The Role of the Nucleosomal Acidic Patch in Histone Dimer Exchange

Gioacchini, Nathan

07 January 2022

Eukaryotes organize their genomes by wrapping DNA around positively charged proteins called histones to form a structure known as chromatin. This structure is ideal for keeping the genome safe from damage, but also becomes an obstacle for the transcriptional machinery to access information stored in the DNA. To facilitate a balance between storage and accessibility, eukaryotes utilize a family of enzymes known as ATP-dependent chromatin remodelers to directly manipulate chromatin structure. The diverse activities of these chromatin remodeling enzymes range from simply sliding nucleosomes to reveal transcription start sites, to editing the composition of a nucleosome by exchanging canonical histones for histone variants. Chromatin remodeling enzymes recognize features of the nucleosome that activate their ATPase domains and enable proper remodeling function. One nuclear epitope that has been extensively studied is the nucleosomal acidic patch. This negatively charged region on the face of the nucleosome has been shown to be essential for remodeling enzymes like Chd1, ISWI, and INO80C. The chromatin remodeler SWR1C edits nucleosomes by removing the canonical histone H2A from nucleosomes and exchanges it for the histone variant H2A.Z, but the role of the acidic patch in this process has not been investigated. In this work, I showed that SWR1C has normal binding affinity to acidic patch mutant nucleosomes and retains ATPase stimulation but can no longer exchange dimers on this substrate. This work also identified a novel arginine anchor on the essential SWR1C subunit, Swc5, that binds specifically to the nucleosomal acidic patch. The data in this work suggest a mechanism where SWR1C engages nucleosomes and uses the Swc5 subunit to recognize the nucleosomal acidic patch to couple ATPase activity to histone dimer exchange.

Chromatin Remodeling

Histone Variants

Nucleosome

Acidic Patch

Biochemistry

Myocyte-Specific Overexpressing HDAC4 Promotes Myocardial Ischemia/Reperfusion Injury

Zhang, Ling, Wang, Hao, Zhao, Yu, Wang, Jianguo, Dubielecka, Patrycja M., Zhuang, Shougang, Qin, Gangjian, Chin, Y. Eugene, Kao, Race L., Zhao, Ting C.

17 July 2018

Background: Histone deacetylases (HDACs) play a critical role in modulating myocardial protection and cardiomyocyte survivals. However, Specific HDAC isoforms in mediating myocardial ischemia/reperfusion injury remain currently unknown. We used cardiomyocyte-specific overexpression of active HDAC4 to determine the functional role of activated HDAC4 in regulating myocardial ischemia and reperfusion in isovolumetric perfused hearts. Methods: In this study, we created myocyte-specific active HDAC4 transgenic mice to examine the functional role of active HDAC4 in mediating myocardial I/R injury. Ventricular function was determined in the isovolumetric heart, and infarct size was determined using tetrazolium chloride staining. Results: Myocyte-specific overexpressing activated HDAC4 in mice promoted myocardial I/R injury, as indicated by the increases in infarct size and reduction of ventricular functional recovery following I/R injury. Notably, active HDAC4 overexpression led to an increase in LC-3 and active caspase 3 and decrease in SOD-1 in myocardium. Delivery of chemical HDAC inhibitor attenuated the detrimental effects of active HDAC4 on I/R injury, revealing the pivotal role of active HDAC4 in response to myocardial I/R injury. Conclusions: Taken together, these findings are the first to define that activated HDAC4 as a crucial regulator for myocardial ischemia and reperfusion injury.

histone deacetylase4 (HDAC4)

ischemia/reperfusion

myocardial function

Surgery

Cytochemical Studies of RNA and Basic Nuclear Proteins in Lycosid Spiders

Rasch, Ellen, Connelly, Barbara A.

01 December 2006

Tissues of lycosid spiders were studied for RNA distributions with the basic dye Azure B. Changes in the basic proteins associated with DNA during spermiogenesis were identified with alkaline fast green staining after DNA extraction with trichloroacetic acid and by cytochemical tests for arginine. Tissue glycoproteins of the gut diverticula and the ducts of silk glands were resistant to diastase digestion and required periodic acid hydrolysis to localize reaction products with the Schiff reagent for aldehydes. Spiders possess novel types of cells that are in need of further study and may be useful as models for developmental biology.

araneidae

histone proteins

protamines

RNA

spermiogenesis

Biomedical Sciences

Identification of Sperm Chromatin Proteins as Candidate Markers of Stallion Fertility

Ketchum, Chelsea C.

