Understanding H3K36 methyltransferases in mouse embryonic stem cells

Coe Torres, Davi

02 July 2014

Methylation of histone 3 (H3) at lysine 36 (K36) has been implicated in several biological processes, such as DNA replication, DNA repair, and transcription. To date, at least eight distinct mammalian enzymes have been described to methylate H3K36 in vitro and/or in vivo. In this work, Set2, Nsd1, and Nsd3 Venus tagged proteins were successfully expressed in mouse embryonic stem cells and, then, analyzed by confocal microscopy, mass spectrometry (MS), and chromatin immunoprecipitation sequencing (ChIP-seq). MS analysis revealed that Setd2, Nsd1, and Nsd3 do not associate in protein complexes with each other. Setd2 was associated with RNA polymerase II subunits and two transcription elongation factors (Supt5 and Supt6), whereas Nsd1 associated with the transcription factor Zfx. In contrast, Nsd3 interacted with multiple protein complexes including Kdm1b and Brd4 complexes. Interestingly, Nsd1 and Zfx seem to be bound to chromatin during cell division. ChIP-seq analysis of the H3K36 methyltransferases showed different binding profiles at transcribed genes: Nsd1 binds near the transcription start site (TSS), Setd2 loading starts near the TSS and spreads along the gene body, while, Nsd3 is preferentially enriched at the 5’ and 3’ gene regions. Sequential deletion of PWWP and zinger-finger like domains was achieved to study any possible changes in Nsd1 and Nsd3 function. Deletion of either PHD1-4 or PHD5/C5HCH domains decreased Nsd1 recruitment to chromatin. Particularly, the PHD5/C5HCH were identified as the protein-protein interface for Zfx interaction. In agreement, Zfx knockdown also decreased Nsd1 deposition at the Oct4 and Tcl1 promoter regions. Furthermore, Nsd1 depletion reduced bulk histone H3K36me2 and histone H3K36me3 loading at the coding regions of Oct4, Rif1, Brd2, and Ccnd1. In addition, Nsd1 knockdown led to an increased Zfx deposition at promoters. Our findings suggest Zfx recruits Nsd1 to its target loci, whereas Nsd1 regulates Zfx chromatin release and further contributes to transcription regulation through its H3K36 dimethylase activity. On the other hand, loss of Nsd3’s PHD5/C5HCH or PWWP domains decreased Nsd3 binding to DNA. In addition, we demonstrate that Nsd3 is recruited to target genes in a Brd4-dependent manner. Herein, we provided further insights on how H3K36 methyltransferases are regulated, and how they contribute to changes in the epigenetic landscape in mouse embryonic stem cells.fi

Epigenetik

H3K36 Methylierung

embryonale Stammzellen

Epigenetics

H3K36 methylation

embryonic stem cells

ddc:570

rvk:WG 2100

Understanding H3K36 methyltransferases in mouse embryonic stem cells

Coe Torres, Davi

05 June 2014

Methylation of histone 3 (H3) at lysine 36 (K36) has been implicated in several biological processes, such as DNA replication, DNA repair, and transcription. To date, at least eight distinct mammalian enzymes have been described to methylate H3K36 in vitro and/or in vivo. In this work, Set2, Nsd1, and Nsd3 Venus tagged proteins were successfully expressed in mouse embryonic stem cells and, then, analyzed by confocal microscopy, mass spectrometry (MS), and chromatin immunoprecipitation sequencing (ChIP-seq). MS analysis revealed that Setd2, Nsd1, and Nsd3 do not associate in protein complexes with each other. Setd2 was associated with RNA polymerase II subunits and two transcription elongation factors (Supt5 and Supt6), whereas Nsd1 associated with the transcription factor Zfx. In contrast, Nsd3 interacted with multiple protein complexes including Kdm1b and Brd4 complexes. Interestingly, Nsd1 and Zfx seem to be bound to chromatin during cell division. ChIP-seq analysis of the H3K36 methyltransferases showed different binding profiles at transcribed genes: Nsd1 binds near the transcription start site (TSS), Setd2 loading starts near the TSS and spreads along the gene body, while, Nsd3 is preferentially enriched at the 5’ and 3’ gene regions. Sequential deletion of PWWP and zinger-finger like domains was achieved to study any possible changes in Nsd1 and Nsd3 function. Deletion of either PHD1-4 or PHD5/C5HCH domains decreased Nsd1 recruitment to chromatin. Particularly, the PHD5/C5HCH were identified as the protein-protein interface for Zfx interaction. In agreement, Zfx knockdown also decreased Nsd1 deposition at the Oct4 and Tcl1 promoter regions. Furthermore, Nsd1 depletion reduced bulk histone H3K36me2 and histone H3K36me3 loading at the coding regions of Oct4, Rif1, Brd2, and Ccnd1. In addition, Nsd1 knockdown led to an increased Zfx deposition at promoters. Our findings suggest Zfx recruits Nsd1 to its target loci, whereas Nsd1 regulates Zfx chromatin release and further contributes to transcription regulation through its H3K36 dimethylase activity. On the other hand, loss of Nsd3’s PHD5/C5HCH or PWWP domains decreased Nsd3 binding to DNA. In addition, we demonstrate that Nsd3 is recruited to target genes in a Brd4-dependent manner. Herein, we provided further insights on how H3K36 methyltransferases are regulated, and how they contribute to changes in the epigenetic landscape in mouse embryonic stem cells.fi

