Evidence for Ca2+- and ATP-sensitive peripheral channels in nuclear pore complexes.

In eukaryotic cells the nuclear envelope (NE) serves as a functional barrier between cytosol and nucleoplasm perforated by nuclear pore complexes (NPCs). Both active and passive transport of ions and macromolecules are thought to be mediated by the centrally located large NPC channel. However, 3-dimensional imaging of NPCs based on electron microscopy indicates the existence of additional small channels of unknown function located in the NPC periphery. By means of the recently developed nuclear hourglass technique that measures NE electrical conductance, we evaluated passive electrically driven transport through NPCs. In isolated Xenopus laevis oocyte nuclei, we varied ambient Ca2+ and ATP in the cytosolic solution and/or chelated Ca2+ in the perinuclear stores in order to assess the role of Ca2+ in regulating passive ion transport. We noticed that NE electrical conductance is large under conditions where macromolecule permeability is known to be low. In addition, atomic force microscopy applied to native NPCs detects multiple small pores in the NPC periphery consistent with channel openings. Peripheral pores were detectable only in the presence of ATP. We conclude that NPC transport of ions and macromolecules occurs through different routes. We present a model in which NE ion flux does not occur through the central NPC channel but rather through Ca2+- and ATP-activated peripheral channels of individual NPCs.     

Dynamics of nuclear pore complex organization through the cell cycle

In eukaryotic cells, all macromolecules that traffic between the nucleus and the cytoplasm cross the double nuclear membrane through nuclear pore complexes (NPCs). NPCs are elaborate gateways that allow efficient, yet selective, translocation of many different macromolecules. Their protein composition has been elucidated, but how exactly these nucleoporins come together to form the pore is largely unknown. Recent data suggest that NPCs are composed of an extremely stable scaffold on which more dynamic, exchangeable parts are assembled. These could be targets for molecular rearrangements that change nuclear pore transport properties and, ultimately, the state of the cell.     

Hot spot formation in the nuclear envelope of oocytes in response to steroids.

A Glucocorticoid-sensitive cell rapidly responds to hormone stimulation with bidirectional exchange of specific macromolecules between cytosol and nucleus. Glucocorticoid-initiated macromolecules (GIMs) must overcome the nuclear envelope (NE) to enter or leave the nucleus. GIM translocation occurs through nuclear pore complexes (NPCs) that span the NE. We investigated the question whether transport of GIMs through NPCs occurs random or involves selected groups of NPCs (hot spots). Glucocorticoid receptors were expressed in Xenopus laevis oocytes and GIM transport was activated by triamcinolone acetonide, a potent synthetic glucocorticoid analogon. Glucocorticoid receptors associated with the NE and the chromatin were identified using western blot analysis and, at single molecule level, atomic force microscopy. Fluorescence-labeled dextran was used to describe passive NE permeability. We observed that after hormone injection (i) small GIMs, most likely GRs, localize within seconds on both sides of the NE. (ii) large GIMs, most likely ribonucleoproteins, localize within minutes on NPCs at the nucleoplasmic side (iii) both small and large GIMs accumulate on selected NPC clusters (iv) NE permeability transiently decreases when GIMs attach to NPCs. We conclude that GIM transport across the nuclear barrier does not randomly take place but is carried out by a selected population of NPCs.     

Exceptional structural and mechanical flexibility of the nuclear pore complex

Nuclear pore complexes (NPCs) mediate all transport between the cytosol and the nucleus and therefore take centre stage in physiology. While transport through NPCs has been extensively investigated little is known about their structural and barley anything about their mechanical flexibility. Structural and mechanical flexibility of NPCs, however, are presumably of key importance. Like the cell and the cell nucleus, NPCs themselves are regularly exposed to physiological mechanical forces. Besides, NPCs reveal striking transport properties which are likely to require fairly high structural flexibility. The NPC transports up to 1,000 molecules per second through a physically 9 nm wide channel which repeatedly opens to accommodate macromolecules significantly larger than its physical diameter. We hypothesised that NPCs possess remarkable structural and mechanical stability. Here, we tested this hypothesis at the single NPC level using the nano‐imaging and probing approach atomic force microscopy (AFM). AFM presents the NPC as a highly flexible structure. The NPC channel dilates by striking 35% on exposure to trans‐cyclohexane‐1,2‐diol (TCHD), which is known to transiently collapse the hydrophobic phase in the NPC channel like receptor–cargo complexes do in transit. It constricts again to its initial size after TCHD removal. AFM‐based nano‐indentation measurements show that the 50 nm long NPC basket can astonishingly be squeezed completely into the NPC channel on exposure to incremental mechanical loads but recovers its original vertical position within the nuclear envelope plane when relieved. We conclude that the NPC possesses exceptional structural and mechanical flexibility which is important to fulfilling its functions. J. Cell. Physiol. 226: 675–682, 2011. © 2010 Wiley‐Liss, Inc.     