01 December 2018

During spermatogenesis, histones are largely replaced by transition proteins and protamines in normal stallions. Incomplete nucleoprotein exchange results in the abnormal retention of histones and transition proteins, which is an indicator of poor sperm quality. Equine nucleoprotein exchange has not previously been investigated in detail, so that equine sperm chromatin quality problems, which are often responsible for poor breeding performance of stallions, are not well understood. In order to characterize chromatin remodeling events in stallion spermatogenesis and to identify proteins indicative of sperm chromatin defects, such as excessive amounts of histones, we identified antibodies that recognize equine testis-specific proteins of interest. Immunoblotting of testis and sperm protein lysates and immunofluorescence staining of histological tissue sections were used to identify candidate marker proteins of incomplete sperm chromatin maturation. Results of the study, which represents the first comprehensive characterization of the nucleoprotein exchange during spermatogenesis in the stallion, challenge the paradigm that the main function of histone H4 lysine (hyper-) acetylation (concomitant H4K5 and H4K8 acetylation) is to facilitate nucleosome ejection during spermatid nuclear elongation to allow for transition protein and protamine insertion into the chromatin. That paradigm was based on observations in mice and rats where H4 acetylation in several lysine residues occurs just prior to or during nuclear elongation. In contrast, the equine data presented here show strong acetylation of H4 in K5, K8 and K12 positions immediately after meiosis in round spermatids, independent of nuclear transition protein 1 deposition. Furthermore, results of H4K16 acetylation analyses underline the importance of this mark, which is likely mediated by DNA damage signaling pathways, emphasizing the importance of DNA repair processes for the exchange of nucleoprotein exchange in spermiogenesis and therefore, in extension, for male fertility. In addition, a revised description of the equine spermatogenic cycle is proposed here that is better aligned with human, mouse and rat spermatogenesis. Finally, the testis-specific histone variant TH2B was identified as a potential quantitative marker of equine sperm quality.

spermatogenesis

chromatin

spermiogenesis

spermatid

histone modification

Animal Sciences

The function of Prdm12 in histone methylation and cell proliferation / ヒストンメチル化と細胞増殖におけるPrdm12の役割

Yang, Chia-Ming

25 November 2013

京都大学 / 0048 / 新制・課程博士 / 博士(生命科学) / 甲第17969号 / 生博第295号 / 新制||生||39(附属図書館) / 30799 / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授 米原 伸, 教授 河内 孝之, 教授 朝長 啓造 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

Prdm12

Histone methyltransferase

Retinoic acid

cell cycle

460

Mutant IDH1 Dysregulates the Differentiation of Mesenchymal Stem Cells in Association with Gene-Specific Histone Modifications to Cartilage- and Bone-Related Genes / 変異型IDH1は遺伝子特異的なヒストン修飾を介して、間葉系幹細胞から軟骨及び骨への分化を脱制御する

Hassan, Mohamed Hassan Ali Elalaf

23 May 2016

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第19891号 / 医博第4140号 / 新制||医||1016(附属図書館) / 32968 / 京都大学大学院医学研究科医学専攻 / (主査)教授 妻木 範行, 教授 山田 泰広, 教授 開 祐司 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Cartilaginous tumor

IDH1 mutation

Mesenchymal stem cell

Histone modification

490

The role of nuclear architecture in the context of antigenic variation in Trypanosoma brucei / Über die Rolle der Zellkernarchitektur im Kontext von Antigenvariation in Trypanosoma brucei