info:eu-repo/classification/ddc/570

ddc:570

Caractérisation de la fonction des complexes histone déacétylases Rpd3S et Set3C

Drouin, Simon

05 1900

La chromatine est essentielle au maintien de l’intégrité du génome, mais, ironiquement, constitue l’obstacle principal à la transcription des gènes. Plusieurs mécanismes ont été développés par la cellule pour pallier ce problème, dont l’acétylation des histones composant les nucléosomes. Cette acétylation, catalysée par des histones acétyl transférases (HATs), permet de réduire la force de l’interaction entre les nucléosomes et l’ADN, ce qui permet à la machinerie transcriptionnelle de faire son travail. Toutefois, on ne peut laisser la chromatine dans cet état permissif sans conséquence néfaste. Les histone déacétylases (HDACs) catalysent le clivage du groupement acétyle pour permettre à la chromatine de retrouver une conformation compacte. Cette thèse se penche sur la caractérisation de la fonction et du mécanisme de recrutement des complexes HDACs Rpd3S et Set3C. Le complexe Rpd3S est recruté aux régions transcrites par une interaction avec le domaine C-terminal hyperphosphorylé de Rpb1, une sous-unité de l’ARN polymérase II. Toutefois, le facteur d’élongation DSIF joue un rôle dans la régulation de cette association en limitant le recrutement de Rpd3S aux régions transcrites. L’activité HDAC de Rpd3S, quant à elle, dépend de la méthylation du résidu H3K36 par l’histone méthyltransférase Set2. La fonction du complexe Set3C n’est pas clairement définie. Ce complexe est recruté à la plupart de ses cibles par l’interaction entre le domaine PHD de Set3 et le résidu H3K4 di- ou triméthylé. Un mécanisme indépendant de cette méthylation, possiblement le même que pour Rpd3S, régit toutefois l’association de Set3C aux régions codantes des gènes les plus transcrits. La majorité de ces résultats ont été obtenus par la technique d’immunoprécipitation de la chromatine couplée aux biopuces (ChIP-chip). Le protocole technique et le design expérimental de ce type d’expérience fera aussi l’objet d’une discussion approfondie. / Chromatin is essential for the maintenance of genomic integrity but, ironically, is also the main barrier to gene transcription. Many mechanisms, such as histone acetylation, have evolved to overcome this problem. Histone acetylation, catalyzed by histone acetyltransferases (HATs), weakens the internucleosomal and nucleosome-DNA interactions, thus permitting the transcriptional machinery access to its template. However, this permissive chromatin state also allows for opportunistic DNA binding events. Histone deacetylases (HDACs) help restore a compact chromatin structure by catalyzing the removal of acetyl moieties from histones. This thesis focuses on the characterization of the function and of the recruitment mechanism of HDAC complexes Rpd3S and Set3C. The Rpd3S complex is recruited to actively transcribed coding regions through interactions with the hyperphosphorylated C-terminal domain of Rpb1, a subunit of RNA polymerase II, with the DSIF elongation factor playing a role in limiting this recruitment. However, the HDAC activity of Rpd3S depends on H3K36 methylation, which is catalyzed by the Set2 histone methyltransferase. The Set3C complex’ function is still not clearly defined. It is recruited to most of its targets through the interaction between the Set3 PHD domain and di- or trimethylated H3K4. However, Set3C recruitment to genes displaying high RNA polymerase II occupancy is independent of H3K4 methylation. The mechanism by which Set3C is recruited to this gene subset is under investigation. These results have mostly been obtained through chromatin immunoprecipitation coupled to tiling microarrays (ChIP-chip). The protocol and experimental design challenges inherent to this technique will also be discussed in depth.

