Chm7 and Heh1 collaborate to link nuclear pore complex quality control with nuclear envelope sealing

The integrity of the nuclear envelope barrier relies on membrane remodeling by the ESCRTs, which seal nuclear envelope holes and contribute to the quality control of nuclear pore complexes (NPCs); whether these processes are mechanistically related remains poorly defined. Here, we show that the ESCRT‐II/III chimera, Chm7, is recruited to a nuclear envelope subdomain that expands upon inhibition of NPC assembly and is required for the formation of the storage of improperly assembled NPCs (SINC) compartment. Recruitment to sites of NPC assembly is mediated by its ESCRT‐II domain and the LAP2‐emerin‐MAN1 (LEM) family of integral inner nuclear membrane proteins, Heh1 and Heh2. We establish direct binding between Heh2 and the “open” forms of both Chm7 and the ESCRT‐III, Snf7, and between Chm7 and Snf7. Interestingly, Chm7 is required for the viability of yeast strains where double membrane seals have been observed over defective NPCs; deletion of CHM7 in these strains leads to a loss of nuclear compartmentalization suggesting that the sealing of defective NPCs and nuclear envelope ruptures could proceed through similar mechanisms.     

Lumenal interactions in nuclear pore complex assembly and stability

Nuclear pore complexes (NPCs) provide a gateway for the selective transport of macromolecules across the nuclear envelope (NE). Although we have a solid understanding of NPC composition and structure, we do not have a clear grasp of the mechanism of NPC assembly. Here, we demonstrate specific defects in nucleoporin distribution in strains lacking Heh1p and Heh2p-two conserved members of the LEM (Lap2, emerin, MAN1) family of integral inner nuclear membrane proteins. These effects on nucleoporin localization are likely of functional importance as we have defined specific genetic interaction networks between HEH1 and HEH2, and genes encoding nucleoporins in the membrane, inner, and outer ring complexes of the NPC. Interestingly, expression of a domain of Heh1p that resides in the NE lumen is sufficient to suppress both the nucleoporin mislocalization and growth defects in heh1Δpom34Δ strains. We further demonstrate a specific physical interaction between the Heh1p lumenal domain and the massive cadherin-like lumenal domain of the membrane nucleoporin Pom152p. These findings support a role for Heh1p in the assembly or stability of the NPC, potentially through the formation of a lumenal bridge with Pom152p.     

Direct binding of ESCRT protein Chm7 to phosphatidic acid–rich membranes at nuclear envelope herniations

Mechanisms that control nuclear membrane remodeling are essential to maintain the integrity of the nucleus but remain to be fully defined. Here, we identify a phosphatidic acid (PA)–binding capacity in the nuclear envelope (NE)–specific ESCRT, Chm7, in budding yeast. Chm7’s interaction with PA-rich membranes is mediated through a conserved hydrophobic stretch of amino acids, which confers recruitment to the NE in a manner that is independent of but required for Chm7’s interaction with the LAP2-emerin-MAN1 (LEM) domain protein Heh1 (LEM2). Consistent with the functional importance of PA binding, mutation of this region abrogates recruitment of Chm7 to membranes and abolishes Chm7 function in the context of NE herniations that form during defective nuclear pore complex (NPC) biogenesis. In fact, we show that a PA sensor specifically accumulates within these NE herniations. We suggest that local control of PA metabolism is important for ensuring productive NE remodeling and that its dysregulation may contribute to pathologies associated with defective NPC assembly.     

Diffusion and retention are major determinants of protein targeting to the inner nuclear membrane

Newly synthesized membrane proteins are constantly sorted from the endoplasmic reticulum (ER) to various membranous compartments. How proteins specifically enrich at the inner nuclear membrane (INM) is not well understood. We have established a visual in vitro assay to measure kinetics and investigate requirements of protein targeting to the INM. Using human LBR, SUN2, and LAP2β as model substrates, we show that INM targeting is energy-dependent but distinct from import of soluble cargo. Accumulation of proteins at the INM relies on both a highly interconnected ER network, which is affected by energy depletion, and an efficient immobilization step at the INM. Nucleoporin depletions suggest that translocation through nuclear pore complexes (NPCs) is rate-limiting and restricted by the central NPC scaffold. Our experimental data combined with mathematical modeling support a diffusion-retention–based mechanism of INM targeting. We experimentally confirmed the sufficiency of diffusion and retention using an artificial reporter lacking natural sorting signals that recapitulates the energy dependence of the process in vivo.     

