Your search keyword '"Adewola Osunsade"' showing total 13 results

1. Chromatin sequesters pioneer transcription factor Sox2 from exerting force on DNA

Author

Tuan Nguyen, Sai Li, Jeremy T-H Chang, John W. Watters, Htet Ng, Adewola Osunsade, Yael David, and Shixin Liu

Subjects

Science

Abstract

Here the authors used single-molecule imaging and manipulation to study the mechanical effects of transcription factor Sox2 co-condensation with DNA and chromatin. They found that Sox2 condensates exert a high level of mechanical stress on DNA, but this stress is dramatically attenuated by nucleosomes assembled on the DNA.

Published

2022

2. Protein arginine deiminase 4 antagonizes methylglyoxal-induced histone glycation

Author

Qingfei Zheng, Adewola Osunsade, and Yael David

Subjects

Science

Abstract

Protein arginine deiminase 4 (PAD4) facilitates the posttranslational citrullination of histones H3 and H4. Here, the authors provide evidence that PAD4 antagonizes histone methylglyoxal-glycation by rewriting the glycated arginine into citrulline and protecting the reactive sites from further glycation.

Published

2020

3. Reversible histone glycation is associated with disease-related changes in chromatin architecture

Author

Qingfei Zheng, Nathaniel D. Omans, Rachel Leicher, Adewola Osunsade, Albert S. Agustinus, Efrat Finkin-Groner, Hannah D’Ambrosio, Bo Liu, Sarat Chandarlapaty, Shixin Liu, and Yael David

Subjects

Science

Abstract

Proteins continuously undergo non-enzymatic modifications such as glycation, which accumulate under physiological conditions but can be enhanced in disease. Here the authors characterise histone glycation, provide evidence that it affects chromatin, particularly in breast cancer, and identify DJ-1 as a deglycase.

Published

2019

4. Histone H1 loss drives lymphoma by disrupting 3D chromatin architecture

Author

Ethel Cesarman, Ashley S. Doane, Andreas Kloetgen, Joseph Conway, Jeannie M. Camarillo, Olivier Elemento, Neil L. Kelleher, Stephanie Portillo-Ledesma, Adewola Osunsade, Christopher E. Mason, Bryan J. Venters, Ari Melnick, Yael David, Alexey A. Soshnev, Tamar Schlick, Marcin Imielinski, David Scott, Aristotelis Tsirigos, Christopher R. Chin, Wendy Béguelin, Eftychia Apostolou, Arthur I. Skoultchi, Jonathan D. Licht, C. David Allis, Louis M. Staudt, Jude M. Phillip, Nevin Yusufova, Michael-Christopher Keogh, and Matt Teater

Subjects

0301 basic medicine, Lymphoma, medicine.disease_cause, Article, Epigenesis, Genetic, Histones, 03 medical and health sciences, Histone H3, Mice, 0302 clinical medicine, Histone H1, medicine, Nucleosome, Animals, Humans, Genes, Tumor Suppressor, Epigenetics, Gene Silencing, Cell Self Renewal, Alleles, Regulation of gene expression, Mutation, B-Lymphocytes, Multidisciplinary, biology, Stem Cells, Chromatin Assembly and Disassembly, Germinal Center, Chromatin, Cell biology, Gene Expression Regulation, Neoplastic, 030104 developmental biology, Histone, Cell Transformation, Neoplastic, 030220 oncology & carcinogenesis, biology.protein

