Deciphering the Mechanism of G9a Spreading Genome-wide

Yevstafiev, Dmytro

January 2015

The cell differentiation process is associated with activation and repression of different genes, whereby the formation of heterochromatin is mediated by spreading of repressor proteins along large chromatin domains. Some of these proteins are methyltransferases, including GLP and G9a that are implicated in the addition of mono- and dimethyl groups to lysine 9 at Histone 3. Despite extensive research the exact mechanism of binding and spreading of G9a and GLP is unclear. To better understand the molecular mechanisms through which G9a and GLP bind to chromatin we tested the in vivo binding of a mutant G9a that is unable to bind to H3K9me2 histone marks via its Ankyrin domain. Murine erythroleukemia (MEL) cell line with expression of mutant G9a was generated using recombinant DNA technologies; G9a binding targets genome-wide were detected by the analysis of ChIP-sequencing data. We validated ChIP-sequencing data providing a reliable tool to visualize G9a targets in MEL cells. We also found that G9a Ankyrin mutant bound to all tested regions suggesting that the Ankyrin domain is not the only factor that contributes to the binding of G9a on chromatin in vivo.

G9a

GLP

Epigenetics

ChIP

ChIP-sequencing

Ankyrin domain

Spreading genome-wide

Methylation of DNA Ligase 1 by G9a/GLP Recruits UHRF1 to Replicating DNA and Regulates DNA Methylation / G9a/GLP複合体によりメチル化されたDNAリガーゼ１はUHRF1をDNA複製の場にリクルートしDNAメチル化を制御する

Tsusaka, Takeshi

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第21028号 / 医科博第89号 / 新制||医科||6(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 斎藤 通紀, 教授 浅野 雅秀, 教授 玉木 敬二 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Non-histone protein methylation

DNA ligase 1

DNA methylation

Replication

UHRF1

G9a/GLP

491

Identifikation und Charakterisierung von Protein-Interaktionspartnern des Transkriptionsfaktors CCAAT/Enhancer Binding Protein beta

