蛋白质的入核运送和它在基因表达中的调节作用

蛋白质进入细胞核是由蛋白质分子内部的核定位信号（nuclear localization signal, NLS）引导的.NLS蛋白首先与NLS受体结合,然后在多种胞浆因子及核孔复合物蛋白的作用下穿过核孔、转位入核.蛋白质上存在NLS并不一定总能够引导蛋白质入核.当NLS被修饰或遮掩时,它们便不能被核转运装置所识别.因而,NLS的遮掩被解除之前,蛋白质一直被扣留在胞浆中.以调节转录因子的入核运送来控制转录因子的活性是基因表达调节的一个新概念,也是细胞生长和分化的另一水平的调节.     

Nuclear import substrates compete for a limited number of binding sites. Evidence for different classes of yeast nuclear import receptors

A nuclear receptor likely involved in nuclear protein import is described. Purified ATP-depleted yeast nuclei show saturable high-affinity binding of the yeast nuclear protein Mcm1. The dissociation constant for the binding is 0.5 microM, and the number of binding sites is approximately 3,500 per nucleus, equivalent to 10-30 binding sites per nuclear pore. Mcm1 competes with other yeast nuclear proteins Ste12 and Swi5, but not with Rap1 or Nop1, indicating that there may be different types of import receptors. Bound Mcm1 is resistant to extraction by nucleases, salt, and non-ionic detergent, but can be released by 5 M urea, suggesting that Mcm1 binds to a yeast equivalent of the nuclear pore complex-lamina fraction of higher eukaryotes.     

Mechanisms of receptor-mediated nuclear import and nuclear export

Nuclear transport of proteins and RNA occurs through the nuclear pore complex and is mediated by a superfamily of transport receptors known collectively as karyopherins. Karyopherins bind to their cargoes by recognition of specific nuclear localization signals or nuclear export signals. Transport through the nuclear pore complex is facilitated by transient interactions between the karyopherins and the nuclear pore complex. The interactions of karyopherins with their cargoes are regulated by the Ras-related GTPase Ran. Ran is assisted in this process by proteins that regulate its GTPase cycle and subcellular localization. In this review, we describe several of the major transport pathways that are conserved in higher and lower eukaryotes, with particular emphasis on the role of Ran. We highlight the latest advances in the structure and function of transport receptors and discuss recent examples of steroid hormone receptor import and regulation by signal transduction pathways. Understanding the molecular basis of nuclear transport may provide insight into human diseases by revealing how nucleocytoplasmic trafficking regulates protein activity.     

Computational identification of post‐translational modification‐based nuclear import regulations by characterizing nuclear localization signal‐import receptor interaction

The binding affinity between a nuclear localization signal (NLS) and its import receptor is closely related to corresponding nuclear import activity. PTM‐based modulation of the NLS binding affinity to the import receptor is one of the most understood mechanisms to regulate nuclear import of proteins. However, identification of such regulation mechanisms is challenging due to the difficulty of assessing the impact of PTM on corresponding nuclear import activities. In this study we proposed NIpredict, an effective algorithm to predict nuclear import activity given its NLS, in which molecular interaction energy components (MIECs) were used to characterize the NLS‐import receptor interaction, and the support vector regression machine (SVR) was used to learn the relationship between the characterized NLS‐import receptor interaction and the corresponding nuclear import activity. Our experiments showed that nuclear import activity change due to NLS change could be accurately predicted by the NIpredict algorithm. Based on NIpredict, we developed a systematic framework to identify potential PTM‐based nuclear import regulations for human and yeast nuclear proteins. Application of this approach has identified the potential nuclear import regulation mechanisms by phosphorylation of two nuclear proteins including SF1 and ORC6. Proteins 2014; 82:2783–2796. © 2014 Wiley Periodicals, Inc.     

Mediators of Nuclear Protein Import Target Karyophilic Proteins to Pore Complexes of Cytoplasmic Annulate Lamellae

Nuclear pore complexes are constitutive structures of the nuclear envelope in eukaryotic cells and represent the sites where transport of molecules between nucleus and cytoplasm takes place. However, pore complexes of similar structure, but with largely unknown functional properties, are long known to occur also in certain cytoplasmic cisternae that have been termed annulate lamellae (AL). To analyze the capability of the AL pore complex to interact with the soluble mediators of nuclear protein import and their karyophilic protein substrates, we have performed a microinjection study in stage VI oocytes ofXenopus laevis.In these cells AL are especially abundant and can easily be identified by light and electron microscopy. Following injection into the cytoplasm, fluorochrome-labeled mediators of two different nuclear import pathways, importin β and transportin, not only associate with the nuclear envelope but also with AL. Likewise, nuclear localization signals (NLS) of the basic and M9 type, but not nuclear export signals, confer targeting and transient binding of fluorochrome-labeled proteins to cytoplasmic AL. Mutation or deletion of the NLS signals prevents these interactions. Furthermore, binding to AL is abolished by dominant negative inhibitors of nuclear protein import. Microinjections of gold-coupled NLS-bearing proteins reveal specific gold decoration at distinct sites within the AL pore complex. These include such at the peripheral pore complex-attached fibrils and at the central “transporter” and closely resemble those of “transport intermediates” found in electron microscopic studies of the nuclear pore complex (NPC). These data demonstrate that AL can represent distinct sites within the cytoplasm of transient accumulation of nuclear proteins and that the AL pore complex shares functional binding properties with the NPC.     