Abstract

Linker histone H1 proteins bind to nucleosomes and facilitate chromatin compaction1, although their biological functions are poorly understood. Mutations in the genes that encode H1 isoforms B–E (H1B, H1C, H1D and H1E; also known as H1-5, H1-2, H1-3 and H1-4, respectively) are highly recurrent in B cell lymphomas, but the pathogenic relevance of these mutations to cancer and the mechanisms that are involved are unknown. Here we show that lymphoma-associated H1 alleles are genetic driver mutations in lymphomas. Disruption of H1 function results in a profound architectural remodelling of the genome, which is characterized by large-scale yet focal shifts of chromatin from a compacted to a relaxed state. This decompaction drives distinct changes in epigenetic states, primarily owing to a gain of histone H3 dimethylation at lysine 36 (H3K36me2) and/or loss of repressive H3 trimethylation at lysine 27 (H3K27me3). These changes unlock the expression of stem cell genes that are normally silenced during early development. In mice, loss of H1c and H1e (also known as H1f2 and H1f4, respectively) conferred germinal centre B cells with enhanced fitness and self-renewal properties, ultimately leading to aggressive lymphomas with an increased repopulating potential. Collectively, our data indicate that H1 proteins are normally required to sequester early developmental genes into architecturally inaccessible genomic compartments. We also establish H1 as a bona fide tumour suppressor and show that mutations in H1 drive malignant transformation primarily through three-dimensional genome reorganization, which leads to epigenetic reprogramming and derepression of developmentally silenced genes. Mutations in histone H1 induce the remodelling of chromatin architecture to a more relaxed state, which leads to malignant transformation through changes in histone modifications and the expression of stem cell genes.

Published

2020

5. Single-stranded nucleic acid binding and coacervation by linker histone H1

Author

Rachel Leicher, Adewola Osunsade, Gabriella N. L. Chua, Sarah C. Faulkner, Andrew P. Latham, John W. Watters, Tuan Nguyen, Emily C. Beckwitt, Sophia Christodoulou-Rubalcava, Paul G. Young, Bin Zhang, Yael David, and Shixin Liu

Subjects

Histones, Structural Biology, DNA, Single-Stranded, DNA, Molecular Biology, Article, Chromatin, Nucleosomes, Protein Binding

Abstract

The H1 linker histone family is the most abundant group of eukaryotic chromatin-binding proteins. However, their contribution to chromosome structure and function remains incompletely understood. Here we use single-molecule fluorescence and force microscopy to directly visualize the behavior of H1 on various nucleic acid and nucleosome substrates. We observe that H1 coalesces around single-stranded DNA generated from tension-induced DNA duplex melting. Using a droplet fusion assay controlled by optical tweezers, we find that single-stranded nucleic acids mediate the formation of gel-like H1 droplets, whereas H1-double-stranded DNA and H1-nucleosome droplets are more liquid-like. Molecular dynamics simulations reveal that multivalent and transient engagement of H1 with unpaired DNA strands drives their enhanced phase separation. Using eGFP-tagged H1, we demonstrate that inducing single-stranded DNA accumulation in cells causes an increase in H1 puncta that are able to fuse. We further show that H1 and Replication Protein A occupy separate nuclear regions, but that H1 colocalizes with the replication factor Proliferating Cell Nuclear Antigen, particularly after DNA damage. Overall, our results provide a refined perspective on the diverse roles of H1 in genome organization and maintenance, and indicate its involvement at stalled replication forks.

Published

2022

6. Chromatin sequesters pioneer transcription factor Sox2 from exerting force on DNA

Author

Tuan Nguyen, Sai Li, Jeremy T-H Chang, John W. Watters, Htet Ng, Adewola Osunsade, Yael David, and Shixin Liu

Subjects

Multidisciplinary, Gene Expression Regulation, fungi, General Physics and Astronomy, General Chemistry, DNA, General Biochemistry, Genetics and Molecular Biology, Chromatin, Nucleosomes, Transcription Factors

