Project description:Background Kabuki syndrome (KS) is a genetic disorder caused by DNA mutations in KMT2D, a lysine methyltransferase that methylates histones and other proteins, and therefore modifies chromatin structure and subsequent gene expression. Ketones, derived from the ketogenic diet, are histone deacetylase inhibitors that can ‘open’ chromatin and encourage gene expression. Preclinical studies have shown that the ketogenic diet rescues hippocampal memory neurogenesis in mice with KS via the epigenetic effects of ketones. Methods Single-cell RNA sequencing and mass spectrometry-based proteomics were used to explore molecular mechanisms of disease in individuals with KS (n=4) versus controls (n=4). Findings Pathway enrichment analysis indicated that loss of function mutations in KMT2D are associated with ribosomal protein dysregulation at an RNA and protein level in individuals with KS (FDR <0.05). Cellular proteomics also identified immune dysregulation and increased abundance of other lysine modification and histone binding proteins, representing a potential compensatory mechanism. A 12-year-old boy with KS, suffering from recurrent episodes of cognitive decline, exhibited improved cognitive function and neuropsychological assessment performance after 12 months on the ketogenic diet, with concomitant improvement in transcriptomic ribosomal protein dysregulation.

Project description:Kabuki Syndrome (KS) is a multisystemic rare disorder, characterized by growth delay, distinctive facial features, intellectual disability, and rarely autism spectrum disorder. This condition is mostly caused by de novo mutations of KMT2D, encoding a catalytic subunit of the COMPASS complex involved in enhancer regulation. KMT2D catalyzes the deposition of histone-3-lysine-4 mono-methyl (H3K4Me1) that marks active and poised enhancers. To assess the impact of KMT2D mutations in the chromatin landscape of KS tissues, we have generated patient-derived induced pluripotent stem cells (iPSC), which we further differentiated into neural crest stem cells (NCSC), mesenchymal stem cells (MSC) and cortical neurons (iN). In addition, we further collected blood samples from 5 additional KS patients. To complete our disease modeling cohort we generated an isogenic KMT2D mutant line from human embryonic stem cells, which we differentiated into neural precursor and mature neurons. Micro-electrode-array (MEA)-based neural network analysis of KS iNs revealed an altered pattern of spontaneous network-bursts in a Kabuki-specific pattern. RNA-seq profiling was performed to relate this aberrant MEA pattern to transcriptional dysregulations, revealing that dysregulated genes were enriched for neuronal functions, such as ion channels, synapse activity, and electrophysiological activity. Here we show that KMT2D haploinsufficiency tends to heavily affect the transcriptome of cortical neurons and differentiated tissues while sparing multipotent states, suggesting that KMT2D has a most prevalent role in terminally differentiated cell and activate transcriptional circuitry unique to each cell type. Moreover, thorough profiling of H3K4Me1 unveiled the almost complete uncoupling between this chromatin mark and the regulatory effects of KMT2D on transcription, which is instead reflected by a defect of H3K27Ac. By integrating RNA-seq with ChIP-seq data we defined TEAD and REST as the master effectors of KMT2D haploinsufficiency. Also, we identified a subset of genes whose regulation is controlled by the balance between KMT2D and EZH2 dosage. Finally, we identified the bona fide direct targets of KMT2D in healthy and KS mature cortical neurons and TEAD2 as the main proxy of KMT2D dysregulation in KS. Overall, our study provides the transcriptional and epigenomic characterization of patient-derived tissues as well as iPSCs and differentiated disease-relevant cell types, as well as the identification of KMT2D direct target in cortical neurons, together with the identification of a neuronal phenotype of the spontaneous electrical activity.