Immunoprécipitation de la chromatine

ChIP-chip

histone acétyltransférase (HAT)

histone déacétylase (HDAC)

histone méthyltransférase (HMT)

méthylation de H3K36

méthylation de H3K4

transcription

Rpd3

Set3

Chromatin immunoprecipitation

histone acetyltransferase (HAT)

histone deacetylase (HDAC)

ChIP-chip

histone methyltransferase (HMT)

H3K36 methylation

H3K4 methylation

transcription

Rpd3

Set3

Caractérisation de la fonction des complexes histone déacétylases Rpd3S et Set3C

Drouin, Simon

05 1900

La chromatine est essentielle au maintien de l’intégrité du génome, mais, ironiquement, constitue l’obstacle principal à la transcription des gènes. Plusieurs mécanismes ont été développés par la cellule pour pallier ce problème, dont l’acétylation des histones composant les nucléosomes. Cette acétylation, catalysée par des histones acétyl transférases (HATs), permet de réduire la force de l’interaction entre les nucléosomes et l’ADN, ce qui permet à la machinerie transcriptionnelle de faire son travail. Toutefois, on ne peut laisser la chromatine dans cet état permissif sans conséquence néfaste. Les histone déacétylases (HDACs) catalysent le clivage du groupement acétyle pour permettre à la chromatine de retrouver une conformation compacte. Cette thèse se penche sur la caractérisation de la fonction et du mécanisme de recrutement des complexes HDACs Rpd3S et Set3C. Le complexe Rpd3S est recruté aux régions transcrites par une interaction avec le domaine C-terminal hyperphosphorylé de Rpb1, une sous-unité de l’ARN polymérase II. Toutefois, le facteur d’élongation DSIF joue un rôle dans la régulation de cette association en limitant le recrutement de Rpd3S aux régions transcrites. L’activité HDAC de Rpd3S, quant à elle, dépend de la méthylation du résidu H3K36 par l’histone méthyltransférase Set2. La fonction du complexe Set3C n’est pas clairement définie. Ce complexe est recruté à la plupart de ses cibles par l’interaction entre le domaine PHD de Set3 et le résidu H3K4 di- ou triméthylé. Un mécanisme indépendant de cette méthylation, possiblement le même que pour Rpd3S, régit toutefois l’association de Set3C aux régions codantes des gènes les plus transcrits. La majorité de ces résultats ont été obtenus par la technique d’immunoprécipitation de la chromatine couplée aux biopuces (ChIP-chip). Le protocole technique et le design expérimental de ce type d’expérience fera aussi l’objet d’une discussion approfondie. / Chromatin is essential for the maintenance of genomic integrity but, ironically, is also the main barrier to gene transcription. Many mechanisms, such as histone acetylation, have evolved to overcome this problem. Histone acetylation, catalyzed by histone acetyltransferases (HATs), weakens the internucleosomal and nucleosome-DNA interactions, thus permitting the transcriptional machinery access to its template. However, this permissive chromatin state also allows for opportunistic DNA binding events. Histone deacetylases (HDACs) help restore a compact chromatin structure by catalyzing the removal of acetyl moieties from histones. This thesis focuses on the characterization of the function and of the recruitment mechanism of HDAC complexes Rpd3S and Set3C. The Rpd3S complex is recruited to actively transcribed coding regions through interactions with the hyperphosphorylated C-terminal domain of Rpb1, a subunit of RNA polymerase II, with the DSIF elongation factor playing a role in limiting this recruitment. However, the HDAC activity of Rpd3S depends on H3K36 methylation, which is catalyzed by the Set2 histone methyltransferase. The Set3C complex’ function is still not clearly defined. It is recruited to most of its targets through the interaction between the Set3 PHD domain and di- or trimethylated H3K4. However, Set3C recruitment to genes displaying high RNA polymerase II occupancy is independent of H3K4 methylation. The mechanism by which Set3C is recruited to this gene subset is under investigation. These results have mostly been obtained through chromatin immunoprecipitation coupled to tiling microarrays (ChIP-chip). The protocol and experimental design challenges inherent to this technique will also be discussed in depth.

Immunoprécipitation de la chromatine

ChIP-chip

histone acétyltransférase (HAT)

histone déacétylase (HDAC)

histone méthyltransférase (HMT)

méthylation de H3K36

méthylation de H3K4

transcription

Rpd3

Set3

Chromatin immunoprecipitation

histone acetyltransferase (HAT)

histone deacetylase (HDAC)

ChIP-chip

histone methyltransferase (HMT)

H3K36 methylation

H3K4 methylation

transcription

Rpd3

Set3