Müller-Hübner, Laura

January 2020

Antigenic variation of surface proteins is a commonly used strategy among pathogens to evade the host immune response [63]. The mechanism underlying antigenic variation relies on monoallelic exclusion of a single gene from a hypervariable multigene family combined with repeated, systematic changes in antigen expression. In many systems, these gene families are arranged in subtelomeric contingency loci that are subject to both transcriptional repression and enhanced mutagenesis and recombination [16]. Eviction of a selected gene from a repressed antigen repertoire can be achieved e.g. by recombination into a dedicated, transcriptionally permissive site or by local epigenetic alterations in chromatin composition of the selected gene. Both processes are ultimately affected by genome architecture. Architectural proteins controlling antigenic variation have, however, remained elusive in any pathogen. The unicellular protozoan parasite Trypanosoma brucei evades the host immune response by periodically changing expression of a single variant surface glycoprotein (VSG) from a repertoire of ~3000 VSG genes – the largest mutually exclusively expressed gene family described today. To activate a selected VSG gene, it needs to be located in a dedicated expression site that becomes subject to relocation into a distinct, transcriptionally active subnuclear compartment, the expression site body (ESB). Whereas this emphasizes the importance of nuclear architecture in regulating antigen expression in T. brucei, the mechanisms underlying spatial positioning of DNA in T. brucei are not well understood. In this study I applied genome-wide chromosome conformation capture (Hi-C) to obtain a comprehensive picture of the T. brucei genome in three dimensions, both in procyclic and bloodstream form parasites. Hi-C revealed a highly structured nucleus with megabase chromosomes occupying distinct chromosome territories. Further, specific trans interactions between chromosomes, among which are clusters of centromeres, rRNA genes and procyclins became apparent. With respect to antigenic variation, Hi-C revealed a striking compaction of the subtelomeric VSG gene repertoire and a strong clustering of transcriptionally repressed VSG-containing expression sites. Further, Hi-C analyses confirmed the spatial separation of the actively transcribed from the silenced expression sites in three dimensions. I further sought to characterize architectural proteins mediating nuclear architecture in T. brucei. Whereas CTCF is absent in non-metazoans, we found cohesin to be expressed throughout the cell cycle, emphasizing a function beyond sister chromatid cohesion in S-phase. By Chromatin-Immunoprecipitation with sequencing (ChIPseq), I found cohesin enrichment to coincide with the presence of histone H3 vari- ant (H3.V) and H4 variant (H4.V). Most importantly, cohesin and the histone variants were enriched towards the VSG gene at silent and active expression sites. While the deletion of H3.V led to increased clustering of expression sites in three dimensions and increased chromatin accessibility at expression site promoters, the additional deletion of H4.V increased chromatin accessibility at expression sits even further. RNAseq showed that mutually exclusive VSG expression was lost in H3.V and H4.V single and double deletion mutants. Immunofluorescence imaging of surface VSGs, flow cytometry and single-cell RNAseq revealed a progressive loss of VSG-2 expression, indicative of an increase in VSG switching rate in the H3.V/H4.V double deletion mutants. Using long-read sequencing technology, we found that VSG switching occurred via recombination and concluded, that the concomitant increase in spatial proximity and accessibility among expression sites facilitated the recombination event. I therefore identified the histone variants H3.V and H4.V to act at the interface of global nuclear architecture and chromatin accessibility and to represent a link between genome architecture and antigenic variation. / Antigenvariation ist ein weit verbreiteter Mechanismus der Immunevasion von Pathogenen [63]. Sie beruht auf der transkriptionellen Selektion eines einzelnen Gens aus einer hypervariablen Multi-Gen Familie und dem wiederholten, systematischen Wechsel zwischen der Expression verschiedener Gene dieser Familie. In vielen Organismen sind diese Gene als Kontingenzgene in den Subtelomeren