Geoffrey Bartholomeusz scite author profile

Epidermal growth factor receptor (EGFR) exists in the nucleus of highly proliferative cells where it functions as a transcription factor. Although EGFR has transactivational activity, it lacks a DNA binding domain and, therefore, may require a DNA binding transcription cofactor for its transcriptional function. Here, we report that EGFR physically interacts with signal transducers and activators of transcription 3 (STAT3) in the nucleus, leading to transcriptional activation of inducible nitric oxide synthase (iNOS). In breast carcinomas, nuclear EGFR positively correlates with iNOS. This study describes a mode of transcriptional control involving cooperated efforts of STAT3 and nuclear EGFR. Our work suggests that the deregulated iNOS/NO pathway may partly contribute to the malignant biology of tumor cells with high levels of nuclear EGFR and STAT3.

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Erk Associates with and Primes GSK-3β for Its Inactivation Resulting in Upregulation of β-Catenin

Ding

et al. 2005

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Beta-catenin is upregulated in many human cancers and considered to be an oncogene. Hepatocellular carcinoma (HCC) is one of the most prevalent human malignancies, and individuals who are chronic hepatitis B virus (HBV) carriers have a greater than 100-fold increased relative risk of developing HCC. Here we report a mechanism by which HBV-X protein (HBX) upregulates beta-catenin. Erk, which is activated by HBX, associates with GSK-3beta through a docking motif ((291)FKFP) of GSK-3beta and phosphorylates GSK-3beta at the (43)Thr residue, which primes GSK-3beta for its subsequent phosphorylation at Ser9 by p90RSK, resulting in inactivation of GSK-3beta and upregulation of beta-catenin. This pathway is a general signal, as it was also observed in cell lines in which Erk-primed inactivation of GSK-3beta was regulated by IGF-1, TGF-beta, and receptor tyrosine kinase HER2, and is further supported by immunohistochemical staining in different human tumors, including cancers of the liver, breast, kidney, and stomach.

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Binding at and transactivation of the COX-2 promoter by nuclear tyrosine kinase receptor ErbB-2

et al. 2004

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Endosomal Transport of ErbB-2: Mechanism for Nuclear Entry of the Cell Surface Receptor

Giri

Ali-Seyed

et al. 2005

Molecular and Cellular Biology

220

237

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The cell membrane receptor ErbB-2 migrates to the nucleus. However, the mechanism of its nuclear translocation is unclear. Here, we report a novel mechanism of its nuclear localization that involves interaction with the transport receptor importin ␤1, nuclear pore protein Nup358, and a host of players in endocytic internalization. Knocking down importin ␤1 using small interfering RNA oligonucleotides or inactivation of small GTPase Ran by RanQ69L, a dominant-negative mutant of Ran, causes a nuclear transport defect of ErbB-2. Mutation of a putative nuclear localization signal in ErbB-2 destroys its interaction with importin ␤1 and arrests nuclear translocation, while inactivation of nuclear export receptor piles up ErbB-2 within the nucleus. Additionally, blocking of internalization by a dominant-negative mutant of dynamin halts its nuclear localization. Thus, the cell membrane-embedded ErbB-2, through endocytosis using the endocytic vesicle as a vehicle, importin ␤1 as a driver and Nup358 as a traffic light, migrates from the cell surface to the nucleus. This novel mechanism explains how a receptor tyrosine kinase on the cell surface can be translocated into the nucleus. This pathway may serve as a general mechanism to allow direct communication between cell surface receptors and the nucleus, and our findings thus open a new era in understanding direct trafficking between the cell membrane and nucleus.Despite a number of recent reports on translocation of receptor tyrosine kinases (RTKs) to the nucleus (reviewed in references 8 and 52), the mechanism of how RTKs travel from the cell surface to the nucleus is still unknown. Transmembrane receptors serve as sensors, recognizing the growth factor in the extracellular environment and conveying the message through the signaling cascade to the nucleus. However, some RTKs, like the epidermal growth factor receptor (EGFR) family members (27,29,32,36,37,49,54), fibroblast growth factor receptor 1 (FGFR1) and FGFR3 and their splice variants (23,31,40,43,44,45,57), insulin receptor (41), and vascular endothelium growth factor receptor Flk1/KDR (13,21,34), are known to migrate to the nucleus either intact or as a fragment of proteolytic cleavage, interestingly, with or without the corresponding ligand. These nuclear RTKs have been shown to act as transcription factors (27,36,49,54) for genes like Cyclin D1 (27), FGF2 (38), and COX-2 (49) and modulators for induction of c-jun and cyclin D1 (40). Additionally, nuclear matrix binding of FGFR1 and insulin receptor (41, 45) has been shown to strategically position the receptors for involvement in the regulation of gene expression. More recently, the nuclear EGFR was shown to interact with well-known DNA binding transcriptional factors, such as STAT3 and E2F1, to regulate the expression of inducible nitric oxide synthase and B-Myb (17, 28). Overall, these reports support direct roles for RTKs in the nucleus, which represent a new class of RTK functions.However, the mechanism of their nuclear import is virtually unknown. We repor...

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Nuclear‐cytoplasmic transport of EGFR involves receptor endocytosis, importin β1 and CRM1

Ali-Seyed

et al. 2006

J of Cellular Biochemistry

218

195

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Many receptor tyrosine kinases (RTKs) can be detected in the cell nucleus, such as EGFR, HER-2, HER-3, HER-4, and fibroblast growth factor receptor. EGFR, HER-2 and HER-4 contain transactivational activity and function as transcription co-factors to activate gene promoters. High EGFR in tumor nuclei correlates with increased tumor proliferation and poor survival in cancer patients. However, the mechanism by which cell-surface EGFR translocates into the cell nucleus remains largely unknown. Here, we found that EGFR co-localizes and interacts with importins alpha1/beta1, carriers that are critical for macromolecules nuclear import. EGFR variant mutated at the nuclear localization signal (NLS) is defective in associating with importins and in entering the nuclei indicating that EGFR's NLS is critical for EGFR/importins interaction and EGFR nuclear import. Moreover, disruption of receptor internalization process using chemicals and forced expression of dominant-negative Dynamin II mutant suppressed nuclear entry of EGFR. Additional evidences suggest an involvement of endosomal sorting machinery in EGFR nuclear translocalization. Finally, we found that nuclear export of EGFR may involve CRM1 exportin as we detected EGFR/CRM1 interaction and markedly increased nuclear EGFR following exposure to leptomycin B, a CRM1 inhibitor. Collectively, these data suggest the importance of receptor endocytosis, endosomal sorting machinery, interaction with importins alpha1/beta1, and exportin CRM1 in EGFR nuclear-cytoplasmic trafficking. Together, our work sheds light into the nature and regulation of the nuclear EGFR pathway and provides a plausible mechanism by which cells shuttle cell-surface EGFR and potentially other RTKs through the nuclear pore complex and into the nuclear compartment.

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