Abstract

Formation of biomolecular condensates constitutes an emerging mechanism for transcriptional regulation. Recent studies suggest that the co-condensation between transcription factors (TFs) and DNA can generate mechanical forces driving genome rearrangements. However, the reported forces generated by such protein-DNA co-condensation are typically below one piconewton (pN), questioning its physiological significance. Moreover, the force-generating capacity of these condensates in the chromatin context remains unknown. Using single-molecule biophysical techniques, we show that Sox2, a nucleosome-binding pioneer TF, forms co-condensates with DNA, thereby exerting considerable mechanical tension on DNA strands both in cis and trans. Sox2 can generate forces up to 7 pN—similar in magnitude to other cellular forces. Sox2:DNA condensates are highly stable, withstanding disruptive forces high enough to melt DNA. We find that the disordered domains of Sox2 are required for maximum force generation but not condensate formation per se. Finally, we show that nucleosomes dramatically attenuate the mechanical stress exerted by Sox2 via sequestering it from coalescing on bare DNA. Our findings reveal that TF-mediated DNA condensation can exert significant mechanical stress which can nonetheless be alleviated by the chromatin organization, suggesting a new function of eukaryotic chromatin in protecting the genome from potentially deleterious nuclear forces.

Published

2021

7. Single-stranded nucleic acid sensing and coacervation by linker histone H1

Author

Rachel Leicher, Adewola Osunsade, Gabriella N.L. Chua, Sarah C. Faulkner, Andrew P. Latham, John W. Watters, Tuan A. Nguyen, Emily C. Beckwitt, Sophia Christodoulou-Rubalcava, Paul G. Young, Bin Zhang, Yael David, and Shixin Liu

Subjects

Biophysics

Published

2022

8. Reversible histone glycation is associated with disease-related changes in chromatin architecture

Author

Rachel Leicher, Albert S Agustinus, Qingfei Zheng, Bo Liu, Yael David, Adewola Osunsade, Efrat Finkin-Groner, Hannah K. D'Ambrosio, Shixin Liu, Nathaniel D. Omans, and Sarat Chandarlapaty

Subjects

Glycation End Products, Advanced, 0301 basic medicine, Glycosylation, Science, Protein Deglycase DJ-1, General Physics and Astronomy, Breast Neoplasms, 02 engineering and technology, Article, General Biochemistry, Genetics and Molecular Biology, Epigenesis, Genetic, Histones, Pathogenesis, Mice, 03 medical and health sciences, Glycation, Cell Line, Tumor, Tumor Microenvironment, Animals, Humans, Nucleosome, Epigenetics, lcsh:Science, Epigenesis, Multidisciplinary, biology, Chemistry, Acetylation, General Chemistry, Pyruvaldehyde, 021001 nanoscience & nanotechnology, In vitro, Nucleosomes, 3. Good health, Cell biology, Chromatin, 030104 developmental biology, Histone, biology.protein, Heterografts, Female, lcsh:Q, 0210 nano-technology, Protein Processing, Post-Translational

Abstract

Cellular proteins continuously undergo non-enzymatic covalent modifications (NECMs) that accumulate under normal physiological conditions and are stimulated by changes in the cellular microenvironment. Glycation, the hallmark of diabetes, is a prevalent NECM associated with an array of pathologies. Histone proteins are particularly susceptible to NECMs due to their long half-lives and nucleophilic disordered tails that undergo extensive regulatory modifications; however, histone NECMs remain poorly understood. Here we perform a detailed analysis of histone glycation in vitro and in vivo and find it has global ramifications on histone enzymatic PTMs, the assembly and stability of nucleosomes, and chromatin architecture. Importantly, we identify a physiologic regulation mechanism, the enzyme DJ-1, which functions as a potent histone deglycase. Finally, we detect intense histone glycation and DJ-1 overexpression in breast cancer tumors. Collectively, our results suggest an additional mechanism for cellular metabolic damage through epigenetic perturbation, with implications in pathogenesis., Proteins continuously undergo non-enzymatic modifications such as glycation, which accumulate under physiological conditions but can be enhanced in disease. Here the authors characterise histone glycation, provide evidence that it affects chromatin, particularly in breast cancer, and identify DJ-1 as a deglycase.