Project description:Kabuki Syndrome (KS) is a multisystemic rare disorder, characterized by growth delay, distinctive facial features, intellectual disability, and rarely autism spectrum disorder. This condition is mostly caused by de novo mutations of KMT2D, encoding a catalytic subunit of the COMPASS complex involved in enhancer regulation. KMT2D catalyzes the deposition of histone-3-lysine-4 mono-methyl (H3K4Me1) that marks active and poised enhancers. To assess the impact of KMT2D mutations in the chromatin landscape of KS tissues, we have generated patient-derived induced pluripotent stem cells (iPSC), which we further differentiated into neural crest stem cells (NCSC), mesenchymal stem cells (MSC) and cortical neurons (iN). In addition, we further collected blood samples from 5 additional KS patients. To complete our disease modeling cohort we generated an isogenic KMT2D mutant line from human embryonic stem cells, which we differentiated into neural precursor and mature neurons. Micro-electrode-array (MEA)-based neural network analysis of KS iNs revealed an altered pattern of spontaneous network-bursts in a Kabuki-specific pattern. RNA-seq profiling was performed to relate this aberrant MEA pattern to transcriptional dysregulations, revealing that dysregulated genes were enriched for neuronal functions, such as ion channels, synapse activity, and electrophysiological activity. Here we show that KMT2D haploinsufficiency tends to heavily affect the transcriptome of cortical neurons and differentiated tissues while sparing multipotent states, suggesting that KMT2D has a most prevalent role in terminally differentiated cell and activate transcriptional circuitry unique to each cell type. Moreover, thorough profiling of H3K4Me1 unveiled the almost complete uncoupling between this chromatin mark and the regulatory effects of KMT2D on transcription, which is instead reflected by a defect of H3K27Ac. By integrating RNA-seq with ChIP-seq data we defined TEAD and REST as the master effectors of KMT2D haploinsufficiency. Also, we identified a subset of genes whose regulation is controlled by the balance between KMT2D and EZH2 dosage. Finally, we identified the bona fide direct targets of KMT2D in healthy and KS mature cortical neurons and TEAD2 as the main proxy of KMT2D dysregulation in KS. Overall, our study provides the transcriptional and epigenomic characterization of patient-derived tissues as well as iPSCs and differentiated disease-relevant cell types, as well as the identification of KMT2D direct target in cortical neurons, together with the identification of a neuronal phenotype of the spontaneous electrical activity.

Project description:KMT2D+/bGeoation in KMT2D, a histone-lysine N-methyl transferase, is responsible for majority of Kabuki syndrome in human. A mouse model of Kabuki syndrome with heterzygous KMT2D+/bGeoation of KMT2D, KMT2D+/bGeo was created to understand the disease mechanism and for drug discovery. TAK-418-418, a lysine-specific histone demethylase (LSD1) inhibitor, was tested on these mice for therapeutic treatment of the disease. Rescue of genome wide chromatin abnormality, which has been reported in KMT2D+/bGeo mice, was evaluated by high throughput next generation sequencing following chromatin immunoprecipitation of H3K4me1 and H3K4me3.

Project description:The crosstalk between H3K4 monomethylation and DNA methylation has been receiving little attention to date. We investigated a mouse model harboring a loss-of-function mutation of lysine methyltransferase 2D (KMT2D), which catalyzes the monomethylation of lysine 4 on histone H3. We performed H3K4me1 ChIP-seq in spleen B cells with the wild type (WT) KMT2D as well as heterozygous (HET) and homozygous (HOM) chr15: 98,835,228 A>T KMT2D mutation. Alongside, using WGBS, we performed genome-wide DNA methylation profiling in spleen B cells with the WT KMT2D as well as HET and HOM chr15: 98,835,228 A>T KMT2D mutation.

Project description:The crosstalk between H3K4 monomethylation and DNA methylation has been receiving little attention to date. We investigated a mouse model harboring a loss-of-function mutation of lysine methyltransferase 2D (KMT2D), which catalyzes the monomethylation of lysine 4 on histone H3. We performed H3K4me1 ChIP-seq in spleen B cells with the wild type (WT) KMT2D as well as heterozygous (HET) and homozygous (HOM) chr15: 98,835,228 A>T KMT2D mutation. Alongside, using WGBS, we performed genome-wide DNA methylation profiling in spleen B cells with the WT KMT2D as well as HET and HOM chr15: 98,835,228 A>T KMT2D mutation.

Project description:Histone H3 lysine (H3K4) methyltransferase KMT2D is a key regulator of gene expression, mainly through promoting H3K4 methylation and activating enhancers, and plays critical roles in development, differentiation, metabolism, and tumor suppression. To investigate the mechanisms by which KMT2D loss promotes HNSCC and to identify potential therapeutic targets, we generated KMT2D wild-type (KMT2D-WT) and KMT2D knock-out (KMT2D-KO) SCC23 HNSCC cells and performed RNA-seq under different glucose conditions.

Project description:Lysine specific methyltransferase 2D (Kmt2d) catalyzes the mono-methylation of histone 3 lysine 4 (H3K4me1) and plays a critical role in regulatory T cell generation via modulating Foxp3 gene expression. We utilized ChIPseq, RNAseq, and scRNAseq to show the role of Kmt2d in naive CD8+ T cell generation and survival.

Project description:Mutation in KMT2D, a histone-lysine N-methyl transferase, is responsible for majority of Kabuki syndrome in human. A mouse model of Kabuki syndrome with heterzygous mutation of KMT2D, KMT2D+/bGeo was created to understand the disease mechanism and for drug discovery. TAK-418-418, a lysine-specific histone demethylase (LSD1) inhibitor, was tested on these mice for therapeutic treatment of the disease. Differences between expression levels among different experimental conditions was evaluated by high throughput RNA sequencing (RNA-Seq).

Project description:We identified KMT2D target loci in OCI-LY7 by ChIPseq. KMT2D ChIPseq was carried out in the LY7 cell line (n=1).