• Skip to navigation (Press Enter).
  • Skip to main content (Press Enter).
Suche
  • Universitätsklinikum
  • Home
  • Projects
    • Chromatin
    • Cancer
    • Signal Transduction
    • Animal Models / Bone
  • Publications
  • Prof. Schuele
  • Lab Members
  • Transgenic Services
  • Academic Program
  • Awards
  • SFB 992 Initiative
Grafik unten
Logo
  • Contact
  • How to Find Us
  • Organisations
  • Media
Namensbildlinkesbildmittebildrechtesbild
Printer  Pdf
» Projects » Chromatin
Google-Suchmaschine
Gesamte Uniklinikseite
Interne Suchmaschine
Aktuelle Uniklinikseite (molgyn)
Suche nach Stichworten
Begriffe, Krankheiten, Einrichtungen u.v.m., verknüpft mit dem zuständigen Bereich.
Personensuche
Nachname:
Vorname:
Akad. Titel:
Org.-Einheit:
phonetische Suche
Suche nach Einrichtungen:
Such-Bereich:
Bezeichnung:
phonetische Suche
Suche über die Einrichtungen
Im Menüpunkt "Übersicht" sind Einrichtungen unter verschiedenen Gesichtspunkten gruppiert: Kliniken, Abteilungen, Institute, Zentrale Einrichtungen und ähnliches.
Smart-Link
Seitenaufruf mit Smartlink--> Info hier!
smartlink-symbol

NIR is a novel INHAT repressor that modulates the transcriptional activity of p53

Most transcriptional repression pathways depend on the targeted deacetylation of histone tails. We characterize NIR, a novel transcriptional corepressor with inhibitor of histone acetyltransferase (INHAT) activity. NIR (Novel INHAT Repressor) is ubiquitously expressed throughout embryonic development and adulthood. NIR is a potent transcriptional corepressor that is not blocked by histone deacetylase inhibitors and is capable of silencing both basal and activator-driven transcription. NIR directly binds to nucleosomes and core histones and prevents acetylation by histone acetyltransferases, thus acting as a bona fide INHAT.
Using a tandem affinity purification approach, we identified the tumor suppressor p53 as a NIR-interacting partner. Association of p53 and NIR was verified in vitro and in vivo. Upon recruitment by p53, NIR represses transcription of both p53-dependent reporters and endogenous target genes.
Knock-down of NIR by RNA interference significantly enhances histone acetylation at p53-regulated promoters. Moreover, p53-dependent apoptosis is robustly increased upon depletion of NIR. In summary, our findings describe NIR as a novel INHAT that plays an important role in the control of p53 function.

Gene regulation by histone demethylation

Gene regulation in eukaryotes requires the coordinate interaction of chromatin-modulating proteins with specific transcription factors such as the androgen receptor. Gene activation and repression is specifically regulated by histone methylation status at distinct lysine residues. Lysine-specific demethylase 1 (LSD1; also known as BHC110) co-localizes with the androgen receptor in normal human prostate and prostate tumour.
LSD1 interacts with androgen receptor in vitro and in vivo, and stimulates androgen-receptor-dependent transcription. Conversely, knockdown of LSD1 protein levels abrogates androgen-induced transcriptional activation and cell proliferation. Chromatin immunoprecipitation analyses demonstrate that androgen receptor and LSD1 form chromatin-associated complexes in a ligand-dependent manner.
LSD1 relieves repressive histone marks by demethylation of histone H3 at lysine 9 (H3-K9), thereby leading to de-repression of androgen receptor target genes. Furthermore, we identify pargyline as an inhibitor of LSD1. Pargyline blocks demethylation of H3-K9 by LSD1 and consequently androgen-receptor-dependent transcription. Thus, modulation of LSD1 activity offers a new strategy to regulate androgen receptor functions. Here, we link demethylation of a repressive histone mark with androgen-receptor-dependent gene activation, thus providing a mechanism by which demethylases control specific gene expression.
unterer Abschluss
Imprint