Published

2019

9. A Robust Method for the Purification and Characterization of Recombinant Human Histone H1 Variants

Author

Yael David, Devin M Ray, Ivo C. Lorenz, Jakob M Hebert, Adewola Osunsade, Yazen Jmeian, and Nicholas A Prescott

Subjects

SUMO-1 Protein, Computational biology, Biology, Protein Engineering, Biochemistry, Article, Germline, law.invention, Histones, 03 medical and health sciences, Histone H1, Peptide Library, law, Transcription (biology), Escherichia coli, Humans, Micrococcal Nuclease, Peptide library, 0303 health sciences, Nucleosome binding, Circular Dichroism, 030302 biochemistry & molecular biology, Recombinant Proteins, Nucleosomes, Chromatin, Recombinant DNA, Electrophoresis, Polyacrylamide Gel, Linker

Abstract

Higher order compaction of the eukaryotic genome is key to the regulation of all DNA-templated processes, including transcription. This tightly controlled process involves the formation of mononucleosomes, the fundamental unit of chromatin, packaged into higher order architectures in an H1 linker histone-dependent process. While much work has been done to delineate the precise mechanism of this event in vitro and in vivo, major gaps still exist, primarily due to a lack of molecular tools. Specifically, there has never been a successful purification and biochemical characterization of all human H1 variants. Here we present a robust method to purify H1 and illustrate its utility in the purification of all somatic variants and one germline variant. In addition, we performed a first ever side-by-side biochemical comparison, which revealed a gradient of nucleosome binding affinities and compaction capabilities. These data provide new insight into H1 redundancy and lay the groundwork for the mechanistic investigation of disease-driving mutations.

Published

2018

10. Single-stranded nucleic acid sensing and coacervation by linker histone H1

Author

Bin Zhang, Chua Gnl, Christodoulou-Rubalcava S, Rachel Leicher, Watters Jw, Adewola Osunsade, David Y, Shixin Liu, and Andrew P. Latham

Subjects

Molecular dynamics, chemistry.chemical_compound, Coacervate, Histone H1, chemistry, Nucleic acid, Biophysics, Linker, Fluorescence, DNA, Genomic organization

Abstract

The linker histone H1 is the most abundant group of eukaryotic chromatin-binding proteins. The mechanism underlying the diverse physiological functions of H1 remains unclear. Here we used single-molecule fluorescence and force microscopy to observe the behavior of H1 on DNA under different tensions. Unexpectedly, we found that H1 coalesces around nascent ssDNA. Molecular dynamics simulations revealed that multivalent and transient interactions between H1 and ssDNA mediate their phase separation. We further showed that longer and unpaired nucleic acids result in more viscous, gel-like H1 droplets. Finally, we imaged H1 puncta in cells under normal and stressed conditions and observed that RPA and H1 occupy separate nuclear regions. Overall, our results provide a new perspective to understanding the role of H1 in genome organization and maintenance.

Published

2021

11. H1 histones control the epigenetic landscape by local chromatin compaction

Author

Yael David, Karin A. Skalina, Benjamin A. Garcia, Cary N. Weiss, Adewola Osunsade, Chul Hwan Lee, Yair Botbol, Jie Zhao, Ari Melnick, Michael A. Willcockson, Sean E. Healton, Fernando Macian, Ethel Cesarman, Winfried Edelmann, Harry Hou, Arthur I. Skoultchi, Hugo Pinto, Boris Bartholdy, Dhruv S. Sidhwani, Maxim I. Maron, Laura Norwood Toro, Tommy J. Wilson, Simone Sidoli, Nevin Yusufova, Laxmi N. Mishra, and Cem Meydan

Subjects

Lymphoma, T cell, Methylation, Article, Chromosome conformation capture, Histones, 03 medical and health sciences, 0302 clinical medicine, medicine, Nucleosome, Humans, Epigenetics, 030304 developmental biology, 0303 health sciences, Multidisciplinary, biology, Chemistry, Chromatin, Cell biology, Histone, medicine.anatomical_structure, 030220 oncology & carcinogenesis, biology.protein, PRC2