Conservation of inner nuclear membrane targeting sequences in mammalian Pom121 and yeast Heh2 membrane proteins

Endoplasmic reticulum–synthesized membrane proteins traffic through the nuclear pore complex (NPC) en route to the inner nuclear membrane (INM). Although many membrane proteins pass the NPC by simple diffusion, two yeast proteins, ScSrc1/ScHeh1 and ScHeh2, are actively imported. In these proteins, a nuclear localization signal (NLS) and an intrinsically disordered linker encode the sorting signal for recruiting the transport factors for FG-Nup and RanGTP-dependent transport through the NPC. Here we address whether a similar import mechanism applies in metazoans. We show that the (putative) NLSs of metazoan HsSun2, MmLem2, HsLBR, and HsLap2β are not sufficient to drive nuclear accumulation of a membrane protein in yeast, but the NLS from RnPom121 is. This NLS of Pom121 adapts a similar fold as the NLS of Heh2 when transport factor bound and rescues the subcellular localization and synthetic sickness of Heh2ΔNLS mutants. Consistent with the conservation of these NLSs, the NLS and linker of Heh2 support INM localization in HEK293T cells. The conserved features of the NLSs of ScHeh1, ScHeh2, and RnPom121 and the effective sorting of Heh2-derived reporters in human cells suggest that active import is conserved but confined to a small subset of INM proteins.     

Localization of Pom121 to the inner nuclear membrane is required for an early step of interphase nuclear pore complex assembly

The nuclear pore complex (NPC) is a large protein assembly that mediates molecular trafficking between the cytoplasm and the nucleus. NPCs assemble twice during the cell cycle in metazoans: postmitosis and during interphase. In this study, using small interfering RNA (siRNA) in conjunction with a cell fusion-based NPC assembly assay, we demonstrated that pore membrane protein (Pom)121, a vertebrate-specific integral membrane nucleoporin, is indispensable for an early step in interphase NPC assembly. Functional domain analysis of Pom121 showed that its nuclear localization signals, which bind to importin β via importin α and likely function with RanGTP, play an essential role in targeting Pom121 to the interphase NPC. Furthermore, a region of Pom121 that interacts with the inner nuclear membrane (INM) and lamin B receptor was found to be crucial for its NPC targeting. Based on these findings and on evidence that Pom121 localizes at the INM in the absence of a complete NPC structure, we propose that the nuclear migration of Pom121 and its subsequent interaction with INM proteins are required to initiate interphase NPC assembly. Our data also suggest, for the first time, the importance of the INM as a seeding site for "prepores" during interphase NPC assembly.     

Nuclear envelope lipids request border surveillance

In this issue, Thaller et al. (2021. J. Cell Biol. https://doi.org/10.1083/jcb.202004222) explore how the ESCRT protein Chm7 is recruited to sites of defective nuclear pore assembly. They show that a lipid, phosphatidic acid, is enriched at pathological nuclear envelope herniations, where it promotes Chm7 recruitment for membrane surveillance and repair.