Distinct nuclear import and export pathways mediated by members of the karyopherin β family

Transport of proteins into and out of the nucleus occurs through nuclear pore complexes (NPCs) and is mediated by the interaction of transport factors with nucleoporins at the NPC. Nuclear import of proteins containing classical nuclear localization signals (NLSs) is mediated by a heterodimeric protein complex, composed of karyopherin α and β1, that docks via β1 the NLS-protein to the NPC. The GTPase Ran; the RanGDP binding protein, p10; and the RanGTP binding protein, RanBP1 are involved in translocation of the docked NLS-protein into the nucleus. Recently, new distinct nuclear import and export pathways that are mediated by members of the karyopherin β family have been discovered. Karyopherin β2 mediates import of mRNA binding proteins, whereas karyopherin β3 and β4 mediate import of a set of ribosomal proteins. Two other β karyopherin family members, CRM1 and CAS, mediate export of proteins containing leucine-rich nuclear export signals (NES) and reexport of karyopherin α, respectively. This growing family contains new members that constitute potential transport factors for cargoes yet to be identified in the future. The common features of the members of karyopherin β family are the ability to bind RanGTP and the ability to interact directly with nucleoporins at the NPC. The challenge for the future will be to identify the distinct or, perhaps, overlapping cargo(es) for each member of the karyopherin β superfamily and to characterize the molecular mechanisms of translocation of karyopherins together with their cargoes through the NPC. J. Cell. Biochem. 70:231–239, 1998.© 1998 Wiley-Liss, Inc.     

The nuclear pore complex

The nuclear pore complex is the largest supramolecular complex that assembles in the eukaryotic cell. This structure is highly dynamic and must disassemble prior to mitosis and reassemble after the event. The directed movement of macromolecules into and out of the nucleus occurs through the nuclear pore complex, a potentially regulatory point for translocation. Using biochemical and genetic approaches, several nuclear pore complex proteins from yeast and vertebrates have been well characterized. Although very little is known about plant nuclear pore proteins, research is providing new information that indicates that plant nuclear pore complexes may have some unique features.     

Reconstitution of nuclear protein transport with semi-intact yeast cells

We have developed an in vitro nuclear protein import reaction from semi- intact yeast cells. The reaction uses cells that have been permeabilized by freeze-thaw after spheroplast formation. Electron microscopic analysis and antibody-binding experiments show that the nuclear envelope remains intact but the plasma membrane is perforated. In the presence of ATP and cytosol derived from yeast or mammalian cells, a protein containing the nuclear localization sequence (NLS) of SV40 large T-antigen is transported into the nucleus. Proteins with mutant NLSs are not imported. In the absence of cytosol, binding of NLS- containing proteins occurs at the nuclear envelope. N-ethylmaleimide treatment of the cytosol as well as antibodies to the nuclear pore protein Nsp1 inhibit import but not binding to the nuclear envelope. Yeast mutants defective in nuclear protein transport were tested in the in vitro import reaction. Semi-intact cells from temperature-sensitive nsp1 mutants failed to import but some binding to the nuclear envelope was observed. On the other hand, no binding and thus no import into nuclei was observed in semi-intact nsp49 cells which are mutated in another nuclear pore protein. Np13 mutants, which are defective for nuclear protein import in vivo, were also deficient in the binding step under the in vitro conditions. Thus, the transport defect in these mutants is at the level of the nucleus and the point at which nuclear transport is blocked can be defined.     