Abstract

H1 linker histones are the most abundant chromatin-binding proteins(1). In vitro studies indicate that their association with chromatin determines nucleosome spacing and enables arrays of nucleosomes to fold into more compact chromatin structures. However, the in vivo roles of H1 are poorly understood(2). Here we show that the local density of H1 controls the balance of repressive and active chromatin domains by promoting genomic compaction. We generated a conditional triple-H1-knockout mouse strain and depleted H1 in haematopoietic cells. H1 depletion in T cells leads to de-repression of T cell activation genes, a process that mimics normal T cell activation. Comparison of chromatin structure in normal and H1-depleted CD8(+) T cells reveals that H1-mediated chromatin compaction occurs primarily in regions of the genome containing higher than average levels of H1: the chromosome conformation capture (Hi-C) B compartment and regions of the Hi-C A compartment marked by PRC2. Reduction of H1 stoichiometry leads to decreased H3K27 methylation, increased H3K36 methylation, B-to-A-compartment shifting and an increase in interaction frequency between compartments. In vitro, H1 promotes PRC2-mediated H3K27 methylation and inhibits NSD2-mediated H3K36 methylation. Mechanistically, H1 mediates these opposite effects by promoting physical compaction of the chromatin substrate. Our results establish H1 as a critical regulator of gene silencing through localized control of chromatin compaction, 3D genome organization and the epigenetic landscape.

Published

2020

12. Tolerance of various biological species to triorganotins

Author

Rowan Far, Xueqing Song, James Ferguson, Hirut Yimer, George Eng, Jana Hoerner, Robert D. Pike, Joni Robinson, Stephanie Graves, Adewola Osunsade, Russell Knighton, and José H. Delao Hernández

Subjects

Triphenyltin chloride, biology, Chemistry, Stereochemistry, Ligand, Organic Chemistry, Infrared spectroscopy, Bacillus subtilis, biology.organism_classification, medicine.disease_cause, Adduct, Inorganic Chemistry, Trigonal bipyramidal molecular geometry, chemistry.chemical_compound, Materials Chemistry, medicine, Picoline, Escherichia coli

Abstract

Several triphenyltin chloride picoline N-oxide adducts were synthesized. X-ray studies of triphenyltin chloride 4- picoline N-oxide indicate that the adduct has a distorted trigonal bipyramid (TBP) configuration with the phenyl groups in the equatorial positions and the axial positions being occupied by the 4-picoline N-oxide ligand and chlorine atom. Structures of the other adducts are assumed to be similar based on the IR spectra. Multinuclear NMR studies indicated that the TBP configuration is lost in solution. Screening results of the adducts against Escherichia coli (E. coli) and Bacillus subtilis (B. subtilis) indicate that the E. coli were more tolerant to the adducts. In addition to the adducts, three other series of triorganotins that incorporated various modified fragments of pyrethroids were also tested against B. subtilis and E. coli. No common order of toxicity was observed for these compounds based on the organic group attached to the tin atom. In addition to the evaluation of the triphenyltin chloride adducts and modified triorganotins against the two bacteria, 12 commercial triorganotins were evaluated against a freshwater snail, Biomphalaria glabrata (B. glabrata). The screening results indicated that the bacteria are more tolerant to the triorganotins than B. glabrata.

Published

2014

13. Histone 1 Mutations Drive Lymphomagenesis By Inducing Primitive Stem Cell Functions and Epigenetic Instructions through Profound 3D Re-Organization of the B-Cell Genome

Author

Matthew R. Teater, Ethel Cesarman, Yael David, Adewola Osunsade, Ashley S. Doane, Aristotelis Tsirigos, Andreas Kloetgen, C. David Allis, Alexey A. Soshnev, Joseph Conway, Arthur I. Skoultchi, Ari Melnick, and Nevin Yusufova