Virtual gating and nuclear transport: the hole picture

The eukaryotic nucleus is surrounded by a protective nuclear envelope, which is perforated by trafficking machines termed nuclear pore complexes (NPCs). The NPCs are the sole mediators of exchange between the nucleus and the cytoplasm. Small molecules pass through the NPCs unchallenged; however, large macromolecules are excluded unless chaperoned across by transport factors. Here, we suggest a model, termed ‘virtual gating’, to explain the mechanism of this rapid and selective macromolecular trafficking.     

The human nuclear pore complex as revealed by cryo-electron tomography

Nuclear pore complexes (NPCs) are the sole passage through the nuclear envelope, connecting the cytoplasm to the nucleoplasm. These gigantic molecular machines, over 100 MDa in molecular weight, allow free diffusion of small molecules and ions while mediating selective energy-dependent nucleocytoplasmic transport of large macromolecules. Here, we applied cryo-electron tomography to human fibroblast cells, reconstructing their nuclear envelopes without applying any purification steps. From these reconstructions, we extracted subtomograms containing individual NPCs and utilized in silico subtomogram averaging procedures to determine the structure of the mammalian pore complex at a resolution of ～6.6?nm. Beyond revealing the canonical features of the human NPC, our analysis identified inner lateral channels and fusing bridge-like structures, suggesting alternative routes of peripheral nuclear passage. Finally, we concluded from our structural analysis that the human NPC is structurally distinct from that of lower eukaryotes in terms of dimension and organization but resembles its amphibian (frog) counterpart.     

核孔复合物的结构、组装及功能

核孔复合物(NPC)是一个巨型分子复合物,相对分子质量约125×106。脊椎动物的NPC由大约30种蛋白质组成,这些蛋白质的序列大多具有FG(苯丙氨酸-甘氨酸)重复序列。NPC锚定于双层核膜上,并且是物质跨核膜运输的惟一通道,它可快速介导小分子物质的被动运输以及大分子物质的主动运输过程。虽然NPC具有较大的相对分子质量和复杂的结构,但它可在细胞分裂过程中分离并重新组装。生物大分子经NPC的跨核膜运输直接影响真核细胞的生长、增殖、分化、发育等多种生命活动。本文重点介绍NPC的结构、组装及其功能特点。     

Nuclear accumulation of plasmid DNA can be enhanced by non-selective gating of the nuclear pore

One of the major obstacles in non-viral gene transfer is the nuclear membrane. Attempts to improve the transport of DNA to the nucleus through the use of nuclear localization signals or importin-β have achieved limited success. It has been proposed that the nuclear pore complexes (NPCs) through which nucleocytoplasmic transport occurs are filled with a hydrophobic phase through which hydrophobic importins can dissolve. Therefore, considering the hydrophobic nature of the NPC channel, we evaluated whether a non-selective gating of nuclear pores by trans-cyclohexane-1,2-diol (TCHD), an amphipathic alcohol that reversibly collapses the permeability barrier of the NPCs, could be obtained and used as an alternative method to facilitate nuclear entry of plasmid DNA. Our data demonstrate for the first time that TCHD makes the nucleus permeable for both high molecular weight dextrans and plasmid DNA (pDNA) at non-toxic concentrations. Furthermore, in line with these observations, TCHD enhanced the transfection efficacy of both naked DNA and lipoplexes. In conclusion, based on the proposed structure of NPCs we succeeded to temporarily open the NPCs for macromolecules as large as pDNAs and demonstrated that this can significantly enhance non-viral gene delivery.     