The membranes of the nucleus form a protective boundary around the DNA, while nuclear pore complexes (NPCs) embedded in these membranes act as control gates, deciding what can pass (1). Maintaining the integrity of this boundary, called the nuclear envelope (NE), is essential for cell survival. Complications can arise if the NE or its pores become disrupted. Cells employ a sophisticated surveillance system that can rapidly recognize and fix any damage inflicted on the NE. How this damage is located and what activates its repair is still poorly understood.The integrity of the NE is compromised in a variety of conditions, including neurodegenerative diseases like amyotrophic lateral sclerosis and frontotemporal degeneration. An age-related decline in NE/NPC function has been observed (2). Moreover, a key feature of early onset dystonia, a disease that causes muscle spasms, is NE herniations that originate from NPC-like structures. Herniations are frequently observed in yeast cells with defects in NPC biogenesis. It is therefore thought that herniations result from defective NPC assembly.Embedding new NPCs into the NE is not trivial. Interphase NPC assembly likely occurs through an inside-out evagination of the inner nuclear membrane (INM) followed by a membrane fusion with the outer nuclear membrane (3). This process creates holes in the NE and poses a threat to NE integrity if not properly executed. Protection comes from an ESCRT-dependent surveillance system that is recruited by NE disruption or defective NPC assembly (4). In yeast, two key players are the ESCRT (endosomal sorting complexes required for transport) protein Chm7 and the LEM (LAP2-emerin-MAN1) domain protein Heh1. Heh1 and Chm7 are normally segregated to opposite sides of the NE. However, if the NE is damaged, Heh1 and Chm7 come in contact (5). Heh1 activates Chm7, which can then repair the damage to the NE by closing and sealing any gaps. Active Chm7/Heh1 may form a polymer similar to that of the human CHMP7–LEM2 complex (6). Several domains of Chm7 (the orthologue of mammalian CHMP7) contribute to its cellular localization and activity when NE surveillance is triggered. In this issue, Thaller et al. (7) shed light on the determinants controlling the timely recruitment of Chm7 to NE defect sites.The researchers characterized a conserved hydrophobic region of Chm7, which is predicted to form an amphipathic helix. Amphipathic helices are found in numerous proteins and are defined by the separation of hydrophobic and polar residues between the two faces of the helix. This separation enables these helices to bind at apolar/polar interfaces such as the lipid surfaces of cell organelles. Depending on the nature and distribution of the hydrophobic and polar residues as well as the length of the helix, amphipathic helices can be tuned into versatile molecular tools and for example, deform lipid bilayers, recognize specific lipids or sense membrane curvature.Chm7 is normally located in the cytosol but can be forced into the nucleus and into interaction with Heh1 by inhibiting its nuclear export. Interestingly, Thaller et al. observed that mutating the hydrophobic face of the amphipathic helix inhibited Chm7 recruitment to the INM, where Heh1 is located, suggesting the existence of a previously unknown membrane-binding activity in Chm7. The authors employed in vitro assays using liposomes to elucidate what attracts Chm7 to membranes. Chm7 showed enhanced liposome binding when the concentration of phosphatidic acid (PA) was increased, suggesting that Chm7 binds directly to PA-rich lipid bilayers. Chm7 preferred liposomes with a small diameter and, hence, high curvature over larger liposomes with an essentially flat surface. Given that Chm7 bound to PA-rich membranes in vitro, the authors then analyzed how altered cellular PA levels affect Chm7 distribution. Interestingly, elevated PA levels led to a redistribution of Chm7 from the cytoplasm to the membranes of the NE and the endoplasmic reticulum, which required Chm7’s amphipathic helix. Since increased PA levels can disrupt NE integrity, this raised the interesting possibility that Chm7 directly senses an instability in nuclear membranes via PA.A key question that follows is whether PA indeed accumulates at sites of Chm7 activity. To probe INM PA levels, Thaller et al. took advantage of an INM-specific PA biosensor (8). This sensor comprises an amphipathic helix that specifically binds to the phosphate moiety of PA by a three-finger grip of basic residues. The PA sensor was nucleoplasmic under normal growth conditions, indicating low PA levels at the INM. In contrast, the PA sensor relocalized to distinct INM foci when a constitutively active variant of Chm7 was expressed and colocalized with Chm7 at these foci. Thus, this hyperactive variant of Chm7 appears to affect INM PA levels, either by locally altering PA metabolism or through direct recruitment of PA, suggesting some positive feedback in PA-mediated Chm7 recruitment to membranes.Wild-type Chm7 is known to accumulate at the NE when de novo NPC assembly is perturbed. A hallmark of several NPC assembly mutants is the occurrence of NE herniations. These aberrant structures likely arise as a consequence of impaired NE remodeling. Notably, the PA sensor accumulated in distinct foci along the nuclear periphery in a nuclear pore mutant that exhibits such herniations. Thaller et al. found that Chm7 was dispensable for this PA sensor accumulation. This suggested that a local increase in PA concentration likely precedes Chm7 recruitment under conditions of NPC misassembly. Finally, through a series of elegant correlative light and electron microscopy experiments, the authors offered compelling ultrastructural evidence that the NPC misassembly-associated NE herniations can indeed recruit the PA sensor, indicative of high local PA concentrations at these sites (7).Thaller et al. propose a model in which a specific lipid, PA, can request NE surveillance by Chm7. PA accumulates at NE herniations, which are indicative of NE damage, and recruits Chm7 via its PA-sensing amphipathic helix. Chm7 then binds to Heh1, which reinforces the membrane recruitment and activates Chm7.This study is conceptually important and offers a lot of food for thought. First, because it adds a missing link—a lipid—to the complex hierarchy of signals that lead to NE surveillance and repair. Second, because it raises the question of which specific lipids surround NPCs in health and disease and how these lipids become locally enriched. And more generally, because it gives fresh insight into the poorly understood connection between lipid metabolism and the functional architecture of the nucleus (8, 9). Notably, Opi1, from which the PA sensor is derived, not only senses PA but also senses the lipid-packing density of a membrane, which is related to its lipid saturation state (10). Hence, the SOS call from PA that Thaller et al. have now detected may just be the tip of the iceberg, with other lipid surveillance codes remaining to be discovered.     