Subjects

Mutation, biology, Immunology, Cell Biology, Hematology, medicine.disease_cause, Biochemistry, Chromatin, Cell biology, Chromosome conformation capture, Histone, Histone H1, biology.protein, medicine, Epigenetics, Stem cell, Reprogramming

Abstract

Somatic missense mutations in histone 1 genes occur in ~30% of follicular lymphomas and DLBCL and 85% of Hodgkin's lymphomas, with significant mutual co-occurrence among these alleles, most frequently involving H1C and H1E. We crossed constitutive H1C+/-H1E+/- mice with VavP-Bcl2 transgenic mice and observed significant acceleration of lymphomagenesis (p=0.0001). Lymphoma H1 mutations affect the H1 globular domain or C-terminus. We found that the globular domain mutants fail to insert into chromatin whereas C-ter mutants fail to compact chromatin as shown by atomic force microscopy, in vitro assembled nucleosome arrays, and FRET assays in live cells. Hence both types of mutation confer loss of function. Constitutive H1C/E knockout mice are healthy and have no overt phenotype. However, immunization with T-cell dependent antigen caused significant GC hyperplasia (p=0.013) and disruption of polarity due to expansion in the number of centrocytes. Notably, H1C/EDKO GC B-cells readily outcompeted WT GC B-cells in mixed chimera experiments indicating that they have superior fitness (p=0.0086). To understand the mechanism through which this occurs we performed RNA-seq in H1C/EDKO GC B-cells which revealed an aberrant gene expression signature composed almost entirely of transcriptional activation (n=721 upregulated and n=61 downregulated q=0.05, LFC=log(1.5)). Strikingly, these same genes are upregulated during induced pluripotency (iPS cell) reprogramming, and are normally silenced during early development by the PRC2 complex (p This prompted us to extensively characterize the epigenome of purified H1C/EDKO vs WT GC B-cells using High-throughput chromosome conformation capture (Hi-C), ATAC-seq, and ChIP-seq for multiple histone marks. From the topological standpoint the genome is distributed in two compartments: Compartment A, consisting of unpacked chromatin available for gene regulatory processes, and compartment B, which is highly packed, silenced and inaccessible. Beyond this organization, sets of genes are organized into boundary delimited domains called TADs that share regulatory information. Remarkably, the primary effect of H1 loss of function was the shifting of approximately 256 TADs from compartment B to compartment A (there was no A to B shift). These TADs manifested highly significant gain of chromatin accessibility by ATACs-seq and featured reciprocal loss of H3K27me3 and gain of H3K36me2. These "B to A" TADs yielded increased looping connectivity and contained the primitive stem cell genes that were upregulated. Indeed, B to A shifting enabled critical stem cell enhancers to interact with and activate various stem cell genes as shown by v4C (e.g. KLF5, PRDM5, MEIS1, etc). Most remarkably, the 3D architecture of H1C/H1EDKO GC B-cells was similar to that of intermediate stages of iPS cell reprogramming. Consistent with this finding, H1C/EDKO cells exhibited 4-fold greater reprogramming to the iPS state than WT cells after OKSM transduction, and these iPS cells exhibited reduced H3K27me3, stronger pluripotency potential, and impaired differentiation. This effect was rescued by transduction of WT H1, but not globular or C terminal domain mutant H1. Strikingly, the H1C/EDKO primitive stem cell gene expression signature was highly significantly enriched (NES 1.24, FDR Collectively, we find that H1 isoforms are bona fide lymphoma tumor suppressors. We speculate that H1 mutations are limited to GC derived lymphomas due to the stoichiometric need for H1 proteins in these rapidly dividing cells. To the best of our knowledge these are the first data to implicate disruption of topological packing order of chromatin as a cancer driver mechanism, as well as the first data to provide a mechanism whereby mature B-cells can acquire cancer stem cell-like characteristics. Disclosures Melnick: Janssen: Research Funding; Epizyme: Consultancy; Constellation: Consultancy.

Published

2019