Katharine S. Ullman

Nuclear Export Receptors: From Importin to Exportin

In a literal sense, export receptors may next interact with proteins of the nuclear pore (for example,Powers et al. 1997xPowers, M.A., Forbes, D.J., Dahlberg, J.E., and Lund, E. J. Cell Biol. 1997; 136: 241–250Crossref | PubMed | Scopus (152)See all ReferencesPowers et al. 1997; see alsoDoye and Hurt 1997xDoye, V. and Hurt, E. Curr. Opin. Cell Biol. 1997; 9: 401–411Crossref | PubMed | Scopus (192)See all ReferencesDoye and Hurt 1997). Another option is that other soluble factors may be required to bind exportins to the pore. Rip/Rab may belong to an as-yet-uncharacterized class of proteins that act as “itinerant” nucleoporins, soluble at some times and docked at the pore at others. By forming a Rip/exportin 1/Rev-NES complex, such proteins could act to dock the exportins at the pore. Indeed, evidence for such a complex was recently found (Neville et al. 1997xNeville, M., Lee, L., Stutz, F., Davis, L., and Rosbash, M. Curr. Biol., in press. 1997; See all ReferencesNeville et al. 1997).In the broader sense of where export receptors go next, questions for the future include: Do more exportins exist? If so, are they importin β–related or different? Are there specialized exportins that have distinct cargoes? Does signal transduction alter the exportins used? With exportins now in hand, meaningful experiments on the mechanism of export will soon follow.

The nuclear envelope environment and its cancer connections

Because of the association between aberrant nuclear structure and tumour grade, nuclear morphology is an indispensible criterion in the current pathological assessment of cancer. Components of the nuclear envelope environment have central roles in many aspects of cell function that affect tumour development and progression. As the roles of the nuclear envelope components, including nuclear pore complexes and nuclear lamina, are being deciphered in molecular detail there are opportunities to harness this knowledge for cancer therapeutics and biomarker development. In this Review, we summarize the progress that has been made in our understanding of the nuclear envelope and the implications of changes in this environment for cancer biology.

Domain-specific antibodies reveal multiple-site topology of Nup153 within the nuclear pore complex.

Nup153, one of the best characterized nuclear pore complex proteins (nucleoporins), plays a critical role in the import of proteins into the nucleus as well as in the export of RNAs and proteins from the nucleus. Initially an epitope of Nup153 was found to reside at the distal ring of the NPC, whereas more recently another epitope was localized to the nuclear ring moiety of the NPC. In an effort to more definitively determine the location of Nup153 within the 3-D architecture of the NPC we have generated domain-specific antibodies against distinct domains of Xenopus Nup153. With this approach we have found that the N-terminal domain is exposed at the nuclear ring of the NPC, whereas the zinc-finger domain of Nup153 is exposed at the distal ring of the NPC. In contrast, the C-terminal domain of Nup153 is not restricted to one particular subdomain of the NPC but rather appears to be highly flexible. Exogenous epitope-tagged hNup153 incorporated into Xenopus oocyte NPCs further underscored these findings. Our data illustrate that multiple domain-specific antibodies are essential to understanding the topology of a nucleoporin within the context of the NPC. Moreover, this approach has revealed new clues to the mechanisms by which Nup153 may contribute to nucleocytoplasmic transport.

Protein Arginine Methyltransferase 5 Accelerates Tumor Growth by Arginine Methylation of the Tumor Suppressor Programmed Cell Death 4

Programmed cell death 4 (PDCD4) has been described as a tumor suppressor, with high expression correlating with better outcomes in a number of cancer types. Yet a substantial number of cancer patients with high PDCD4 in tumors have poor survival, suggesting that oncogenic pathways may inhibit or change PDCD4 function. Here, we explore the significance of PDCD4 in breast cancer and identify protein arginine methyltransferase 5 (PRMT5) as a cofactor that radically alters PDCD4 function. Specifically, we find that coexpression of PDCD4 and PRMT5 in an orthotopic model of breast cancer causes accelerated tumor growth and that this growth phenotype is dependent on both the catalytic activity of PRMT5 and a site of methylation within the N-terminal region of PDCD4. In agreement with the xenograft model, elevated PDCD4 expression was found to correlate with worse outcome within the cohort of breast cancer patients whose tumors contain higher levels of PRMT5. These results reveal a new cofactor for PDCD4 that alters its tumor suppressor functions and point to the utility of PDCD4/PRMT5 status as both a prognostic biomarker and a potential target for chemotherapy.

The COPI Complex Functions in Nuclear Envelope Breakdown and Is Recruited by the Nucleoporin Nup153

Nuclear envelope breakdown is a critical step in the cell cycle of higher eukaryotes. Although integral membrane proteins associated with the nuclear membrane have been observed to disperse into the endoplasmic reticulum at mitosis, the mechanisms involved in this reorganization remain to be fully elucidated. Here, using Xenopus extracts, we report a role for the COPI coatomer complex in nuclear envelope breakdown, implicating vesiculation as an important step. We have found that a nuclear pore protein, Nup153, plays a critical role in directing COPI to the nuclear membrane at mitosis and that this event provides feedback to other aspects of nuclear disassembly. These results provide insight into how key steps in nuclear division are orchestrated.