Functional association of Sun1 with nuclear pore complexes

Sun1 and 2 are A-type lamin-binding proteins that, in association with nesprins, form a link between the inner nuclear membranes (INMs) and outer nuclear membranes of mammalian nuclear envelopes. Both immunofluorescence and immunoelectron microscopy reveal that Sun1 but not Sun2 is intimately associated with nuclear pore complexes (NPCs). Topological analyses indicate that Sun1 is a type II integral protein of the INM. Localization of Sun1 to the INM is defined by at least two discrete regions within its nucleoplasmic domain. However, association with NPCs is dependent on the synergy of both nucleoplasmic and lumenal domains. Cells that are either depleted of Sun1 by RNA interference or that overexpress dominant-negative Sun1 fragments exhibit clustering of NPCs. The implication is that Sun1 represents an important determinant of NPC distribution across the nuclear surface.     

Phosphorylation-dependent mitotic SUMOylation drives nuclear envelope–chromatin interactions

In eukaryotes, chromatin binding to the inner nuclear membrane (INM) and nuclear pore complexes (NPCs) contributes to spatial organization of the genome and epigenetic programs important for gene expression. In mitosis, chromatin–nuclear envelope (NE) interactions are lost and then formed again as sister chromosomes segregate to postmitotic nuclei. Investigating these processes in S. cerevisiae, we identified temporally and spatially controlled phosphorylation-dependent SUMOylation events that positively regulate postmetaphase chromatin association with the NE. Our work establishes a phosphorylation-mediated targeting mechanism of the SUMO ligase Siz2 to the INM during mitosis, where Siz2 binds to and SUMOylates the VAP protein Scs2. The recruitment of Siz2 through Scs2 is further responsible for a wave of SUMOylation along the INM that supports the assembly and anchorage of subtelomeric chromatin at the INM and localization of an active gene (INO1) to NPCs during the later stages of mitosis and into G1-phase.     

A perinuclear α-helix with amphipathic features in Brl1 promotes NPC assembly

How nuclear pore complexes (NPCs) assemble in the intact nuclear envelope (NE) is only rudimentarily understood. Nucleoporins (Nups) accumulate at the inner nuclear membrane (INM) and deform this membrane toward the outer nuclear membrane (ONM), and eventually INM and ONM fuse by an unclear mechanism. In budding yeast, the integral membrane protein Brl1 that transiently associates with NPC assembly intermediates is involved in INM/ONM fusion during NPC assembly but leaving the molecular mechanism open. AlphaFold predictions indicate that Brl1-like proteins carry as common motifs an α-helix with amphipathic features (AαH) and a disulfide-stabilized, anti-parallel helix bundle (DAH) in the perinuclear space. Mutants with defective AαH (brl1^F391E, brl1^F391P, brl1^L402E) impair the essential function of BRL1. Overexpression of brl1^F391E promotes the formation of INM and ONM enclosed petal-like structures that carry Nups at their base, suggesting that they are derived from an NPC assembly attempt with failed INM/ONM fusion. Accordingly, brl1^F391E expression triggers mislocalization of Nup159 and Nup42 and to a lesser extent Nsp1, which localize on the cytoplasmic face of the NPC. The DAH also contributes to the function of Brl1, and AαH has functions independent of DAH. We propose that AαH and DAH in Brl1 promote INM/ONM fusion during NPC assembly.     