Peering through the pore: nuclear pore complex structure,assembly, and function

Nuclear pore complexes (NPCs) are large proteinaceous assemblies that provide the only known portals for exchanging macromolecules between the nucleus and cytoplasm. This includes the movement of small molecules and the selective, facilitated transport of large proteins and RNAs. Faithful, continuous NPC assembly is key for maintaining normal physiological function and is closely tied to proper cell division. This review focuses on the most outstanding issues involving NPC structure, assembly, and function.     

Nuclear pore complex assembly through the cell cycle: regulation and membrane organization

In eukaryotes, all macromolecules traffic between the nucleus and the cytoplasm through nuclear pore complexes (NPCs), which are among the largest supramolecular assemblies in cells. Although their composition in yeast and metazoa is well characterized, understanding how NPCs are assembled and form the pore through the double membrane of the nuclear envelope and how both processes are controlled still remains a challenge. Here, we summarize what is known about the biogenesis of NPCs throughout the cell cycle with special focus on the membrane reorganization and the regulation that go along with NPC assembly.     

The permeability barrier of nuclear pore complexes appears to operate via hydrophobic exclusion

Nuclear pore complexes (NPCs) restrict the nucleocytoplasmic flux of most macromolecules, but permit facilitated passage of nuclear transport receptors and their cargo complexes. We found that a simple hydrophobic interaction column can mimic the selectivity of NPCs surprisingly well and that nuclear transport receptors appear to be the most hydrophobic soluble proteins. This suggests that surface hydrophobicity represents a major sorting criterion of NPCs. The rate of NPC passage of cargo-receptor complexes is, however, not dominated just by properties of the receptors. We found that large cargo domains drastically hinder NPC passage and require more than one receptor molecule for rapid translocation. This argues against a rigid translocation channel and instead suggests that NPC passage involves a partitioning of the entire translocating species into a hydrophobic phase, whereby the receptor:cargo ratio determines the solubility in that permeability barrier. Finally, we show that interfering with hydrophobic interactions causes a reversible collapse of the permeability barrier of NPCs, which is consistent with the assumption that the barrier is formed by phenylalanine-rich nucleoporin repeats that attract each other through hydrophobic interactions.     

The molecular mechanism of transport of macromolecules through nuclear pore complexes

Trafficking of macromolecules between nuclear and cytoplasmic compartments takes place through the nuclear pore complexes (NPCs) of the nuclear envelope. Nuclear trafficking involves a complex series of interactions between cargo, soluble transport factors (carriers) and nuclear pore proteins (nucleoporins) that are orchestrated by the Ras-family GTPase Ran. The primary role of Ran is probably to establish directionality and to sort molecules to be transported by controlling the interaction between carriers and cargoes, so that they bind in one compartment but dissociate in the other. Translocation of carriers and cargo-carrier complexes through NPCs requires interactions between the carriers and nucleoporins that contain distinctive tandem sequence repeats based on cores rich in glycine and phenylalanine residues that are separated by hydrophilic linkers. Much recent work has focused on these interactions and, in particular, their specificity, regulation and function. Evidence is accumulating that carriers move through the NPC by distinct but overlapping routes using specific subsets of nucleoporins.     

Characterisation of the passive permeability barrier of nuclear pore complexes

Nuclear pore complexes (NPCs) restrict uncontrolled nucleocytoplasmic fluxes of inert macromolecules but permit facilitated translocation of nuclear transport receptors and their cargo complexes. We probed the passive barrier of NPCs and observed sieve‐like properties with a dominating mesh or channel radius of 2.6 nm, which is narrower than proposed earlier. A small fraction of diffusion channels has a wider opening, explaining the very slow passage of larger molecules. The observed dominant passive diameter approximates the distance of adjacent hydrophobic clusters of FG repeats, supporting the model that the barrier is made of FG repeat domains cross‐linked with a spacing of an FG repeat unit length. Wheat germ agglutinin and the dominant‐negative importin β^45‐462 fragment were previously regarded as selective inhibitors of facilitated NPC passage. We now observed that they do not distinguish between the passive and the facilitated mode. Instead, their inhibitory effect correlates with the size of the NPC‐passing molecule. They have little effect on small species, inhibit the passage of green fluorescent protein‐sized objects >10‐fold and virtually block the translocation of larger ones. This suggests that passive and facilitated NPC passage proceed through one and the same permeability barrier.     

