Comparative Multiplexed Mass Spectrometric Analyses of Endogenously Expressed Yeast Nuclear and Cytoplasmic Exosomes

Here we combined tandem affinity purification with several mass-spectrometry-based approaches to gain more insight into the composition and structure of the yeast nuclear-cytoplasmic exosome protein complex. The yeast exosome fulfills several different functions in RNA metabolism and can be localized in both the cytoplasm and the nucleus. These two exosome complexes differ in protein composition, although they share several constituents. We focused on these differences in composition by selecting a nuclear-specific exosome protein (Rrp6) and a cytoplasmic-specific protein (Ski7) as the tandem-affinity-purification-tagged affinity bait protein. First, we investigated both these purified exosome assemblies by macromolecular mass spectrometry (MS) to determine the stability and mass of the intact protein complexes and to obtain information on composition and core constituents. We used tandem MS on these intact protein complexes to further probe the composition and to obtain insight into the peripheral nature of some of the constituents. Finally, we combine stable isotope labeling with MS to quantitate differences in exosome composition and posttranslational modifications. We identified a few phosphorylation sites that are differentially regulated between the cytoplasmic exosome and the nuclear exosome. From all of these data, we conclude that the yeast nuclear exosome and the cytoplasmic exosome share a common stable core complex, but are decorated with quite a few differing peripheral proteins. We show that the nuclear exosome selectively copurifies with the α/β importin heterodimer, which is known to be involved in the transport of proteins across the nuclear membrane.     

Structural basis of importin-α-mediated nuclear transport for Ku70 and Ku80

Ku70 and Ku80 form a heterodimeric complex involved in multiple nuclear processes. This complex plays a key role in DNA repair due to its ability to bind DNA double-strand breaks and facilitate repair by the nonhomologous end-joining pathway. Ku70 and Ku80 have been proposed to contain bipartite and monopartite nuclear localization sequences (NLSs), respectively, that allow them to be translocated to the nucleus independently of each other via the classical importin-α (Impα)/importin-β-mediated nuclear import pathway. To determine the structural basis of the recognition of Ku70 and Ku80 proteins by Impα, we solved the crystal structures of the complexes of Impα with the peptides corresponding to the Ku70 and Ku80 NLSs. Our structural studies confirm the binding of the Ku80 NLS as a classical monopartite NLS but reveal an unexpected binding mode for Ku70 NLS with only one basic cluster bound to the receptor. Both Ku70 and Ku80 therefore contain monopartite NLSs, and sequences outside the basic cluster make favorable interactions with Impα, suggesting that this may be a general feature in monopartite NLSs. We show that the Ku70 NLS has a higher affinity for Impα than the Ku80 NLS, consistent with more extensive interactions in its N-terminal region. The prospect of nuclear import of Ku70 and Ku80 independently of each other provides a powerful regulatory mechanism for the function of the Ku70/Ku80 heterodimer and independent functions of the two proteins.     

The N-terminal domain of the mammalian nucleoporin p62 interacts with other nucleoporins of the FXFG family during interphase

Nuclear pore complexes (NPCs) provide the only sites for macromolecular transport between nucleus and cytoplasm. The nucleoporin p62, a component of higher eukaryotic NPCs, is located at the central gated channel and involved in nuclear trafficking of various cargos. p62 is organized into an N-terminal segment that contains FXFG repeats and binds the soluble transport factor NTF2, whereas the C-terminal portion associates with other nucleoporins and importin-beta1. We have now identified new components that interact specifically with the p62 N-terminal domain. Using the p62 N-terminal segment as bait, we affinity-purified nucleoporins Nup358, Nup214 and Nup153 from crude cell extracts. In ligand binding assays, the N-terminal p62 segment associated with Nup358 and p62, suggesting their direct binding to the p62 N-terminal portion. Furthermore, p62 was isolated in complex with Nup358, Nup214 and Nup153 from growing HeLa cells, indicating that the interactions Nup358/p62, Nup214/p62 and p62/Nup153 also occur in vivo. The formation of Nup358/p62 and p62/Nup153 complexes was restricted to interphase cells, whereas Nup214/p62 binding was detected in interphase as well as during mitosis. Our results support a model of complex interactions between FXFG containing nucleoporins, and we propose that some of these interactions may contribute to the movement of cargo across the NPC.     

