Epigenetic chromatin modification by amber suppression technology

The genetic incorporation of unnatural amino acids (UAAs) into proteins by amber suppression technology provides unique avenues to study protein structure, function and interactions both in vitro and in living cells and organisms. This approach has been particularly useful for studying mechanisms of epigenetic chromatin regulation, since these extensively involve dynamic changes in structure, complex formation and posttranslational modifications that are difficult to access by traditional approaches. Here, we review recent achievements in this field, emphasizing UAAs that help to unravel protein-protein interactions in cells by photo-crosslinking or that allow the biosynthesis of proteins with defined posttranslational modifications for studying their function and turnover in vitro and in cells

Programmable protein-DNA crosslinking for the direct capture and quantification of 5-formylcytosine

5-Formylcytosine (5fC) is an epigenetic nucleobase of mammalian genomes that occurs as intermediate of active DNA demethylation. 5fC uniquely interacts and reacts with key nuclear proteins, indicating functions in genome regulation. Transcription-activator-like effectors (TALEs) are repeat-based DNA binding proteins that can serve as probes for the direct, programmable recognition and analysis of epigenetic nucleobases. However, no TALE repeats for the selective recognition of 5fC are available, and the typically low genomic levels of 5fC represent a particular sensitivity challenge. We here advance TALEbased nucleobase targeting from recognition to covalent crosslinking. We report TALE repeats bearing the ketoneamino acid p-acetylphenylalanine (pAcF) that universally bind all mammalian cytosine nucleobases, but selectively form diaminooxy-linker-mediated dioxime crosslinks to 5fC. We identify repeat-linker combinations enabling single CpG resolution, and demonstrate the direct quantification of 5fC levels in a human genome background by covalent enrichment. This strategy provides a new avenue to expand the application scope of programmable probes with selectivity beyond A, G, T and C for epigenetic studies

Light‐activatable MBD‐readers of 5‐methylcytosine reveal domain‐dependent chromatin association kinetics in vivo

5-Methylcytosine (5mC) is the central epigenetic mark of mammalian DNA, and plays fundamental roles in chromatin regulation. 5mC is dynamically read and translated into regulatory outputs by methyl-CpG-binding domain (MBD) proteins. These multidomain readers recognize 5mC via an MBD domain, and undergo additional domain-dependent interactions with multiple additional chromatin components. However, studying this dynamic process is limited by a lack of methods to conditionally control the 5mC affinity of MBD readers in cells. Light-control of MBD association to chromatin by genetically encoding a photocaged serine at the MBD-DNA interface is reported. The authors study the association of MBD1 to mouse pericentromeres, dependent on its CxxC3 and transcriptional repressor domains (TRD) which interact with unmethylated CpG and heterochromatin-associated complexes, respectively. Both domains significantly modulate association kinetics, arguing for a model in which the CxxC3 delays methylation responses of MBD1 by holding it at unmethylated loci, whereas the TRD promotes responses by aiding heterochromatin association is studied. Their approach offers otherwise inaccessible kinetic insights into the domain-specific regulation of a central MBD reader, and sets the basis for further unravelling how the integration of MBDs into complex heterochromatin interaction networks control the kinetics of 5mC reading and translation into altered chromatin states

Programmable Protein-DNA Crosslinking for the Direct Capture and Quantification of 5-Formylcytosine

5-Formylcytosine (5fC) is an epigenetic nucleobase of mammalian genomes that occurs as intermediate of active DNA demethylation. 5fC uniquely interacts and reacts with key nuclear proteins, indicating functions in genome regulation. Transcription-activator-like effectors (TALEs) are repeat-based DNA binding proteins that can serve as probes for the direct, programmable recognition and analysis of epigenetic nucleobases. However, no TALE repeats for the selective recognition of 5fC are available, and the typically low genomic levels of 5fC represent a particular sensitivity challenge. We here advance TALE-based nucleobase targeting from recognition to covalent cross-linking. We report TALE repeats bearing the ketone-amino acid p-acetylphenylalanine (pAcF) that universally bind all mammalian cytosine nucleobases, but selectively form diaminooxy-linker-mediated dioxime cross-links to 5fC. We identify repeat-linker combinations enabling single CpG resolution, and demonstrate the direct quantification of 5fC levels in a human genome background by covalent enrichment. This strategy provides a new avenue to expand the application scope of programmable probes with selectivity beyond A, G, T and C for epigenetic studies

Engineered TALE repeats for enhanced imaging-based analysisof cellular 5-Methylcytosine

Two‐TALE test: Engineered transcription‐activator‐like effector (TALE) repeats can be used to design programmable receptors for improved in situ imaging‐based analysis of 5 mC in user‐defined DNA sequences. Pairs of natural 5 mC‐discriminating and engineered 5 mC‐binding TALEs allow nucleotide resolution analysis of 5 mC with response of both TALEs. This provides an impulse for the design of programmable imaging probes for studying 5 mC functions in chromatin regulation with increased dynamic range

Light-activatable TET-dioxygenases reveal dynamics of 5-Methylcytosine oxidation and transcriptome reorganization