Nuclear pore complex is able to transport macromolecules with diameters of about 39 nm

Bidirectional transport of macromolecules between the nucleus and the cytoplasm occurs through the nuclear pore complexes (NPCs) by a signal-mediated mechanism that is directed by targeting signals (NLSs) residing on the transported molecules or "cargoes." Nuclear transport starts after interaction of the targeting signal with soluble cellular receptors. After the formation of the cargo-receptor complex in the cytosol, this complex crosses the NPC. Herein, we use gold particles of various sizes coated with cargo-receptor complexes to determine precisely how large macromolecules crossing the NPC by the signal-mediated transport mechanism could be. We found that cargo-receptor-gold complexes with diameter close to 39 nm could be translocated by the NPC. This implies that macromolecules much larger than the assumed functional NPC diameter of 26 nm can be transported into the karyoplasm. The physiological relevance of this finding was supported by the observation that intact nucleocapsids of human hepatitis B virus with diameters of 32 and 36 nm are able to cross the nuclear pore without disassembly.     

Nuclear pore complex-a coat specifically tailored for the nuclear envelope

Nuclear pore complexes (NPCs) are highly selective transport gates that enable the bi-directional traffic of macromolecules across the nuclear envelope (NE). NPCs are located at the fusion pores between the inner and outer membranes of the NE and are built from a common set of ～30 different proteins, nucleoporins. Remarkably, recent proteomic, bioinformatic, and structural studies have provided firm evidence that key structural nucleoporins share common ancestry with elements of coated vesicles, indicating an evolutionary link between these structures. This has provided novel insight into the origin of NPCs and may help us to better functionally characterize these fundamental components of eukaryotic cells.     

核孔复合体的结构及其功能

核孔复合体(Nuclear pore complexes, NPCs)镶嵌在核膜上,是细胞核与细胞质之间的唯一通道。冷冻电子X射线断层扫描将环状NPCs分为三个环,分别称为胞质环、内环和核质环,胞质环上附有胞质纤丝,核质环上附有核篮。由于物种不同,NPCs由30～50多种不同的核孔蛋白(nucleoporins, Nups)组成,但结构和功能高度保守。根据其结构、氨基酸序列,NPCs定位和功能,Nups被分为跨膜Nups、屏障Nups、骨架Nups、胞质纤丝Nups和核篮Nups。相互间作用稳定、紧密连接的数个Nups可组成亚复合体。为了应对不同生理需要,NPCs处于高度动态变化中,间期和有丝分裂期均可通过组装和去组装改变核孔数量和功能。NPCs的主要功能是调控核质转运,小分子物质可自由扩散,大分子物质则需在核转位信号和转运载体的介导下以主动运输的方式进行转运。除了核质转运这一主要功能外,Nups还能以一个独立于转运的方式影响基因组功能。通过影响染色质结构和影响转录调控元件对靶基因的访问,Nups促进或抑制转录。在酵母,Nups介导的基因调控主要由位于NPCs中的Nups执行;在多细胞生物,不仅NPCs中的Nups,核质内游离的Nups也具有基因调控功能。此外,Nups还能通过参与形成染色质边界和形成转录记忆对基因进行调控。在增殖细胞, Nups通过与DNA修复机器相互作用,参与DNA损伤修复,保护基因组完整性。有丝分裂时,Nups协助核膜解体和中心体迁移,并通过作用于着丝粒来控制有丝分裂组件的空间定位与活性,稳定它们与微管之间的相互作用,保证纺锤体正常组装和染色体准确分离。总之,NPCs与生物分子的核质转运、基因表达和细胞周期密切相关,它的结构和功能的稳定是真核细胞生长、增殖、分化等生命活动的基本保证。     

Passive and facilitated transport in nuclear pore complexes is largely uncoupled

Nuclear pore complexes provide the sole gateway for the exchange of material between nucleus and cytoplasm of interphase eukaryotic cells. They support two modes of transport: passive diffusion of ions, metabolites, and intermediate-sized macromolecules and facilitated, receptor-mediated translocation of proteins, RNA, and ribonucleoprotein complexes. It is generally assumed that both modes of transport occur through a single diffusion channel located within the central pore of the nuclear pore complex. To test this hypothesis, we studied the mutual effects between transporting molecules utilizing either the same or different modes of translocation. We find that the two modes of transport do not interfere with each other, but molecules utilizing a particular mode of transport do hinder motion of others utilizing the same pathway. We therefore conclude that the two modes of transport are largely segregated.