and lead to diminished global H3K4 methylation in germinal center (GC) B cells and DLBCL, consistent with the enrichment of KMT2D binding at enhancer and promoter regions marked by mono- and tri-methylation. Conditional deletion of Kmt2d early during B cell development, but not after initiation of the GC reaction, leads to an increase in GC B cells, whose transcriptional profile is enriched in cell-cycle regulatory and B-cell receptor signaling genes. Consistently, Kmt2d-deficient B cells exhibit proliferative advantage ex vivo. Loss of Kmt2d combined with BCL2 deregulation, mimicking FL/DLBCL pathogenesis, leads to an increased incidence of clonal lymphoproliferations resembling the features of the human tumors. These findings suggest that early KMT2D loss facilitates lymphomagenesis by remodeling the epigenetic landscape of the cancer precursor cells. Eradication of KMT2D-deficient cells may represent a rational therapeutic approach targeting early tumorigenic events.

Project description:Inactivating mutations of the CREBBP acetyltransferase and, at lower frequencies, its paralogue EP300 are among the most common genetic alterations in diffuse large B-cell lymphoma (DLBCL) and follicular lymphoma (FL), the two most frequent B cell malignancies. Here we uncover unexpected distinct functions for CREBBP and EP300 in the germinal center (GC), i.e. the target structure for most human B cell lymphomas. We show that these proteins modulate non-overlapping transcriptional programs that are preferentially enriched in biological functions associated with the separate anatomic compartments of the GC. Consistently, deletion of CREBBP or EP300 have opposing effects on GC formation in vivo. Nonetheless, these proteins partially compensate for each other to maintain a minimal threshold of acetyltransferase activity and guarantee homeostatic control of the GC, which is completely abrogated by their combined loss. This synthetic lethal interaction is retained in DLBCL cells, identifying an Achille’s heel in CREBBP-mutant lymphomas that could be pharmacologically targeted by using a novel, selective small molecule inhibitor of the CREBBP/EP300 bromodomain. These data shed light on the unique roles of CREBBP and EP300 in the physiology and pathology of GC B cells, and provide a proof-of-principle for the development and testing of EP300 inhibition as a therapeutic strategy in these diseases.

Project description:Inactivating mutations of the gene encoding for the CREBBP acetyltransferase are highly frequent in diffuse large B cell lymphoma (DLBCL, 30% of cases) and follicular lymphoma (FL, 60% of cases), the two most common cancers derived from the germinal-center (GC). However, the role of CREBBP inactivation in lymphomagenesis remains unclear. Using functional epigenomics and mouse genetics, here we define the program modulated by CREBBP in primary human GC B cells and show that CREBBP regulates enhancer/super-enhancer networks, with specific roles in GC/post-GC cell fate decisions. Conditional GC-specific deletion of Crebbp in the mouse perturbs the expression of a limited set of genes involved in the regulation of signal transduction (BCR, TLR and CD40), lineage specification (NF-κB and BCL6) and terminal B cell differentiation (PRDM1, IRF4). Consistently, Crebbp-deficient B cells exhibit proliferative advantage and show impaired plasma cell differentiation. While GC-specific loss of Crebbp was not sufficient to initiate malignant transformation, compound Crebbp-haploinsufficient/BCL2-transgenic mice, mimicking the genetics ofFL and DLBCL, display an increased incidence of clonal lymphoid malignancies recapitulating the features of the human diseases. These findings establish CREBBPas a haploinsufficient tumor suppressor gene in GC B cells and provide insights into the mechanisms and targets by which loss of CREBBP contributes to lymphomagenesis.

Project description:Inactivating mutations of the gene encoding for the CREBBP acetyltransferase are highly frequent in diffuse large B cell lymphoma (DLBCL, 30% of cases) and follicular lymphoma (FL, 60% of cases), the two most common cancers derived from thegerminal-center (GC). However, the role of CREBBP inactivation in lymphomagenesisremains unclear. Using functional epigenomics and mouse genetics, here we definethe program modulated by CREBBP in primary human GC B cells and show thatCREBBP regulates enhancer/super-enhancer networks, with specific roles in GC/post-GC cell fate decisions. Conditional GC-specific deletion of Crebbp in the mouseperturbs the expression of a limited set of genes involved in the regulation of signaltransduction (BCR, TLR and CD40), lineage specification (NF-κB and BCL6) andterminal B cell differentiation (PRDM1, IRF4). Consistently, Crebbp-deficient B cellsexhibit proliferative advantage and show impaired plasma cell differentiation. WhileGC-specific loss of Crebbp was not sufficient to initiate malignant transformation,compound Crebbp-haploinsufficient/BCL2-transgenic mice, mimicking the genetics ofFL and DLBCL, display an increased incidence of clonal lymphoid malignanciesrecapitulating the features of the human diseases. These findings establish CREBBPas a haploinsufficient tumor suppressor gene in GC B cells and provide insights intothe mechanisms and targes by which loss of CREBBP contributes to lymphomagenesis.