Organization and function of the small Tim complexes acting along the import pathway of metabolite carriers into mammalian mitochondria

Tim9, Tim10a, and Tim10b are members of the family of small Tim proteins located in the intermembrane space of mammalian mitochondria. In yeast, members of this family act along the TIM22 import pathway during import of metabolite carriers and other integral inner membrane proteins. Here, we show that the human small proteins form two distinct hetero-oligomeric complexes. A 70-kDa complex that contains Tim9 and Tim10a and a Tim9-10a-10b that is part of a higher molecular weight assembly of 450 kDa. This distribution among two complexes suggests Tim10b to be the functional homologue of yeast Tim12. Both human complexes are tightly associated with the inner membrane and, compared with yeast, soluble 70-kDa complexes appear to be completely absent in the intermembrane space. Thus, the function of soluble 70-kDa complexes as trans-site receptors for incoming carrier proteins is not conserved from lower to higher eukaryotes. During import, the small Tim complexes directly interact with human adenine nucleotide translocator (ANT) in transit in a metal-dependent manner. For insertion of carrier preproteins into the inner membrane, the human small Tim proteins directly interact with human Tim22, the putative insertion pore of the TIM22 translocase. However, in contrast to yeast, only a small fraction of Tim9-Tim10a-Tim10b complex is in a stable association with Tim22. We conclude that different mechanisms and specific requirements for import and insertion of mammalian carrier preproteins have evolved in higher eukaryotes.     

The nucleoporin Nup358/RanBP2 promotes nuclear import in a cargo- and transport receptor-specific manner

In vertebrates, the nuclear pore complex (NPC), the gate for transport of macromolecules between the nucleus and the cytoplasm, consists of approximately 30 different nucleoporins (Nups). The Nup and SUMO E3-ligase Nup358/RanBP2 are the major components of the cytoplasmic filaments of the NPC. In this study, we perform a structure-function analysis of Nup358 and describe its role in nuclear import of specific proteins. In a screen for nuclear proteins that accumulate in the cytoplasm upon Nup358 depletion, we identified proteins that were able to interact with Nup358 in a receptor-independent manner. These included the importin α/β-cargo DBC-1 (deleted in breast cancer 1) and DMAP-1 (DNA methyltransferase 1 associated protein 1). Strikingly, a short N-terminal fragment of Nup358 was sufficient to promote import of DBC-1, whereas DMAP-1 required a larger portion of Nup358 for stimulated import. Neither the interaction of RanGAP with Nup358 nor its SUMO-E3 ligase activity was required for nuclear import of all tested cargos. Together, Nup358 functions as a cargo- and receptor-specific assembly platform, increasing the efficiency of nuclear import of proteins through various mechanisms.     

Importins and Beyond: Non-Conventional Nuclear Transport Mechanisms

The movement of proteins between the cytoplasm and the nucleus conventionally involves the recognition of nuclear targeting signals by members of the importin (Imp) superfamily of nuclear transporters, followed by translocation through the nuclear envelope-embedded nuclear pore complexes (NPCs). It is becoming increasingly apparent, however, that distinct alternative pathways for nuclear transport exist and are relatively abundant. This review examines several of these novel pathways, including facilitation of Imp-dependent transport by microtubule motors, and Imp-independent pathways involving either other transport molecules such as the calcium-binding protein calmodulin or through direct binding to the components of the NPC. The existence of these pathways and the fact that many proteins appear to possess separate Imp-dependent and -independent nuclear import mechanisms ensure that the cell can function under conditions in which Imp-dependent transport is inhibited and/or modulate the efficiency of Imp-dependent transport itself, according to the need.     

Nuclear import in permeabilized protoplasts from higher plants has unique features.

The import of proteins into the nucleus is a poorly understood process that is thought to require soluble cytosolic factors in vertebrates and yeast. To test this model in plants and to identify components of the import apparatus, we developed a direct in vitro nuclear import assay by using tobacco protoplasts that were permeabilized without detergents such as digitonin or Triton X-100. Substrates were imported specifically by a mechanism that required only guanine nucleotides. Moreover, in vitro import did not require exogenous cytosol. To investigate this novel finding, we isolated a full-length cDNA encoding an Arabidopsis homolog of vertebrate and yeast nuclear localization signal receptors and produced an affinity-purified antibody. The plant receptor was tightly associated with cellular components in permeabilized protoplasts, even in the presence of 0.1% Triton X-100, indicating that this factor and probably others were retained to an extent sufficient to support import. The lectin wheat germ agglutinin bound to the nucleus; however, it did not block translocation in our system, indicating that direct interaction with polysaccharide modifications at the nuclear pore complex was probably not essential for import in plants. Other features of in vitro import included reduced but significant import at low temperature.     