Distinct roles for classical nuclear import receptors in the growth of multinucleated muscle cells

Proper muscle function is dependent on spatial and temporal control of gene expression in myofibers. Myofibers are multinucleated cells that are formed, repaired and maintained by the process of myogenesis in which progenitor myoblasts proliferate, differentiate and fuse. Gene expression is dependent upon proteins that require facilitated nuclear import, however little is known about the regulation of nucleocytoplasmic transport during the formation of myofibers. We analyzed the role of karyopherin alpha (KPNA), a key classical nuclear import receptor, during myogenesis. We established that five karyopherin alpha paralogs are expressed by primary mouse myoblasts in vitro and that their steady-state levels increase in multinucleated myotubes, suggesting a global increase in demand for classical nuclear import during myogenesis. We used siRNA-mediated knockdown to identify paralog-specific roles for KPNA1 and KPNA2 during myogenesis. KPNA1 knockdown increased myoblast proliferation, whereas KPNA2 knockdown decreased proliferation. In contrast, no proliferation defect was observed with KPNA4 knockdown. Only knockdown of KPNA2 decreased myotube growth. These results identify distinct pathways involved in myoblast proliferation and myotube growth that rely on specific nuclear import receptors suggesting that regulation of classical nuclear import pathways likely plays a critical role in controlling gene expression in skeletal muscle.     

How viruses access the nucleus

Many viruses depend on nuclear proteins for replication. Therefore, their viral genome must enter the nucleus of the host cell. In this review we briefly summarize the principles of nucleocytoplasmic transport, and then describe the diverse strategies used by viruses to deliver their genomes into the host nucleus. Some of the emerging mechanisms include: (1) nuclear entry during mitosis, when the nuclear envelope is disassembled, (2) viral genome release in the cytoplasm followed by entry of the genome through the nuclear pore complex (NPC), (3) capsid docking at the cytoplasmic side of the NPC, followed by genome release, (4) nuclear entry of intact capsids through the NPC, followed by genome release, and (5) nuclear entry via virus-induced disruption of the nuclear envelope. Which mechanism a particular virus uses depends on the size and structure of the virus, as well as the cellular cues used by the virus to trigger capsid disassembly and genome release. This article is part of a Special Issue entitled: Regulation of Signaling and Cellular Fate through Modulation of Nuclear Protein Import.     

Expanding the Definition of the Classical Bipartite Nuclear Localization Signal

Nuclear localization signals (NLSs) are amino acid sequences that target cargo proteins into the nucleus. Rigorous characterization of NLS motifs is essential to understanding and predicting pathways for nuclear import. The best‐characterized NLS is the classical NLS (cNLS), which is recognized by the cNLS receptor, importin‐α. cNLSs are conventionally defined as having one (monopartite) or two clusters of basic amino acids separated by a 9‐12 aa linker (bipartite). Motivated by the finding that Ty1 integrase, which contains an unconventional putative bipartite cNLS with a 29 aa linker, exploits the classical nuclear import machinery, we assessed the functional boundaries for linker length within a bipartite cNLS. We confirmed that the integrase cNLS is a bona fide bipartite cNLS, then carried out a systematic analysis of linker length in an obligate bipartite cNLS cargo, which revealed that some linkers longer than conventionally defined can function in nuclear import. Linker function is dependent on the sequence and likely the inherent flexibility of the linker. Subsequently, we interrogated the Saccharomyces cerevisiae proteome to identify cellular proteins containing putative long bipartite cNLSs. We experimentally confirmed that Rrp4 contains a bipartite cNLS with a 25 aa linker. Our studies show that the traditional definition of bipartite cNLSs is too restrictive and linker length can vary depending on amino acid composition.     

Classical NLS proteins from Saccharomyces cerevisiae

Proteins can enter the nucleus through various receptor-mediated import pathways. One class of import cargos carries a classical nuclear localization signal (cNLS) containing a short cluster of basic residues. This pathway involves importin α (Impα), which possesses the cNLS binding site, and importin β (Impβ), which translocates the import complex through the nuclear pore complex. The defining criteria for a cNLS protein from Saccharomyces cerevisiae are an in vivo import defect in Impα and Impβ mutants, direct binding to purified Impα, and stimulation of this binding by Impβ. We show for the first time that endogenous S. cerevisiae proteins Prp20, Cdc6, Swi5, Cdc45, and Clb2 fulfill all of these criteria identifying them as authentic yeast cNLS cargos. Furthermore, we found that the targeting signal of Prp20 is a bipartite cNLS and that of Cdc6 is a monopartite cNLS. Basic residues present within these motifs are of different significance for the interaction with Impα. We determined the binding constants for import complexes containing the five cNLS proteins by surface plasmon resonance spectrometry. The dissociation constants for cNLS/α/β complexes differ considerably, ranging from 1 nM for Cdc6 to 112 nM for Swi5, suggesting that the nuclear import kinetics is determined by the strength of cNLS/Impα binding. Impβ enhances the affinity of Impα for cNLSs approximately 100-fold. This stimulation of cNLS binding to Impα results from a faster association in the presence of Impβ, whereas the dissociation rate is unaffected by Impβ. This implies that, after entry into the nucleus, the release of Impβ by the Ran guanosine triphosphatase (Ran GTPase) from the import complex is not sufficient to dissociate the cNLS/Impα subcomplex. Our observation that the nucleoporin Nup2, which had been previously shown to release the cNLS from Impα in vitro, is required for efficient import of all the genuine cNLS cargos supports a general role of Nup2 in import termination.