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:In humans, inactivating mutations in MLL4, which encodes a histone H3-lysine 4-methyltrasferase, lead to Kabuki syndrome (KS). While dwarfism is a cardinal feature of KS, the underlying etiology remains unclear. Here we report that Mll4 is a critical regulator of the development of growth hormone-releasing hormone (GHRH)-producing neurons in the hypothalamus. The two distinct Mll4 mutant mouse models exhibited dwarfism, accompanied by impairment of developmental programs for GHRH-neurons. Our genome-wide studies revealed that, in the developing hypothalamus, Mll4 collaborates mainly with the transcription factor Nrf1 to trigger the expression of GHRH-neuronal genes. Interestingly, the deficiency of Mll4 resulted in a marked reduction of transcriptionally active histone marks in the embryonic hypothalamus, which was rescued by treatment with the histone deacetylase inhibitor AR-42. Further, AR-42 treatment restored GHRH-neuronal production in Mll4 mutant mice. Together, our results suggest that the dysregulation of MLL4-directed epigenetic control of GHRH-neuronal genes is a substantial contributing factor to dwarfism in human KS.

Project description:In this study, we reprogrammed fibroblasts from two azoospermic Klinefelter syndrome (KS) patients, and two healthy male and one healthy female donor with an efficient integration-free method using episomal plasmids and laminin-521 (LN521). Whole genome transcriptomics analysis showed differentially expressed genes between KS and healthy male donors with enrichment in gene ontology (GO) terms associated with fertility, cardiovascular development, ossification and brain development, for both KS hiPSCs and fibroblasts, correlating with the KS clinical phenotype. Thorough XCI analysis combining transcriptomics data, RNA FISH and H3K27me3 staining, revealed skewed XCI in one KS fibroblast line and variability in XCI state of KS hiPSCs similar to female hiPSCs, showing either XaXi or XaXe status. Furthermore, we found up-regulated X-linked genes involved in nervous system development, synaptic transmission as well as metabolic processes supporting the potential use of KS derived hiPSC as an in vitro model for KS.

Project description:In sub-Saharan Africa, endemic Kaposi’s sarcoma (EnKS) is still prevalent despite high incidence of epidemic Kaposi’s sarcoma (EpKS) resulting from the on-going HIV-1 epidemic. While KSHV is clearly the etiologic agent of KS, the mechanisms underlying KS development are not fully understood. For example, HIV-1 co-infection and concomitant immune dysfunction have been associated with EpKS development. However, the direct or indirect role(s) of HIV-1, and therefore of immune suppression, in EpKS remains unclear. How, or whether, EpKS is mechanistically distinct from EnKS is unknown. Thus, the absence of HIV-1 co-infection in EnKS provides a unique control for investigating and deciphering whether HIV-1 plays a direct or indirect role in the EpKS tumor microenvironment. We hypothesized that HIV-1 co-infection would induce transcriptome changes that differentiate EpKS from EnKS, thereby defining the direct intra-tumor role of HIV-1 in KS. Comparison of ART-treated and -naïve patients would further define the impact of ART on the KS transcriptome. We utilized RNA-seq followed by multiparameter bioinformatics analysis to compare transcriptomes from KS lesions to uninvolved control skin. We provide the first transcriptomic comparison of EpKS versus EnKS, ART-treated vs. –naïve EpKS and male vs. female EpKS to define the roles of HIV-1 co-infection, the impact of ART, and gender on KS gene expression profiles. Our findings suggest that ART-use and gender have minimal impact on transcriptome profiles of KS lesions. Gene expression profiles strongly correlated between EpKS and EnKS patients (Spearman r=0.83, p<10-10). A subset of genes involved in tumorigenesis and inflammation/immune responses showed higher magnitude, but not unique dysregulation in EnKS compared to EpKS. While gender and ART had no detectable contribution, the trend toward higher magnitude of gene dysregulation in EnKS coupled with the absence of HIV-1 transcripts in EpKS may suggest an indirect or systemic effect of HIV-1 to promote KS tumorigenesis.