POM121 and Sun1 play a role in early steps of interphase NPC assembly

Nuclear pore complexes (NPCs) assemble at the end of mitosis during nuclear envelope (NE) reformation and into an intact NE as cells progress through interphase. Although recent studies have shown that NPC formation occurs by two different molecular mechanisms at two distinct cell cycle stages, little is known about the molecular players that mediate the fusion of the outer and inner nuclear membranes to form pores. In this paper, we provide evidence that the transmembrane nucleoporin (Nup), POM121, but not the Nup107-160 complex, is present at new pore assembly sites at a time that coincides with inner nuclear membrane (INM) and outer nuclear membrane (ONM) fusion. Overexpression of POM121 resulted in juxtaposition of the INM and ONM. Additionally, Sun1, an INM protein that is known to interact with the cytoskeleton, was specifically required for interphase assembly and localized with POM121 at forming pores. We propose a model in which POM121 and Sun1 interact transiently to promote early steps of interphase NPC assembly.     

Herpes simplex virus infection induces phosphorylation and delocalization of emerin, a key inner nuclear membrane protein

The inner nuclear membrane (INM) contains specialized membrane proteins that selectively interact with nuclear components including the lamina, chromatin, and DNA. Alterations in the organization of and interactions with INM and lamina components are likely to play important roles in herpesvirus replication and, in particular, exit from the nucleus. Emerin, a member of the LEM domain class of INM proteins, binds a number of nuclear components including lamins, the DNA-bridging protein BAF, and F-actin and is thought to be involved in maintaining nuclear integrity. Here we report that emerin is quantitatively modified during herpes simplex virus (HSV) infection. Modification begins early in infection, involves multiple steps, and is reversed by phosphatase treatment. Emerin phosphorylation during infection involves one or more cellular kinases but can also be influenced by the US3 viral kinase, a protein whose function is known to be involved in HSV nuclear egress. The results from biochemical extraction analyses and from immunofluorescence of the detergent-resistant population demonstrate that emerin association with the INM significantly reduced during infection. We propose that the induction of emerin phosphorylation in infected cells may be involved in nuclear egress and uncoupling interactions with targets such as the lamina, chromatin, or cytoskeletal components.     

A Highlights from MBoC Selection: Three-dimensional superresolution fluorescence microscopy maps the variable molecular architecture of the nuclear pore complex

Nuclear pore complexes (NPCs) are large macromolecular machines that mediate the traffic between the nucleus and the cytoplasm. In vertebrates, each NPC consists of ∼1000 proteins, termed nucleoporins, and has a mass of more than 100 MDa. While a pseudo-atomic static model of the central scaffold of the NPC has recently been assembled by integrating data from isolated proteins and complexes, many structural components still remain elusive due to the enormous size and flexibility of the NPC. Here, we explored the power of three-dimensional (3D) superresolution microscopy combined with computational classification and averaging to explore the 3D structure of the NPC in single human cells. We show that this approach can build the first integrated 3D structural map containing both central as well as peripheral NPC subunits with molecular specificity and nanoscale resolution. Our unbiased classification of more than 10,000 individual NPCs indicates that the nuclear ring and the nuclear basket can adopt different conformations. Our approach opens up the exciting possibility to relate different structural states of the NPC to function in situ.     

