Design, Construction, and Validation of Histone-Binding Effectors <i>in Vitro</i> and in Cells

Tekel, Stefan J.; Barrett, Cassandra; Vargas, Daniel A.; Haynes, Karmella A.

doi:10.1021/acs.biochem.8b00327

Cited by 7 publications

(9 citation statements)

References 35 publications

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“…2011). Although binding affinities for their targets are often lower than those of antibodies (Kungulovski et al, 2014), reader domains have known sequences and thus can be evolved to improve affinity and specificity (Tekel et al, 2018). Similarly, fluorescent modification-specific intracellular antibodies (mintbodies) are small, GFP-tagged, single-chain variable fragments that can be expressed in vivo to allow live imaging of histone modification dynamics spatiotemporally (Sato et al, 2013) (Fig.…”

Section: Classical Methods For Measuring Histone Modificationsmentioning

confidence: 99%

Mapping chromatin modifications at the single cell level

Ludwig

Bintu

2019

Development

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Understanding chromatin regulation holds enormous promise for controlling gene regulation, predicting cellular identity, and developing diagnostics and cellular therapies. However, the dynamic nature of chromatin, together with cell-to-cell heterogeneity in its structure, limits our ability to extract its governing principles. Single cell mapping of chromatin modifications, in conjunction with expression measurements, could help overcome these limitations. Here, we review recent advances in single cell-based measurements of chromatin modifications, including optimization to reduce DNA loss, improved DNA sequencing, barcoding, and antibody engineering. We also highlight several applications of these techniques that have provided insights into cell-type classification, mapping modification co-occurrence and heterogeneity, and monitoring chromatin dynamics.

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Section: Classical Methods For Measuring Histone Modificationsmentioning

confidence: 99%

Mapping chromatin modifications at the single cell level

Ludwig

Bintu

2019

Development

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“…We constructed mammalian expression vector 14 (MV14) for the overexpression of Gal4-mCherry-AAP fusion proteins in-frame with a nuclear localization sequence and 6X-histidine tag. First, plasmid MV13 was built by inserting a Gal4-mCherry fragment into MV10 [100] directly downstream of the CMV promoter. Next, MV14 was built by inserting a SpeI/PstlI (FastDigest enzymes, ThermoFisher Scientific) -digested gBlock Gene Fragment (Integrated DNA Technologies), which encoded a XbaI/NotI multiple cloning site, into MV13 downstream of mCherry.…”

Section: Construction Of Mv14 and Gal4-aap Plasmidsmentioning

confidence: 99%

“…Luciferase assays were performed as previously described in Tekel et al [100]. In brief, a single well of cells from a 12 well tissue culture plate was collected per independent transfection in 1.5mL 1× PBS.…”

Section: Luciferase Assaysmentioning

confidence: 99%

Components from the Human c-myb Transcriptional Regulation System Reactivate Epigenetically Repressed Transgenes

Barrett

McCracken

Elmer

et al. 2020

IJMS

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A persistent challenge for mammalian cell engineering is the undesirable epigenetic silencing of transgenes. Foreign DNA can be incorporated into closed chromatin before and after it has been integrated into a host cell’s genome. To identify elements that mitigate epigenetic silencing, we tested components from the c-myb and NF-kB transcriptional regulation systems in transiently transfected DNA and at chromosomally integrated transgenes in PC-3 and HEK 293 cells. DNA binding sites for MYB (c-myb) placed upstream of a minimal promoter enhanced expression from transiently transfected plasmid DNA. We targeted p65 and MYB fusion proteins to a chromosomal transgene, UAS-Tk-luciferase, that was silenced by ectopic Polycomb chromatin complexes. Transient expression of Gal4-MYB induced an activated state that resisted complete re-silencing. We used custom guide RNAs and dCas9-MYB to target MYB to different positions relative to the promoter and observed that transgene activation within ectopic Polycomb chromatin required proximity of dCas9-MYB to the transcriptional start site. Our report demonstrates the use of MYB in the context of the CRISPR-activation system, showing that DNA elements and fusion proteins derived from c-myb can mitigate epigenetic silencing to improve transgene expression in engineered cell lines.

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“…[20][21][22][23][24][25][26] Reader protein families have evolved to be site-specific binders of different histone PTMs, and the mechanisms by which reader domains recognize these marks are generally well characterized. 27 The recognition capability of reader scaffolds has been exploited to enrich chromatin samples for mass spectrometry analysis 26,28 , to generate artificial histone PTM-dependent transcriptional activators 29,30 , to visualize multiple PTMs simultaneously in stem cells 31 , and to employ histone interacting domains in chromatin immunoprecipitation assays. 21,22,32,33 While the utilization of reader domains as tools has promising potential given their small size and evolved specificity, a major limitation is the generally weak dissociation constants for their respective PTM ligands, often in the midmicromolar range.…”

Section: Graphical Abstractmentioning

confidence: 99%

Engineered Reader Proteins for Enhanced Detection of Methylated Lysine on Histones

et al. 2019

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Histone post-translational modifications (PTMs) are crucial for many cellular processes including mitosis, transcription, and DNA repair. The cellular readout of histone PTMs is dependent on both the chemical modification and histone site, and the array of histone PTMs on chromatin is dynamic throughout the eukaryotic life cycle. Accordingly, methods that report on the presence of PTMs are essential tools for resolving open questions about epigenetic processes and for developing therapeutic diagnostics. Reader domains that recognize histone PTMs have shown potential as advantageous substitutes for anti-PTM antibodies and engineering efforts aimed at enhancing reader domain affinities would advance their efficacy as antibody alternatives. Here we describe engineered chromodomains from D. melanogaster and humans that bind more tightly to H3K9 methylation (H3K9me) marks and result in the tightest reported reader:H3K9me interaction to date. Point mutations near the binding interface of the HP1 chromodomain were screened in a combinatorial fashion, and a triple mutant was found that binds 20-fold tighter than the native scaffold without any loss in PTM-site selectivity. The beneficial mutations were then translated to a human homolog, CBX1, resulting in an even tighter interaction with H3K9me3. Furthermore, we show that these engineered readers (eReaders) increase detection of H3K9me marks in several biochemical assays and outperform a commercial anti-H3K9me antibody in detecting H3K9me-*

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Design, Construction, and Validation of Histone-Binding Effectors in Vitro and in Cells

Cited by 7 publications

References 35 publications

Mapping chromatin modifications at the single cell level

Mapping chromatin modifications at the single cell level

Components from the Human c-myb Transcriptional Regulation System Reactivate Epigenetically Repressed Transgenes

Engineered Reader Proteins for Enhanced Detection of Methylated Lysine on Histones

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