Project description:EHMT1 haploinsufficiency causes Kleefstra syndrome (KS), a complex disorder of developmental delay and intellectual disability. EHMT1 encodes a lysine methyltransferase GLP and regulates histone H3 lysine 9 dimethylation (H3K9me2). Ehmt1 heterozygous mutant (Ehmt1∆/+) mice show KS-like abnormal behavioral phenotypes. Here, we examined the reversibility of decreased H3K9me2 by postnatal supply of GLP in post-mitotic neuron of Ehmt1∆/+ mice brain. For this purpose, we generated the mice harboring inducible Ehmt1 cDNA with CamKII-creER (Ehmt1 iTG-neuron mice) in Ehmt1∆/+ background. These mice expressed exogenous Ehmt1 in post-mitotic neuron upon Tamoxifen treatment. Using these mice, we sorted out NeuN+ cells from cortical region and performed Histone H3 K9-dimethyation ChIP analysis. Here we showed that Ehmt1 haploinsufficiency induces global reduction of euchromatic H3K9me2 especially in the euchromatic region of brain and that postnatal supply of GLP can reverse the diminished H3K9me2 phenotype, even in a postmitotic situation.

Project description:Purpose: To characterize genome-wide microRNA (miRNA) expression profiles in the context of Kaposi’s sarcoma-associated herpesvirus (KSHV)-induced oncogenesis using isogenic cell lines for a Kaposi's sarcoma (KS) xenograft model: KSHV-infected human endothelial cells (LTC) that form tumors with properties closely resembling KS lesions in nude mice and uninfected parental (TIVE) cells. Methods: miRNA expression profiles of LTC and TIVE cells were generated by deep sequencing using Illumina HiSeq 2500. The mappable reads were aligned to the human genome and miRBase using Bowtie. Results: We show, through global cellular miRNA transcriptome analysis, that KSHV infection has a profound impact on the host miRNA expression landscape, up-regulating multiple miRNAs with oncogenic roles while down-regulating many tumor suppressive miRNAs, thereby contributing to KS oncogenesis. In particular, we identify miR-127-3p as one of the most significantly down-regulated miRNAs in LTC and restoring this miRNA inhibits KSHV-induced transformation, proliferation and tumorigenesis. Conclusions: This study provides a detailed analysis of the cellular miRNA transcriptome in LTC and TIVE cells using small RNA sequencing technology. We identify significant dysregulation of cellular miRNAs with important oncogenic or tumor-suppressive functions that may be physiologically relevant to KSHV oncogenesis. Moreover, our results identify a previously unrecognized tumor suppressor function for miR-127-3p in KS, indicating that its restoration offers potential as a therapeutic intervention for KS.

Project description:Identification of the relationships of Kaposi sarcoma (KS), normal skin to various cell cultures. The effects of KS herpes virus, the infectious cause of KS, on infected endothelial cells are also investigated.

Project description:Kleefstra syndrome (KS, also known as 9q.34.3 deletion syndrome) is a rare genetic disorder characterized by a developmental delay, abnormal behaviors and autism-like features. This syndrome is caused by haplo-insufficiency of the euchromatin histone methyltransferase 1 gene (EHMT1/GLP/KDM1D). This gene product, GLP is a methyltransferase responsible for mono- and di-methylation of lysine 9 on histone H3 N-terminal tail, which modulates epigenetic information. Ehmt1 heterozygous mutant (Ehmt1∆/+) mice show KS-like abnormal behavioral phenotypes and utilized as KS model mice. Here, we isolated nuclei from adult Ehmt1∆/+ mice cortex and analysed gene expression precisely by single nucleus RNA-seq analysis. It showed that many genes were up or down regulated in different cell types of Ehmt1∆/+ mice brain. Among them, inflammation associating genes are up-regulated in Ehmt1∆/+ mice neuronal cells. And this up-regulation was reversed by postnatal supply of GLP in post-mitotic neuron of Ehmt1∆/+ mice brain.