Project description:Histone H3 monoaminylations at glutamine(Q) 5 represent an important family of epigenetic markers in neurons that play critical roles in the mediation of permissive gene expression (1, 2). We previously demonstrated that H3Q5 serotonylation(ser) and dopaminylation(dop) are catalyzed by the Transglutaminase 2 (TGM2) enzyme and alter both local and global chromatin states (3, 4). Here, we found that TGM2 additionally functions as an “eraser” of H3 monoaminylations that is capable of “rewriting” these epigenetic marks in cells, including a new class of this modification, H3Q5 histaminylation(his), which displays dynamic diurnal expression in brain and contributes to neural rhythmicity. We found that H3Q5his inhibits binding of the MLL1 complex to the H3 N-terminus and attenuates its methyltransferase activity on H3 lysine(K) 4. We determined that H3Q5 monoaminylation dynamics are dictated by local monoamine concentrations, which are utilized by TGM2. Taken together, we present here a novel mechanism through which a single chromatin regulatory enzyme is capable of sensing chemical microenvironments to affect the epigenetic states of cells.

Project description:Histone H3 monoaminylations at glutamine(Q) 5 represent important epigenetic markers in neurons that play critical roles in the mediation of permissive gene expression. We previously demonstrated that H3Q5 serotonylation(ser) and dopaminylation(dop) are catalyzed by the Transglutaminase 2 (TGM2) enzyme. Here, we identified a new class of histone monoaminylation, H3Q5 histaminylation(his), which displayed dynamic diurnal expression in brain and contributed to neural rhythmicity. We found that H3Q5his, unlike H3Q5ser, electrostatically inhibited recruitment of the “reader” protein WDR5 and attenuated MLL1 methyltransferase activity on H3 lysine(K) 4. We determined that H3Q5 monoaminylation dynamics are dictated by local monoamine concentrations, which are sensed by TGM2. This noncanonical mechanism indicated that histone monoaminylations can be established and removed by a single enzyme based upon its sensing of cellular microenvironments.

Project description:A single enzyme, TGM2, bidirectionally controls H3 monoaminylation dynamics, which, in turn, facilitate neural rhythmicity

Project description:A single enzyme, TGM2, bidirectionally controls H3 monoaminylation dynamics, which, in turn, facilitate neural rhythmicity

Project description:Tissue-specific gene expression requires coordinated control of gene-proximal and distal cis-regulatory elements (CREs), yet functional analysis of putative gene-distal CREs such as enhancers remains challenging. Here we describe enhanced CRISPR/dCas9-based epigenetic editing systems, enCRISPRa and enCRISPRi, for multiplexed analysis of enhancer function in situ and in vivo. Using dual effector proteins capable of re-writing enhancer-associated chromatin modifications, we show that enCRISPRa and enCRISPRi modulate gene transcription by remodeling local epigenetic landscapes at sgRNA-targeted enhancers and associated genes. Comparing with existing methods, our systems display more robust and specific perturbations of gene transcription with minimal off-targets. Allele-specific targeting of enCRISPRa to oncogenic TAL1 super-enhancer modulates TAL1 expression and cancer progression in xenotransplants. Furthermore, multiplexed perturbations of lineage-specific enhancers in an enCRISPRi knock-in mouse establish in vivo evidence for lineage-restricted requirement of developmentally regulated enhancers during hematopoietic lineage specification. Hence, enhanced CRSIPR epigenetic editing provides opportunities for interrogating enhancer function in development and disease.

Project description:Tissue-specific gene expression requires coordinated control of gene-proximal and distal cis-regulatory elements (CREs), yet functional analysis of putative gene-distal CREs such as enhancers remains challenging. Here we describe enhanced CRISPR/dCas9-based epigenetic editing systems, enCRISPRa and enCRISPRi, for multiplexed analysis of enhancer function in situ and in vivo. Using dual effector proteins capable of re-writing enhancer-associated chromatin modifications, we show that enCRISPRa and enCRISPRi modulate gene transcription by remodeling local epigenetic landscapes at sgRNA-targeted enhancers and associated genes. Comparing with existing methods, our systems display more robust and specific perturbations of gene transcription with minimal off-targets. Allele-specific targeting of enCRISPRa to oncogenic TAL1 super-enhancer modulates TAL1 expression and cancer progression in xenotransplants. Furthermore, multiplexed perturbations of lineage-specific enhancers in an enCRISPRi knock-in mouse establish in vivo evidence for lineage-restricted requirement of developmentally regulated enhancers during hematopoietic lineage specification. Hence, enhanced CRSIPR epigenetic editing provides opportunities for interrogating enhancer function in development and disease.