angeordnet, wo sind einerseits transkriptionell reprimiert werden, andererseits erhöhter Mutagenese und Rekombination unterliegen [16]. Monoallelische Exklusion eines Gens und die damit einhergehende Eviktion aus seinem reprimierten genomischen Umfeld beruht auf unterschiedlichen molekularen Mechanismen. Sie ist, zum Beispiel, das Resultat einer Rekombination des betreffenden Gens in einen dedizierten, transkriptionell permissiven Lokus oder wird durch epigenetische, bzw. räumliche Umstrukturierung des entsprechenden Gens oder zugrunde liegenden Chromatins erreicht. Beide Prozesse sind letztendlich durch die Architektur des Genoms beeinflusst. Architekturelle Proteine, die ebenfalls Antigenvariation kontrollieren, sind in vielen Pathogenen unbekannt. Der parasitäre Protozoe Trypanosoma brucei entkommt einer Elimination durch die Immunabwehr seines Wirtes durch den periodischen Wechsel in der Expression eines von fast 3000 variablen Oberflächenglykoproteinen (VSGs). VSG-Gene umfassen die größte, monoallelisch exprimierte Genfamilie, die bislang beschrieben wurde. Um exprimiert zu werden, muss das selektierte VSG Gen in eine Expressionsseite transloziert sein. Diese wiederum wird in einem dedizierten Kompartment des Zellkerns, dem Expressionsseiten-Zellkernkörper (ESB), transkribiert. Obgleich diese Gegebenheiten die zentrale Rolle der Zellkernarchitektur in der Antigenvariation in T. brucei verdeutlichen, so ist wenig über die ihr zugrundeliegenden Mechanismen bekannt. Um ein umfassendes Bild der Zellkernarchitektur in Trypanosomen zu bekommen, habe ich in der hier vorliegenden Doktorarbeit Hi-C, eine Methode zur Feststellung chromosomaler Konformationen, in T. brucei Blutstromform und Prozyklen etabliert und angewendet. Die Applikation dieser Technik offenbarte einen hoch strukturierten Zellkern: Chromosome sind territorial angeordnet und gehen spezifische Interaktionen in trans untereinander ein. Dies sind beispielsweise Interaktionen zwischen Zentromeren, Genen für ribosomale RNA und Prozyklinen unterschiedlicher Chromosomen. Auch Interaktionen, die in funktionellem Zusammenhang mit Antigenvariation stehen, wurden gefunden. Dabei handelte es sich zum Einen um strukturelle Verdichtungen des subtelomerischen Chromatins transkriptionell reprimierter VSG Gene und zum Anderen um erhöhte Interaktionen zwischen reprimierten VSG-Expressionsseiten. Hi-C bestätigte außerdem die räumliche Separation der aktiv transkribierten Expressionsseite von den übrigen, stillen VSG-Expressionsseiten. Des Weiteren suchte ich nach Proteinen, die in der Aufrechterhaltung der Zellkernarchitektur in T. brucei wirken. Anders als CTCF ist Cohesin nicht auf Metazoen beschränkt. Ich fand Cohesin über den gesamten Zellzyklus exprimiert, was eine architekturelle Rolle des Proteinkomplexes zuzüglich der Schwesterchromatidkohäsion suggerierte. Mittels Chromatin-Immunpräzipitation konnte ich feststellen, dass Cohesin mit den Histonvarianten H3.V und H4.V an vielen Stellen des Ge- noms kolokalisierte, insbesondere über dem VSG Gen der aktiven und reprimierten Expressionsseiten. Während eine Deletion von H3.V zu erhöhten Interaktionsfrequenzen zwischen Expressionsseiten führte, resultierte eine gleichzeitige Deletion von H3.V und H4.V zu einer additiven Öffnung des Chromatins an Expressionsseiten. RNA Sequenzierungen ergaben, dass in der H3.V/H4.V Doppeldeletionsmutante die Transcription von VSG Genen erhöht war, was auf einen funktionellen Verlust der monoallelischen Expression hindeutete. Immunfluoreszenzaufnahmen der VSGs auf der Zelloberfläche, Durchflusszytometrie und RNA Sequenzierung einzelner Zellen zeigten einen fortschreitenden Verlust der Expression von VSG-2, was auf einen erhöhten Wechsel der VSG-Expression auf dem Einzelzelllevel hindeutete. Durch die Sequenzierung der genomischen DNA der H3.V/H4.V Doppeldeletionsmutante konnten wir feststellen, dass der primäre Mechanismus des Wechsels in der VSG Expression auf eine Rekombination zwischen Expressionsseiten zurückzuführen war. Diese Rekombination wurde vermutlich durch die gesteigerte räumliche Nähe und Öffnung des Chromatins der Expressionsseiten begünstigt. Zusammenfassend konnte ich feststellen, dass die Histonvarianten H3.V und H4.V auf der Schnittstelle zwischen globaler Zellkernarchitektur und lokaler Chromatinzugänglichkeit agieren und funktionell ein molekulares Verbindungsstück zwischen Genomarchitektur und Antigenvariation darstellen.

