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1. Modified Histone Peptides Linked to Magnetic Beads Reduce Binding Specificity

   https://doi.org/10.3390/ijms23031691  

   Meanor, Jenna N.; Keung, Albert J.; Rao, Balaji M. (February 2022, International Journal of Molecular Sciences)

   Histone post-translational modifications are small chemical changes to the histone protein structure that have cascading effects on diverse cellular functions. Detecting histone modifications and characterizing their binding partners are critical steps in understanding chromatin biochemistry and have been accessed using common reagents such as antibodies, recombinant assays, and FRET-based systems. High-throughput platforms could accelerate work in this field, and also could be used to engineer de novo histone affinity reagents; yet, published studies on their use with histones have been noticeably sparse. Here, we describe specific experimental conditions that affect binding specificities of post-translationally modified histones in classic protein engineering platforms and likely explain the relative difficulty with histone targets in these platforms. We also show that manipulating avidity of binding interactions may improve specificity of binding. 

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2. Nucleosome context regulates chromatin reader preference

   https://doi.org/10.1101/2025.04.29.651129  

   Marunde, Matthew R; Popova, Irina K; Hall, Nathan W; Vaidya, Anup; Bone, James R; Boone, Brandon A; Brown, Peter J; Ezell, Ryan J; Firestone, Tessa M; Fuchs, Harrison A; et al (April 2025, bioRxiv)

   ABSTRACT Chromatin is more than a simple genome packaging system, and instead locally distinguished by histone post-translational modifications (PTMs) that can directly change nucleosome structure and / or be “read” by chromatin-associated proteins to mediate downstream events. An accurate understanding of histone PTM binding preference is vital to explain normal function and pathogenesis, and has revealed multiple therapeutic opportunities. Such studies most often use histone peptides, even though these cannot represent the full regulatory potential of nucleosome context. Here we apply a range of complementary and easily adoptable biochemical and genomic approaches to interrogate fully defined peptide and nucleosome targets with a diversity of mono or multivalent chromatin readers. In the resulting data, nucleosome context consistently refined reader binding, and multivalent engagement was more often regulatory than simply additive. This included abrogating the binding of the Polycomb group L3MBTL1 MBT to histone tails with lower methyl states (me1 or me2 at H3K4, H3K9, H3K27, H3K36 or H4K20); and confirmation that the CBX7 chromodomain and AT-hook-like motif (CD-ATL) tandem act as a functional unit to confer specificity for H3K27me3. Further,in vitronucleosome preferences were confirmed byin vivoreader-CUT&RUN genomic mapping. Such data confirms that more representative chromatin substrates provide greater insight to biological mechanism and its disorder in human disease. 

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3. Direct histone proteoform profiling of the unannotated, endangered coral Acropora cervicornis

   https://doi.org/10.1093/nar/gkaf740  

   Fuller, Cassandra N.; Mansoor, Sabrina; Jeanne Dit Fouque, Kevin; Tose, Lilian Valadares; Rodriguez-Casariego, Javier; Kosmopoulou, Mariangela; Suckau, Detlev; de Luna Vitorino, Francisca N.; Garcia, Benjamin A.; Eirin-Lopez, Jose M.; et al (July 2025, Nucleic Acids Research)

   Abstract Epigenetic modifications directly regulate the patterns of gene expression by altering DNA accessibility and chromatin structure. A knowledge gap is presented by the need to directly measure these modifications, especially for unannotated organisms with unknown primary histone sequences. In the present work, we developed and applied a novel workflow for identifying and annotating histone proteoforms directly from mass spectrometry-based measurements for the endangered Caribbean coral Acropora cervicornis. Combining high-accuracy de novo top-down and bottom-up analysis based on tandem liquid chromatography, trapped ion mobility spectrometry, non-ergodic electron-based fragmentation, and high-resolution mass spectrometry, near complete primary sequence (up to 99%) and over 86 post-translational modification annotations were obtained from pull-down histone fractions. In the absence of reliable genome annotations, H2A, H2B, and H4 histone sequences and the annotation of the post-translational modifications of the stressed A. cervicornis coral allow for a better understanding of chromatin remodeling and new strategies for targeting intervention and restoration of endangered reef corals. 

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4. High-resolution analysis of human centromeric chromatin

   https://doi.org/10.26508/lsa.202402819  

   Melters, Daniël P; Bui, Minh; Rakshit, Tatini; Grigoryev, Sergei A; Sturgill, David; Dalal, Yamini (January 2025, Life Science Alliance)

   Centromeres are marked by the centromere-specific histone H3 variant CENP-A/CENH3. Throughout the cell cycle, the constitutive centromere-associated network is bound to CENP-A chromatin, but how this protein network modifies CENP-A nucleosome conformations in vivo is unknown. Here, we purify endogenous centromeric chromatin associated with the CENP-C complex across the cell cycle and analyze the structures by single-molecule imaging and biochemical assays. CENP-C complex–bound chromatin was refractory to MNase digestion. The CENP-C complex increased in height throughout the cell cycle culminating in mitosis, and the smaller CENP-C complex corresponds to the dimensions of in vitro reconstituted constitutive centromere-associated network. In addition, we found two distinct CENP-A nucleosomal configurations; the taller variant was associated with the CENP-C complex. Finally, CENP-A mutants partially corrected CENP-C overexpression–induced centromeric transcription and mitotic defects. In all, our data support a working model in which CENP-C is critical in regulating centromere homeostasis by supporting a unique higher order structure of centromeric chromatin and altering the accessibility of the centromeric chromatin fiber for transcriptional machinery. 

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5. PTMViz: a tool for analyzing and visualizing histone post translational modification data

   https://doi.org/10.1186/s12859-021-04166-9  

   Chappell, Kevin; Graw, Stefan; Washam, Charity L.; Storey, Aaron J.; Bolden, Chris; Peterson, Eric C.; Byrum, Stephanie D. (May 2021, BMC Bioinformatics)

   Abstract BackgroundHistone post-translational modifications (PTMs) play an important role in our system by regulating the structure of chromatin and therefore contribute to the regulation of gene and protein expression. Irregularities in histone PTMs can lead to a variety of different diseases including various forms of cancer. Histone modifications are analyzed using high resolution mass spectrometry, which generate large amounts of data that requires sophisticated bioinformatics tools for analysis and visualization. PTMViz is designed for downstream differential abundance analysis and visualization of both protein and/or histone modifications. ResultsPTMViz provides users with data tables and visualization plots of significantly differentiated proteins and histone PTMs between two sample groups. All the data is packaged into interactive data tables and graphs using the Shiny platform to help the user explore the results in a fast and efficient manner to assess if changes in the system are due to protein abundance changes or epigenetic changes. In the example data provided, we identified several proteins differentially regulated in the dopaminergic pathway between mice treated with methamphetamine compared to a saline control. We also identified histone post-translational modifications including histone H3K9me, H3K27me3, H4K16ac, and that were regulated due to drug exposure. ConclusionsHistone modifications play an integral role in the regulation of gene expression. PTMViz provides an interactive platform for analyzing proteins and histone post-translational modifications from mass spectrometry data in order to quickly identify differentially expressed proteins and PTMs. 

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