Ten-eleven-translocation (TET) dioxygenases catalyze the oxidation of 5-methylcytosine (5mC), the central epigenetic regulator of mammalian DNA. This activity dy- namically reshapes epigenome and transcriptome by deposit- ing oxidized 5mC derivatives, and initiating active DNA de- methylation. However, studying this dynamic is hampered by the inability to selectively activate individual TETs with tem- poral control in cells. We report activation of TETs in mam- malian cells by incorporation of genetically encoded 4,5- dimethoxy-2-nitrobenzyl-L-serine as transient active site block, and its subsequent deprotection with light. Our ap- proach enables precise insights into the impact of cancer- associated TET2 mutations on the kinetics of TET2 catalysis in vivo, and allows time-resolved monitoring of target gene activation and transcriptome reorganization. This sets a basis for dissecting the order and kinetics of chromatin-associated events triggered by TET catalysis, ranging from DNA de- methylation to chromatin and transcription regulation

Light-Activatable TET-Dioxygenases Reveal Dynamics of 5-Methylcytosine Oxidation and Transcriptome Reorganization

Ten-eleven-translocation (TET) dioxygenases catalyze the oxidation of 5-methylcytosine (5mC), the central epigenetic regulator of mammalian DNA. This activity dynamically reshapes the epigenome and transcriptome by depositing oxidized 5mC derivatives and initiating active DNA demethylation. However, studying this dynamic is hampered by the inability to selectively activate individual TETs with temporal control in cells. We report activation of TETs in mammalian cells by incorporation of genetically encoded 4,5-dimethoxy-2-nitrobenzyl-l-serine as a transient active-site block, and its subsequent deprotection with light. Our approach enables precise insights into the impact of cancer-associated TET2 mutations on the kinetics of TET2 catalysis in vivo, and allows time-resolved monitoring of target gene activation and transcriptome reorganization. This sets a basis for dissecting the order and kinetics of chromatin-associated events triggered by TET catalysis, ranging from DNA demethylation to chromatin and transcription regulation

Light-activation of DNA-methyltransferases

5-Methylcytosine (5mC), the central epigenetic mark of mammalian DNA, plays fundamental roles in chromatin regulation. 5mC is written onto genomes by DNA methyltransferases (DNMT), and perturbation of this process is an early event in carcinogenesis. However, studying 5mC functions is limited by the inability to control individual DNMTs with spatiotemporal resolution in vivo. We report light-control of DNMT catalysis by genetically encoding a photocaged cysteine as a catalytic residue. This enables translation of inactive DNMTs, their rapid activation by light-decaging, and subsequent monitoring of de novo DNA methylation. We provide insights into how cancer-related DNMT mutations alter de novo methylation in vivo, and demonstrate local and tuneable cytosine methylation by light-controlled DNMTs fused to a programmable transcription activator-like effector domain targeting pericentromeric satellite-3 DNA. We further study early events of transcriptome alterations upon DNMT-catalyzed cytosine methylation. Our study sets a basis to dissect the order and kinetics of diverse chromatin-associated events triggered by normal and aberrant DNA methylation

Designer receptors for nucleotide-resolution analysis of genomic 5-Methylcytosine by cellular imaging

We report programmable receptors for the imaging-based analysis of 5-methylcytosine (5mC) in user-defined DNA sequences of single cells. Using fluorescent transcription-activator-like effectors (TALEs) that can recognize sequences of canonical and epigenetic nucleobases through selective repeats, we imaged cellular SATIII DNA, the origin of nuclear stress bodies (nSB). We achieve high nucleobase selectivity of natural repeats in imaging and demonstrate universal nucleobase binding by an engineered repeat. We use TALE pairs differing in only one such repeat in co-stains to detect 5mC in SATIII sequences with nucleotide resolution independently of differences in target accessibility. Further, we directly correlate the presence of heat shock factor 1 with 5mC at its recognition sequence, revealing a potential function of 5mC in its recruitment as initial step of nSB formation. This opens a new avenue for studying 5mC functions in chromatin regulation in situ with nucleotide, locus, and cell resolution

A high-throughput effector screen identifies a novel small molecule scaffold for inhibition of ten-eleven translocation dioxygenase 2

Ten-eleven translocation dioxygenases (TETs) are the erasers of 5-methylcytosine (mC), the central epigenetic regulator of mammalian DNA. TETs convert mC to three oxidized derivatives with unique physicochemical properties and inherent regulatory potential, and it initializes active demethylation by the base excision repair pathway. Potent small molecule inhibitors would be useful tools to study TET functions by conditional control. To facilitate the discovery of such tools, we here report a high-throughput screening pipeline and its application to screen and validate 31.5k compounds for inhibition of TET2. Using a homogenous fluorescence assay, we discover a novel quinoline-based scaffold that we further validate with an orthogonal semi-high throughput MALDI-MS assay for direct monitoring of substrate turnover. Structure–activity relationship (SAR) studies involving >20 derivatives of this scaffold led to the identification of optimized inhibitors, and together with computational studies suggested a plausible model for its mode of action