Pleß, Ole

14 January 2008

Der Transkriptionsfaktor CCAAT/Enhancer Binding Protein beta (C/EBPbeta) reguliert die Genexpression, Proliferation und Differenzierung in verschiedenen Zelltypen. Die Funktion von C/EBPbeta wird durch Interaktionen mit einer Reihe von Kofaktoren moduliert, die Bestandteile von Chromatin-verŠndernden oder Transkriptions-regulierenden makromolekularen Maschinen sind. Die Identifikation und funktionelle Charakterisierung dieser Kofaktoren trŠgt ma§geblich zum VerstŠndnis der Biologie von C/EBPbeta bei. C/EBPbeta wird zudem in vielfŠltiger Weise posttranslational reguliert. Beispielsweise kann C/EBPbeta phosphoryliert, SUMOyliert, acetyliert und an mehreren Positionen an Arginin- und Lysinresten methyliert werden. Die SUMOylierung von C/EBPbeta gilt als SchlŸsselmodifikation, die nachfolgende Modifikationen steuert und zu einer VerŠnderung der genregulatorischen Eigenschaften von C/EBPbeta fŸhrt. C/EBPbeta bindet an zwei Enzyme der SUMOylierungsmaschinerie, Ubc9 und PIAS3. Es konnte gezeigt werden, dass PIAS3 nicht nur als E3-Ligase bei der SUMOylierungsreaktion dient, sondern auch mit SUMO-modifiziertem C/EBPbeta interagieren und als transkriptioneller Repressor wirken kann. Um weitere Interaktionspartner von C/EBPbeta zu identifizieren wurde ein System zur Proteom-weiten Identifikation von Bindungspartnern etabliert. Dazu wurden radioaktiv markierbare Proteinsonden hergestellt, welche die Identifikation von Bindungspartnern auf Protein-Macroarrays ermšglichten. Neben der transaktivierenden DomŠne (TAD) wurde die regulatorische Region in ihrer SUMOylierten und nicht-modifizierten Form in Screening-Experimenten eingesetzt. Eine Vielzahl von neuen C/EBPbeta-Bindungspartnern konnte identifiziert werden, wobei die konstitutive SUMOylierung C/EBPbeta-Interaktionen verŠndern kann. Bei den identifizierten Proteinen handelt es sich um Mitglieder der Polycomb Gruppe, Chromatin-modifizierende Enzyme, SignaltransduktionsmolekŸle und transkriptionelle Koregulatoren. Wissenschaftlich besonders interessant war die Identifikation der Lysin-Methyltransferase H3-K9-HMTase 3 (G9a) als Bindungspartner der transaktivierenden Region von C/EBPbeta. Diese Interaktion wurde durch GST-Bindungs- und KoimmunoprŠzipitationsstudien bestŠtigt. Durch massenspektrometrische Analysen konnte Monomethylierung der AminosŠuren K39 und K168 in C/EBPbeta nachgewiesen werden. Dadurch ergab sich die Vermutung, dass G9a nicht nur die Methylierung von Histon H3 katalysiert, sondern auch fŸr die Methylierung und Regulation von C/EBPbeta verantwortlich ist. Rekombinantes C/EBPbeta konnte durch G9a in vitro methyliert werden. Koexpression von C/EBPbeta und G9a fŸhrte zu einer Reduktion der transaktivierenden Eigenschaften von C/EBPbeta in AbhŠngigkeit von der katalytischen SET-DomŠne von G9a. Dieser Reduktion konnte durch Mutation der AminosŠuren K39 und K168 in Alanin entgegengewirkt werden. Als Bindungspartner der C/EBPbeta TAD konnte au§erdem die intrazellulŠre DomŠne von Notch1 (Notch1-ICD) identifiziert werden. Der Notch-Signalweg ist ein evolutionŠr konservierter Genschalter, der an vielen Entscheidungen in der Entwicklung sowie bei physiologischen und pathophysiologischen Prozessen im adulten Organismus, wie z. B. akuter lymphatischer T-Zell LeukŠmie (T-ALL), beteiligt ist. Die Interaktion zwischen Notch1-ICD und C/EBPbeta konnte in GST-Bindungsexperimenten und KoimmunoprŠzipitationsstudien verifiziert werden. In Reportergenstudien wurde eine Stimulation der C/EBPbeta-abhŠngigen Transkription durch Notch1-ICD beobachtet. C/EBPbeta ist demnach ein ZielmolekŸl des Notch1-Signalweges. / The transcription factor CCAAT/Enhancer Binding Protein beta (C/EBPbeta) regulates gene expression, proliferation and differentiation of various cell types. The function of C/EBPbeta is modulated by a number of co-factors which are components of macromolecular machines that alter the state of chromatin or that regulate gene transcription. Identification and functional characterisation of these co-factors is crucial for understanding the biology of C/EBPbeta. C/EBPbeta is regulated by a number of posttranslational modifications and can be found in phosphorylated, SUMOylated, acetylated and arginine- or lysine-methylated forms. SUMOylation of C/EBPbeta is considered a key modification which controls subsequent modifications. These modifications alter the gene regulatory functions of C/EBPbeta. C/EBPbeta binds two enzymes of the SUMOylation machinery, Ubc9 and PIAS3. This study shows that PIAS3 not only has E3-ligase activity during the SUMOylation of C/EBPbeta, but also interacts with SUMO-modified C/EBPbeta leading to repression of transcription. A proteome-wide screening procedure was established to identify novel interaction partners of C/EBPbeta. It was based on radioactively labelled proteins that can be utilized as probes to identify binding partners on solid phase protein-macroarrays. The C/EBPbeta transactivation domain (TAD) and its regulatory region in SUMOylated and non-SUMOylated form were used in different screening approaches. Using this procedure a number of novel C/EBPbeta interaction partners were identified, that depended in part on the SUMOylation status of C/EBPbeta. The major part of the C/EBPbeta-interacting proteins are members of the Polycomb group, chromatin-modifying enzymes, signal transduction molecules and transcriptional co-regulators. Interestingly, the lysine-methyltransferase H3-K9-HMTase 3 (G9a) was among the binding partners of C/EBPbeta that interacted with the TAD. This interaction was verified by GST-pulldown and co-immunoprecipitation studies. Mass spectrometrical analysis identified the amino acids K39 and K168 of C/EBPbeta to be mono-methylated. Therefore it was speculated that G9a not only catalyzes the methylation of Histone H3 but may also methylate and regulate C/EBPbeta. Indeed, recombinant C/EBPbeta could be methylated by G9a in vitro. Co-expression of C/EBPbeta and G9a resulted in a reduction of the transactivating potential of C/EBPbeta, which depended on the catalytical SET domain of G9a. This reduction could be counteracted by mutating the amino acids K39 and K168 to alanine. In addition to G9a, the Notch1 intracellular domain (Notch1-ICD) could also be identified as a novel binding partner of the C/EBPbeta TAD. Notch is a component of an evolutionary conserved pathway that acts on numerous physiological and pathophysiological processes during development and in the adult, e.g. T-cell acute lymphoblastic leukemia (T-ALL). The interaction between Notch1-ICD and C/EBPbeta could be verified in GST-pulldown studies and by co-immunoprecipitation. Reporter gene studies showed a stimulation of C/EBPbeta-dependent transcription through Notch1-ICD. C/EBPbeta is therefore a novel target molecule of the Notch1 signaling pathway.

CCAAT/Enhancer Binding Protein beta

Protein-Makroarray-Screening

G9a

Notch1

Lysin-Methylierung

SUMOylierung

PIAS3

CCAAT/Enhancer Binding Protein beta

Protein-Macroarray screening

G9a

Notch1

Lysin-methylation

SUMOylation

PIAS3

570 Biowissenschaften, Biologie

32 Biologie

WG 1840

ddc:570

Funkce Zinc-finger proteinu 644 (Zfp644) v myším organismu. / Function of Zinc finger protein 644 (Zfp644) in mouse organism.

Szczerkowska, Katarzyna Izabela

January 2022

ZNF644 (Zinc Finger Protein 644) is a C2H2 zinc finger gene encoding a putative transcription regulator, of which a point mutation (S672G) is associated with inherited high myopia in humans. It is also described to be a partner of the G9a/GLP (G9a- euchromatic histone- lysine N-methyltransferase 2, EHMT2; GLP - euchromatic histone-lysine N-methyltransferase 1, EHMT1) complex, known for its essential role in histone methylation, specifically H3K9me1and H3K9me2. It was reported that another transcription factor, WIZ (Widely-Interspaced Zinc Finger-Containing Protein), can bind to this complex and cooperate in gene silencing simultaneously. In order to study Zfp644 impact on myopia, we generated a mouse model, Zfp644S673G that mimics human mutation. In addition, a mouse with a persuasive truncated form of the protein, Zfp644Δ8 was created. Both mouse models went through an examination of retinal function and morphology. Moreover, with use of ultrasonography, different ocular parameters were examined. We conclude, that Zfp644 gene is causative for myopia in mice. Further examinations of Zfp644Δ8 animals show severe symptoms in metabolism and female fertility. To describe the impact of Zfp644 in mouse fertility we performed various experiments including analysis of expression of Zfp644 in reproductive...