Biology and biophysics of the nuclear pore complex and its components

Nucleocytoplasmic exchange of proteins and ribonucleoprotein particles occurs via nuclear pore complexes (NPCs) that reside in the double membrane of the nuclear envelope (NE). Significant progress has been made during the past few years in obtaining better structural resolution of the three-dimensional architecture of NPC with the help of cryo-electron tomography and atomic structures of domains from nuclear pore proteins (nucleoporins). Biophysical and imaging approaches have helped elucidate how nucleoporins act as a selective barrier in nucleocytoplasmic transport. Nucleoporins act not only in trafficking of macromolecules but also in proper microtubule attachment to kinetochores, in the regulation of gene expression and signaling events associated with, for example, innate and adaptive immunity, development and neurodegenerative disorders. Recent research has also been focused on the dynamic processes of NPC assembly and disassembly that occur with each cell cycle. Here we review emerging results aimed at understanding the molecular arrangement of the NPC and how it is achieved, defining the roles of individual nucleoporins both at the NPC and at other sites within the cell, and finally deciphering how the NPC serves as both a barrier and a conduit of active transport.

Versatility at the nuclear pore complex: lessons learned from the nucleoporin Nup153

The vertebrate pore protein Nup153 plays pivotal roles in nuclear pore function. In addition to being important to pore architecture, Nup153 is a key participant in both import and export. The scope of Nup153 function also extends beyond the canonical view of the pore as a trafficking gateway. During the transition into mitosis, Nup153 directs proteins involved in membrane remodeling to the nuclear envelope. As cells exit mitosis, Nup153 is recruited to the chromosomal surface, where nuclear pores are formed anew in a complicated process still under much experimental scrutiny. In addition, Nup153 is targeted for protease cleavage during apoptosis and in response to certain viral infections, providing molecular insight into pore reconfiguration during cell response. Overall, the versatile nature of Nup153 underscores an emerging view of the nuclear pore at the nexus of many key cellular processes.

Nucleocytoplasmic Transport: Integrating mRNA Production and Turnover with Export through the Nuclear Pore

Separation of the nucleus and cytoplasm, maintained by two membrane bilayers that form the nuclear envelope, allows for spatial control over transcription factors and signaling molecules. This compartmentalization further ensures the presence of specialized environments for different stages of gene expression, such as transcription and protein production. Selective exchange between these two compartments is clearly important as well. Whereas many types of active transport between the nucleus and cytoplasm rely on transport receptors in the importin-β superfamily, export of mRNA utilizes distinct soluble machinery (6, 92). Moreover, in general mRNA export does not depend on a specific motif in the cargo, as has been demonstrated in many other cases of receptor-cargo interactions (22). Recent progress in identifying soluble factors important to mRNA trafficking is beginning to reveal the molecular basis for functional coupling between steps in mRNA biogenesis and how such coupling, rather than a consensus motif, brings specificity to mRNA export. Studies with Saccharomyces cerevisiae revealed that the key modulators of cellular mRNA export are unrelated to canonical importin-β-related receptors. Specifically, yeast deficient in a gene called MEX67 accumulate poly(A)+ RNA in the nucleus (73). A second protein, Mtr2p, binds Mex67p, and this interaction is required for the export of poly(A)+ RNA in yeast (71, 77). In an independent avenue of investigation, involving metazoan cells and the simian type D retrovirus Mason Pfizer monkey virus, the cellular protein TAP was found to facilitate export of RNA containing the viral constitutive transport element (CTE) (8, 32). TAP, confirmed to be the human orthologue of Mex67p, has been redesignated NXF1 (nuclear export factor 1). NXF1 interacts with p15/NXT1, the presumed functional homologue of Mtr2p (33, 44). Although Mtr2p and p15 share no sequence similarity, the Mex67p-Mtr2p complex displays similar structural architecture to the NXF1-p15 heterodimer (21). Indeed, the mRNA export defect in yeast cells deficient in both Mex67p and Mtr2p can be rescued by expression of human NXF1 and its cofactor p15 (44). Expression knock-down studies using RNA interference have demonstrated that NXF1 and p15 are required for poly(A)+ RNA export (35, 84, 93), further strengthening the case for an evolutionarily conserved system of mRNA export that is distinct from the importin-β superfamily. Likewise, studies with Xenopus oocytes support the conclusion that the small GTPase Ran, a key modulator of importin-β-type receptors, is not key to mRNA export (10). However, the distinction between mRNA export and the importin-β family/Ran network is not absolute, as an importin-β family member has recently been implicated in mRNA export as well (74).

The Nucleoporin Nup153 Has Separable Roles in Both Early Mitotic Progression and the Resolution of Mitosis

Accurate inheritance of genomic content during cell division is dependent on synchronized changes in cellular organization and chromosome dynamics. Elucidating how these events are coordinated is necessary for a complete understanding of cell proliferation. Previous in vitro studies have suggested that the nuclear pore protein Nup153 is a good candidate for participating in mitotic coordination. To decipher whether this is the case in mammalian somatic cells, we reduced the levels of Nup153 in HeLa cells and monitored consequences on cell growth. Reduction of Nup153 resulted in a delay during the late stages of mitosis accompanied by an increase in unresolved midbodies. Depletion of Nup153 to an even lower threshold led to a pronounced defect early in mitosis and an accumulation of cells with multilobed nuclei. Although global nucleocytoplasmic transport was not significantly altered under these depletion conditions, the FG-rich region of Nup153 was required to rescue defects in late mitosis. Thus, this motif may play a specialized role as cells exit mitosis. Rescue of the multilobed nuclei phenotype, in contrast, was independent of the FG-domain, revealing two separable roles for Nup153 in the execution of mitosis.

Defects in nuclear pore assembly lead to activation of an Aurora B–mediated abscission checkpoint

In the absence of nuclear pore components, Aurora B delays abscission to ensure that daughter cells separate only when pores are fully formed.