Project description:Tissue-specific gene expression requires coordinated control of gene-proximal and distal cis-regulatory elements (CREs), yet functional analysis of putative gene-distal CREs such as enhancers remains challenging. Here we describe enhanced CRISPR/dCas9-based epigenetic editing systems, enCRISPRa and enCRISPRi, for multiplexed analysis of enhancer function in situ and in vivo. Using dual effector proteins capable of re-writing enhancer-associated chromatin modifications, we show that enCRISPRa and enCRISPRi modulate gene transcription by remodeling local epigenetic landscapes at sgRNA-targeted enhancers and associated genes. Comparing with existing methods, our systems display more robust and specific perturbations of gene transcription with minimal off-targets. Allele-specific targeting of enCRISPRa to oncogenic TAL1 super-enhancer modulates TAL1 expression and cancer progression in xenotransplants. Furthermore, multiplexed perturbations of lineage-specific enhancers in an enCRISPRi knock-in mouse establish in vivo evidence for lineage-restricted requirement of developmentally regulated enhancers during hematopoietic lineage specification. Hence, enhanced CRSIPR epigenetic editing provides opportunities for interrogating enhancer function in development and disease.

Project description:Histone dopaminylation is a newly identified epigenetic mark that plays a role in the regulation of gene transcription, where an isopeptide bond is formed between the fifth amino acid residue of H3 (i.e., glutamine) and dopamine. In our previous studies, we discovered that the dynamics of this post-translational modification (including installation, removal, and replacement) were regulated by a single enzyme, transglutaminase 2 (TGM2), through reversible transamination. Recently, we developed a chemical probe to specifically label and enrich histone dopaminylation via bioorthogonal chemistry.

Project description:We have determined methylation state differences in the epigenomes of neutrophils purified from human and chimpanzee. We used deep sequencing of ends generated by digestion with a methylation-sensitive restriction enzyme, followed by analysis with the MetMap computational pipeline to infer methylation states from the sequencing data. Using the orangutan as an outgroup, analysis of DNA sequence substitutions in CG-dense regions that are either methylated or unmethylated in all three species indicates that methylation states in the neutrophil reflect methylation states in the germline. Differences in methylation states were not correlated with differences in the local genomic sequences, indicating that they can be determined independently of local DNA sequence. Methylation differences were not distributed randomly among the individuals we analyzed, but recapitulated the known phylogenetic relationships of the three species in a pattern consistent with their stable inheritance. This data provide the first comprehensive dataset indicating that epigenetic states are maintained as independent characters that are predictably transmitted within species. Heritable epigenetic differences such as those we have identified could readily have functional and adaptive consequences, and contribute to the phenotypic divergence of human and chimpanzee. Comparison of methylation states in a single, uncultered cell type from human and chimpanzee

Project description:Nucleosomal incorporation of specialized histone variants is an important mechanism to generate different functional chromatin states. Here we report the identification and characterization of two novel primate-specific histone H3 variants, H3.X and H3.Y. Their mRNAs are found in certain human cell lines, in addition to several normal and malignant human tissues. In keeping with their primate-specificity, H3.X and H3.Y are detected in different brain regions. Transgenic H3.X and H3.Y proteins are stably incorporated into chromatin in a similar fashion to the known H3 variants. Importantly, we demonstrate biochemically and by mass spectrometry that endogenous posttranslationally modified H3.Y protein exists in vivo, and that stress-stimuli, such as starvation and cellular density, increase the abundance of H3.Y-expressing cells. Global transcriptome analysis revealed that knock-down of H3.Y affects cell growth and leads to changes in the expression of many genes involved in cell cycle control. Thus, H3.Y is a novel histone variant involved in the regulation of cellular responses to outside stimuli. Total RNA samples from human U2OS cells. Transcript levels after luciferase, H3.X and/or H3.Y RNAi was analyzed.