Project description:Inactivating mutations of the CREBBP acetyltransferase and, at lower frequencies, its paralogue EP300 are among the most common genetic alterations in diffuse large B-cell lymphoma (DLBCL) and follicular lymphoma (FL), the two most frequent B cell malignancies. Here we uncover unexpected distinct functions for CREBBP and EP300 in the germinal center (GC), i.e. the target structure for most human B cell lymphomas. We show that these proteins modulate non-overlapping transcriptional programs that are preferentially enriched in biological functions associated with the separate anatomic compartments of the GC. Consistently, deletion of CREBBP or EP300 have opposing effects on GC formation in vivo. Nonetheless, these proteins partially compensate for each other to maintain a minimal threshold of acetyltransferase activity and guarantee homeostatic control of the GC, which is completely abrogated by their combined loss. This synthetic lethal interaction is retained in DLBCL cells, identifying an Achille’s heel in CREBBP-mutant lymphomas that could be pharmacologically targeted by using a novel, selective small molecule inhibitor of the CREBBP/EP300 bromodomain. These data shed light on the unique roles of CREBBP and EP300 in the physiology and pathology of GC B cells, and provide a proof-of-principle for the development and testing of EP300 inhibition as a therapeutic strategy in these diseases.

Project description:Loss of function mutations within KMT2D are a striking feature of the germinal centre lymphomas, with lesions present in 80% of Follicular Lymphoma (FL) and 30% of Diffuse Large B-cell Lymphoma (DLBCL), resulting in decreased H3K4 methylation and altered gene expression. The KDM5 family normally maintains homeostasis through demethylating H3K4me3/2, thus negatively regulating gene expression. We hypothesised that inhibition of KDM5 may re-establish H3K4 methylation and restore the expression of genes repressed upon loss of KMT2D. Using a selective inhibitor of the KDM5 family we were able to increase H3K4me3 levels in DLBCL cell lines, predominantly at gene promoters, ultimately leading to decreased proliferation and cell death in KMT2D mutant cell lines. This appeared to be driven by an increase in the expression of negative regulators of B cell survival pathways, many of which have previously been described as targets of KMT2D and CREBBP, resulting in diminished BCR signalling. We also observed decreased BCL2 expression in all examined t(14;18) positive cell lines, alongside changes in other BCL2 family members in sensitive cell lines. KDM5 sensitivity was confirmed to be dependent on the presence of KMT2D mutations by generating de novo KMT2D mutant cell lines and correcting naturally mutant cell lines, which displayed greater and lesser sensitivity to KDM5 inhibition respectively. KDM5 inhibition may therefore be an effective therapeutic strategy for ameliorating KMT2D loss of function mutations in malignancies such as germinal centre lymphomas.

Project description:Loss of function mutations within KMT2D are a striking feature of the germinal centre lymphomas, with lesions present in 80% of Follicular Lymphoma (FL) and 30% of Diffuse Large B-cell Lymphoma (DLBCL), resulting in decreased H3K4 methylation and altered gene expression. The KDM5 family normally maintains homeostasis through demethylating H3K4me3/2, thus negatively regulating gene expression. We hypothesised that inhibition of KDM5 may re-establish H3K4 methylation and restore the expression of genes repressed upon loss of KMT2D. Using a selective inhibitor of the KDM5 family we were able to increase H3K4me3 levels in DLBCL cell lines, predominantly at gene promoters, ultimately leading to decreased proliferation and cell death in KMT2D mutant cell lines. This appeared to be driven by an increase in the expression of negative regulators of B cell survival pathways, many of which have previously been described as targets of KMT2D and CREBBP, resulting in diminished BCR signalling. We also observed decreased BCL2 expression in all examined t(14;18) positive cell lines, alongside changes in other BCL2 family members in sensitive cell lines. KDM5 sensitivity was confirmed to be dependent on the presence of KMT2D mutations by generating de novo KMT2D mutant cell lines and correcting naturally mutant cell lines, which displayed greater and lesser sensitivity to KDM5 inhibition respectively. KDM5 inhibition may therefore be an effective therapeutic strategy for ameliorating KMT2D loss of function mutations in malignancies such as germinal centre lymphomas.

