Project description:Abnormal WNT signaling increases MYC expression in colon cancer cells in part via oncogenic super-enhancer-(OSE)-mediated gating of the active MYC to the nuclear pore in a poorly understood process. We show here that that the principal tenet of the WNT-regulated MYC gating, facilitated nuclear export of the MYC mRNA, converged on a single CTCF binding site (CTCFBS) within the OSE to confer increased growth advantage. To achieve this, the CTCFBS directed in a stepwise manner the WNT-dependent trafficking of the entire OSE to the nuclear pore from intra-nucleoplasmic positions. Once the OSE reached a perinuclear position, triggered by CTCFBS-mediated CCAT1 eRNA activation, its final stretch (<1micrometer) to the nuclear pore required the recruitment of AHCTF1, a key nucleoporin, to the CTCFBS. Thus, a novel WNT-CTCF-eRNA circuit converges on the ability of the OSE to promote pathological cell growth by coordinating the trafficking of MYC within the 3D nuclear architecture.

Project description:Abnormal WNT signaling increases MYC expression in colon cancer cells in part via oncogenic super-enhancer-(OSE)-mediated gating of the active MYC to the nuclear pore in a poorly understood process. We show here that that the principal tenet of the WNT-regulated MYC gating, facilitated nuclear export of the MYC mRNA, converged on a single CTCF binding site (CTCFBS) within the OSE to confer increased growth advantage. To achieve this, the CTCFBS directed in a stepwise manner the WNT-dependent trafficking of the entire OSE to the nuclear pore from intra-nucleoplasmic positions. Once the OSE reached a perinuclear position, triggered by CTCFBS-mediated CCAT1 eRNA activation, its final stretch (<1micrometer) to the nuclear pore required the recruitment of AHCTF1, a key nucleoporin, to the CTCFBS. Thus, a novel WNT-CTCF-eRNA circuit converges on the ability of the OSE to promote pathological cell growth by coordinating the trafficking of MYC within the 3D nuclear architecture.

Project description:Abnormal WNT signaling increases MYC expression in colon cancer cells in part via oncogenic super-enhancer (OSE)-mediated gating of MYC to the nuclear pore. This process enables MYC transcripts to escape the higher degradation rate in the nucleus compared to the cytoplasm. By targeted mutation, we show here that a single OSE-specific CTCF binding site (CTCFBS) mediates the WNT-regulated increased nuclear export rate of mRNAs derived from its interacting MYC and FAM49B loci, located >0.5 and >2.6 mbp distal of the OSE. The CTCFBS coordinated OSE-MYC proximity with their peripheral localisation, and mediated the WNT-dependent recruitment of the nuclear pore anchor AHCTF1 to the OSE. Furthermore, the CTCFBS up-regulated CCAT1 eRNA transcription, implicated in OSE-MYC interactions, correlating with an enhanced ability of the OSE to reach the nuclear periphery. We submit that WNT-dependent gating of MYC requires CTCF complexed with the OSE to coordinate multiple steps of the gating process.

Project description:The WNT-dependent gating of MYC requires non-canonical functions of a distal CTCF binding site

Project description:Canonical WNT signaling-dependent gating of MYC requires a non-canonical CTCF function at a distal binding site

Project description:The WNT-dependent gating of MYC requires non-canonical functions of a distal CTCF binding site (RNA-Seq II)

Project description:The WNT-dependent gating of MYC requires non-canonical functions of a distal CTCF binding site

Project description:Recent evidence suggests that nucleoporins, well known components that control nucleo-cytoplasmic trafficking, have wide-ranging functions in developmental gene regulation that potentially extend beyond their role in nuclear transport. Whether the unexpected role of nuclear pore proteins in transcription regulation, which initially has been described in fungi and flies, also applies to human cells is unknown. Here we show at a genome-wide level that the nuclear pore protein NUP98 associates with developmentally regulated genes active during human embryonic stem cell differentiation. Examination of Nup98 binding using multiple Nup98 antibodies in four cell types, three of which are related by direct lineage.

Project description:Nucleoporins are major constituents of nuclear pore complexes, molecular conglomerates embedded within the nuclear envelope that participate in bidirectional trafficking between nucleus and cytoplasm, chromatin silencing and organization, and transcriptional regulation . This functional vantage point is of utmost importance for fundamental cell processes such as intracellular signaling, cell migration, DNA repair and cell division, all of which can be impaired when the molecular identity of the NE and nuclear pore complex is compromised, as seen in cancer. Here we identify a nucleoporin POM121 as a key regulator of proliferation, tumourigenesis, and survival in chemoresistant prostate cancer. Mechanistically, POM121 regulates nuclear transport of specific survival-conferring transcription factors (MYC and E2F1) and androgen receptor that have been previously linked with advanced stages of prostate cancer. POM121-mediated deregulation of nucleocytoplasmic transport occurs through its interaction with Importin β, which serves as a pharmacological target that decreases tumour growth, sensitizes the tumor cells to standard chemotherapy, and improves survival of patient-derived xenograft mice. These results indicate that nuclear pore complex represents a novel mechanism of chemoresistance, which can be therapeutically targetable in aggressive prostate cancer.

Project description:Recent evidence suggests that nucleoporins, well known components that control nucleo-cytoplasmic trafficking, have wide-ranging functions in developmental gene regulation that potentially extend beyond their role in nuclear transport. Whether the unexpected role of nuclear pore proteins in transcription regulation, which initially has been described in fungi and flies, also applies to human cells is unknown. Here we show at a genome-wide level that the nuclear pore protein NUP98 associates with developmentally regulated genes active during human embryonic stem cell differentiation.