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Current Cancer Drug Targets

Editor-in-Chief

ISSN (Print): 1568-0096
ISSN (Online): 1873-5576

Nuclear Export as a Novel Therapeutic Target: The CRM1 Connection

Author(s): Chuanwen Lu, Jose A. Figueroa, Zhongwei Liu, Venu Konala, Amardeep Aulakh, Rashmi Verma, Everardo Cobos, Maurizio Chiriva-Internati and Weimin Gao

Volume 15, Issue 7, 2015

Page: [575 - 592] Pages: 18

DOI: 10.2174/156800961507150828223554

Price: $65

Abstract

The integrity of eukaryotic cellular function depends on molecular and biochemical compartmentalization. The transport of macromolecules between compartments requires specific and energydriven mechanisms. It occurs through a class of transport proteins known as karyopherins, which are divided in three different groups (exportins, importins, and transportins). The ubiquitous exportin Chromosome Region Maintenance 1 (CRM1) is involved in the transport of many proteins and RNA molecules from nucleus to cytoplasm. We have reviewed the available evidence supporting the relevance of CRM1 in the biology of several human neoplasms, its potential role in drug resistance, and its promise as a therapeutic target. Here we discuss different cancer related proteins (tumor suppressor genes, oncogenes, and enzymatic therapeutic targets), their function, and their association with CRM1, as well as agents that specifically inhibit CRM1, their mechanism of action, and their clinical relevance in certain human neoplasms. The directionality of nuclear transport and the specific molecular cargo in question are of paramount importance when examining the effects that CRM1 inhibition may have on cellular pathophysiology. The available data point out the potential role of CRM1-dependent nuclear export of regulatory proteins in the biology of certain human malignancies. Further studies should expand and clarify the importance of this mechanism in the pathobiology of human neoplasia.

Keywords: Cancer, chromosome region maintenance 1, exportin 1, nuclear export signal, oncogene, tumor suppressor gene.


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