Project description:Mutations in chromatin modifiers are a hallmark of many tumors, especially lymphomas arising from germinal center (GC) B cells. Given that these lymphoma mutations all induce aberrant gene repression, it is surprising that they often co-occur in individual patients. The most common pairing are mutations affecting CREBBP and KMT2D. Both impair enhancer activity in overlapping pathways to facilitate lymphomagenesis, hence their co-occurrence is especially puzzling. Herein, we report that combined haploinsufficiency of CREBBP and KMT2D (C+K) do indeed accelerate lymphomagenesis (vs either allele alone) and confer a more malignant phenotype. Single cell RNA-seq analysis of GC reaction showed that C+K haploinsufficiency induced aberrant GC hyperplasia by altering cell fate decisions, skewing B cells away from memory B and plasma cell differentiation and favored instead expansion of centroblasts. Integrative epigenomic studies in murine and human B cells showed that C+K deficiency particularly impairs enhancer activation for immune synapse genes involved in exiting the GC reaction. This effect was especially severe at super-enhancers for genes governing cell fate decisions induced by T cell help, pointing to a particular dependency for both co-activators at these specialized regulatory elements. Mechanistically, CREBBP and KMT2D formed a complex, were highly co-localized on chromatin, and were required for each-other’s stable recruitment to enhancers. Given the impaired expression of immune synapse genes, it was notable that C+K lymphomas in mice and humans manifested significantly reduced CD8+ T cell abundance. This suggests that deficiency of the two chromatin modifiers cooperatively induced an immune evasive phenotype due to failure to activate key immune synapse super-enhancers, associated with altered immune cell fate decisions. These findings point to the potential need for epigenetic adjuvant therapy to augment reactivity with immunotherapy approaches in patients with C+K deficiency.

Project description:Mutations in chromatin modifiers are a hallmark of many tumors, especially lymphomas arising from germinal center (GC) B cells. Given that these lymphoma mutations all induce aberrant gene repression, it is surprising that they often co-occur in individual patients. The most common pairing are mutations affecting CREBBP and KMT2D. Both impair enhancer activity in overlapping pathways to facilitate lymphomagenesis, hence their co-occurrence is especially puzzling. Herein, we report that combined haploinsufficiency of CREBBP and KMT2D (C+K) do indeed accelerate lymphomagenesis (vs either allele alone) and confer a more malignant phenotype.  Single cell RNA-seq analysis of GC reaction showed that C+K haploinsufficiency induced aberrant GC hyperplasia by altering cell fate decisions, skewing B cells away from memory B and plasma cell differentiation and favored instead expansion of centroblasts.  Integrative epigenomic studies in murine and human B cells showed that C+K deficiency particularly impairs enhancer activation for immune synapse genes involved in exiting the GC reaction. This effect was especially severe at super-enhancers for genes governing cell fate decisions induced by T cell help, pointing to a particular dependency for both co-activators at these specialized regulatory elements. Mechanistically, CREBBP and KMT2D formed a complex, were highly co-localized on chromatin, and were required for each-other’s stable recruitment to enhancers.  Given the impaired expression of immune synapse genes, it was notable that C+K lymphomas in mice and humans manifested significantly reduced CD8+ T cell abundance. This suggests that deficiency of the two chromatin modifiers cooperatively induced an immune evasive phenotype due to failure to activate key immune synapse super-enhancers, associated with altered immune cell fate decisions. These findings point to the potential need for epigenetic adjuvant therapy to augment reactivity with immunotherapy approaches in patients with C+K deficiency.

Project description:Mutations in chromatin modifiers are a hallmark of many tumors, especially lymphomas arising from germinal center (GC) B cells. Given that these lymphoma mutations all induce aberrant gene repression, it is surprising that they often co-occur in individual patients. The most common pairing are mutations affecting CREBBP and KMT2D. Both impair enhancer activity in overlapping pathways to facilitate lymphomagenesis, hence their co-occurrence is especially puzzling. Herein, we report that combined haploinsufficiency of CREBBP and KMT2D (C+K) do indeed accelerate lymphomagenesis (vs either allele alone) and confer a more malignant phenotype.  Single cell RNA-seq analysis of GC reaction showed that C+K haploinsufficiency induced aberrant GC hyperplasia by altering cell fate decisions, skewing B cells away from memory B and plasma cell differentiation and favored instead expansion of centroblasts.  Integrative epigenomic studies in murine and human B cells showed that C+K deficiency particularly impairs enhancer activation for immune synapse genes involved in exiting the GC reaction. This effect was especially severe at super-enhancers for genes governing cell fate decisions induced by T cell help, pointing to a particular dependency for both co-activators at these specialized regulatory elements. Mechanistically, CREBBP and KMT2D formed a complex, were highly co-localized on chromatin, and were required for each-other’s stable recruitment to enhancers.  Given the impaired expression of immune synapse genes, it was notable that C+K lymphomas in mice and humans manifested significantly reduced CD8+ T cell abundance. This suggests that deficiency of the two chromatin modifiers cooperatively induced an immune evasive phenotype due to failure to activate key immune synapse super-enhancers, associated with altered immune cell fate decisions. These findings point to the potential need for epigenetic adjuvant therapy to augment reactivity with immunotherapy approaches in patients with C+K deficiency.