A lack of SUMO conjugation affects cNLS-dependent nuclear protein import in yeast

Yeast SUMO (Smt3) and its mammalian ortholog SUMO-1 are ubiquitin-like proteins that can reversibly be conjugated to other proteins. Among the substrates for SUMO modification in vertebrates are RanGAP1 and RanBP2/Nup358, two proteins previously implicated in nucleocytoplasmic transport. Sumoylated RanGAP1 binds to the nuclear pore complex via RanBP2/Nup358, a giant nucleoporin, which was recently reported to act as a SUMO E3 ligase on some nuclear substrates. However, no direct evidence for a role of the SUMO system in nuclear transport has been obtained so far. By the use of conditional yeast mutants, we examined nuclear protein import in vivo. We show here that cNLS-dependent protein import is impaired in mutants with defective Ulp1 and Uba2, two enzymes involved in the SUMO conjugation reaction. In contrast, other transport pathways such as rgNLS-mediated protein import and mRNA export are not affected. Furthermore, we find that the yeast importin-alpha subunit Srp1 accumulates in the nucleus of ulp1 and uba2 strains but not the importin-beta subunit Kap95, indicating that a lack of Srp1 export might impair cNLS import. In summary, our results provide evidence that SUMO modification in yeast, as has been suspected for vertebrates, plays an important role in nucleocytoplasmic trafficking.     

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.     

Nucleocytoplasmic transport of proteins

In eukaryotic cells, the movement of macromolecules between the nucleus and cytoplasm occurs through the nuclear pore complex (NPC)--a large protein complex spanning the nuclear envelope. The nuclear transport of proteins is usually mediated by a family of transport receptors known as karyopherins. Karyopherins bind to their cargoes via recognition of nuclear localization signal (NLS) for nuclear import or nuclear export signal (NES) for export to form a transport complex. Its transport through NPC is facilitated by transient interactions between the karyopherins and NPC components. The interactions of karyopherins with their cargoes are regulated by GTPase Ran. In the current review, we describe the NPC structure, NLS, and NES, as well as the model of classic Ran-dependent transport, with special emphasis on existing alternative mechanisms; we also propose a classification of the basic mechanisms of protein transport regulation.     

Early localization of NPA58, a rat nuclear pore-associated protein, to the reforming nuclear envelope during mitosis

We have studied the mitotic reassembly of the nuclear envelope, using antibodies to nuclear marker proteins and NPA58 in F-111 rat fibroblast cells. In earlier studies we have proposed that NPA58, a 58 kDa rat nuclear protein, is involved in nuclear protein import. In this report, NPA58 is shown to be localized on the cytoplasmic face of the envelope in interphase cells, in close association with nuclear pores. In mitotic cells NPA58 is dispersed in the cytoplasm till anaphase. The targeting of NPA58 to the reforming nuclear envelope in early telophase coincides with the recruitment of a well-characterized class of nuclear pore proteins recognized by the antibody mAb 414, and occurs prior to the incorporation of lamin B1 into the envelope. Significant protein import activity is detectable only after localization of NPA58 in the newly-formed envelope. The early targeting of NPA58 is consistent with its proposed role in nuclear transport.     

Prion formation by a yeast GLFG nucleoporin

The self-assembly of proteins into higher order structures is both central to normal biology and a dominant force in disease. Certain glutamine/asparagine (Q/N)-rich proteins in the budding yeast Saccharomyces cerevisiae assemble into self-replicating amyloid-like protein polymers, or prions, that act as genetic elements in an entirely protein-based system of inheritance. The nuclear pore complex (NPC) contains multiple Q/N-rich proteins whose self-assembly has also been proposed to underlie structural and functional properties of the NPC. Here we show that an essential sequence feature of these proteins—repeating GLFG motifs—strongly promotes their self-assembly into amyloids with characteristics of prions. Furthermore, we demonstrate that Nup100 can form bona fide prions, thus establishing a previously undiscovered ability of yeast GLFG nucleoporins to adopt this conformational state in vivo.     

Nuclear Import of Chromatin Remodeler Isw1 Is Mediated by Atypical Bipartite cNLS and Classical Import Pathway

The protein Isw1 of Saccharomyces cerevisiae is an imitation‐switch chromatin‐remodeling factor. We studied the mechanisms of its nuclear import and found that the nuclear localization signal (NLS) mediating the transport of Isw1 into the nucleus is located at the end of the C‐terminus of the protein (aa1079–1105). We show that it is an atypical bipartite signal with an unconventional linker of 19 aa (KRIR X₁₉ KKAK) and the only nuclear targeting signal within the Isw1 molecule. The efficiency of Isw1 nuclear import was found to be modulated by changes to the amino acid composition in the vicinity of the KRIR motif, but not by the linker length. Live‐cell imaging of various karyopherin mutants and in vitro binding assays of Isw1NLS to importin‐α revealed that the nuclear translocation of Isw1 is mediated by the classical import pathway. Analogous motifs to Isw1NLS are highly conserved in Isw1 homologues of other yeast species, and putative bipartite cNLS were identified in silico at the end of the C‐termini of imitation switch (ISWI) proteins from higher eukaryotes. We suggest that the C‐termini of the ISWI family proteins play an important role in their nuclear import.