Trypanosoma brucei brucei

Zellkern

Histone

DNS

ddc:610

Role of Nuclear Hat1p Complex and Acetylation of Newly Synthesized Histone H4 in Chromatin Assembly

Ge, Zhongqi

20 May 2013

No description available.

Biochemistry

histone acetylation

chromatin assembly

DNA damage repair

Functional Dynamics of ASH1L Histone Methyltransferase and its Activation mechanism(s)

Al-Harthi, Samah

03 1900

The human Absent, small, or homeotic disc1 (ASH1L) is a member of the Trithorax group (TrxG) proteins that play a role in epigenetic gene activation of developmental HOX genes via H3K36me2 methylation mark. ASH1L contains the evolutionarily conserved SET domain responsible for catalyzing monomethylated and dimethylated lysine formation. The crystal structure of the SET domain of ASH1L revealed a substrate-binding pocket blockage caused by an autoinhibitory loop (AI-loop) that undergoes dynamic changes during catalysis and could be exploited for inhibitor development. Studies have shown that the AI-loop regulates the SET domain, thus the KMTase activity of ASH1L. The SET domain adopts an autoinhibited state where the AI-loop blocks the entry of substrate to the active site, have made it a difficult target for the development of inhibitors. The emerging ASH1L's role in multiple oncogenic processes leading to cancer makes it a viable therapeutic target. Effective targeted inhibition of ASH1L enzymatic activity would be a potential therapeutic approach in cancers driven by high HOX gene expression. We employed the state-of-the-art 1H and 13C-detected solution NMR to better understand the ASH1L regulatory mechanism. We investigated the AI-loop's dynamic structure and conformational mobility of backbone and side chains in the absence and presence of the first- in-class small molecule inhibitors. Numerous backbone amide signals across the AI loop and the catalytic cleft of the SET domain are being broadened, indicating the complex interplay of fast local to slow segmental dynamics across the ASH1L SET domain. The binding of the first-in-class inhibitors perturbs the signals around the AI-loop and SAM binding cleft, validating the inhibitor binding site in the solution. The recently published crystal structures of the MRG domain bound to the ASH1L SET domain revealed disordered conformations of the AI-loop and rearrangement in the SAM binding site compared to the apo ASH1L SET domain. It has been proposed that MRG15 allosterically activates ASH1L by releasing the AI loop. Therefore, we performed extensive studies in an aqueous solution to understand the role of MRG15 in stimulating the catalytic activity of ASH1L. We found that the full-length MRG15 is necessary to induce histone methyltransferase activity of the catalytic SET domain of ASH1L. In contrast, the MRG domain alone cannot enhance the catalytic activity. Furthermore, we found that only the complex of ASH1L SET domain with MRG15 but not with isolated MRG domain can interact with nucleosomes. In summary, I have established the direct link between the structural dynamics of the ASH1L SET domain and its enzymatic activity. Moreover, I have defined the adaptor role of the complete MRG15 protein as the substrate recognition factor for the ASH1L protein without perturbing the AI loop or SAM binding site. The atomic level studies mentioned above, supported by the detailed structure and dynamics studies of the first-in-class inhibitor complex with ASH1L, establish the solid foundations for further drug candidate development, selectively targeting the ASH1L and potentially other H3K36me2 methyltransferases.

NMR

Autoinhibitory loop

MST

Lysine histone methyltransferase

HMT

ASH1L

Dissecting the Role of the Histone Demethylase KDM1B in Maintenance of Pluripotency and Differentiation of Human Embryonic Stem Cells

Alfarhan, Dalal

04 1900

Lysine-specific Demethylase 1B (KDM1B) is a chromatin regulator which functions as a histone eraser through the removal of the post-translational modifications mono and dimethylation of histone 3 on lysine 4 (H3K4me1/2). This process is enhanced by the formation of a complex with Nuclear Protein Glyoxylate Reductase (NPAC). NPAC resolves the sequestration of the nucleosome histone tail to allow robust demethylation of H3K4me2 by KDM1B, during transcriptional elongation by RNA polymerase 2 (RNAP II). KDM1B is involved in many crucial processes during development. Its physiological functions include the establishment of maternal genomic imprints, reset of the epigenome during somatic cell reprogramming, and regulation of brown adipogenic differentiation. In light of this, the role of KDM1B in human embryonic stem cells (hESCs) is examined through CRISPR/Cas9-editing to further dissect its biological functions during embryogenesis. CRISPR-induced knockouts of KDM1B exhibited similar cell proliferation rate and expression of OCT4 and NANOG pluripotency markers to wildtype cells. Furthermore, KDM1B-/- clones were able to maintain their pluripotency potential by differentiating to all germ layers in teratoma and embryoid body formation assays. In addition, RNA-seq of KDM1B-/- clones showed enrichment of mesoderm lineage-related gene ontology (GO) terms in the downregulated differentially expressed genes. Thus, KDM1B is believed to be dispensable during the pluripotent stage of the cell but proved fundamental during later stages of development.

KDM1B

Histone demethylation

CRISPR knockout

Human embryonic stem cells

Differentiation