A classical NLS and the SUN domain contribute to the targeting of SUN2 to the inner nuclear membrane

Integral membrane proteins of the inner nuclear membrane (INM) are inserted into the endoplasmic reticulum membrane during their biogenesis and are then targeted to their final destination. We have used human SUN2 to delineate features that are required for INM targeting and have identified multiple elements that collectively contribute to the efficient localization of SUN2 to the nuclear envelope (NE). One such targeting element is a classical nuclear localization signal (cNLS) present in the N‐terminal, nucleoplasmic domain of SUN2. A second motif proximal to the cNLS is a cluster of arginines that serves coatomer‐mediated retrieval of SUN2 from the Golgi. Unexpectedly, also the C‐terminal, lumenal SUN domain of SUN2 supports NE localization, showing that targeting elements are not limited to cytoplasmic or transmembrane domains of INM proteins. Together, SUN2 represents the first mammalian INM protein relying on a functional cNLS, a Golgi retrieval signal and a perinuclear domain to mediate targeting to the INM.     

Cryo-EM structure of the nuclear ring from Xenopus laevis nuclear pore complex

Nuclear pore complex (NPC) shuttles cargo across the nuclear envelope. Here we present single-particle cryo-EM structure of the nuclear ring (NR) subunit from Xenopus laevis NPC at an average resolution of 5.6 Å. The NR subunit comprises two 10-membered Y complexes, each with the nucleoporin ELYS closely associating with Nup160 and Nup37 of the long arm. Unlike the cytoplasmic ring (CR) or inner ring (IR), the NR subunit contains only one molecule each of Nup205 and Nup93. Nup205 binds both arms of the Y complexes and interacts with the stem of inner Y complex from the neighboring subunit. Nup93 connects the stems of inner and outer Y complexes within the same NR subunit, and places its N-terminal extended helix into the axial groove of Nup205 from the neighboring subunit. Together with other structural information, we have generated a composite atomic model of the central ring scaffold that includes the NR, IR, and CR. The IR is connected to the two outer rings mainly through Nup155. This model facilitates functional understanding of vertebrate NPC.Subject terms: Cryoelectron microscopy, Nuclear envelope     

Quantitative Analysis of Membrane Protein Transport Across the Nuclear Pore Complex

Nuclear transport of the Saccharomyces cerevisiae membrane proteins Src1/Heh1 and Heh2 across the NPC is facilitated by a long intrinsically disordered linker between the nuclear localization signal (NLS) and the transmembrane domain. The import of reporter proteins derived from Heh2 is dependent on the FG‐Nups in the central channel, and the linker can position the transport factor‐bound NLS in the vicinity of the FG‐Nups in the central channel, while the transmembrane segment resides in the pore membrane. Here, we present a quantitative analysis of karyopherin‐mediated import and passive efflux of reporter proteins derived from Heh2, including data on the mobility of the reporter proteins in different membrane compartments. We show that membrane proteins with extralumenal domains up to 174 kDa, terminal to the linker and NLS, passively leak out of the nucleus via the NPC, albeit at a slow rate. We propose that also during passive efflux, the unfolded linker facilitates the passage of extralumenal domains through the central channel of the NPC .     

Reticulon-like REEP4 at the inner nuclear membrane promotes nuclear pore complex formation

Nuclear pore complexes (NPCs) are channels within the nuclear envelope that mediate nucleocytoplasmic transport. NPCs form within the closed nuclear envelope during interphase or assemble concomitantly with nuclear envelope reformation in late stages of mitosis. Both interphase and mitotic NPC biogenesis require coordination of protein complex assembly and membrane deformation. During early stages of mitotic NPC assembly, a seed for new NPCs is established on chromatin, yet the factors connecting the NPC seed to the membrane of the forming nuclear envelope are unknown. Here, we report that the reticulon homology domain protein REEP4 not only localizes to high-curvature membrane of the cytoplasmic endoplasmic reticulum but is also recruited to the inner nuclear membrane by the NPC biogenesis factor ELYS. This ELYS-recruited pool of REEP4 promotes NPC assembly and appears to be particularly important for NPC formation during mitosis. These findings suggest a role for REEP4 in coordinating nuclear envelope reformation with mitotic NPC biogenesis.     

Nucleoporins’ exclusive amino acid sequence features regulate their transient interaction with and selectivity of cargo complexes in the nuclear pore

Nucleocytoplasmic traffic of nucleic acids and proteins across the nuclear envelop via the nuclear pore complexes (NPCs) is vital for eukaryotic cells. NPCs screen transported macromolecules based on their morphology and surface chemistry. This selective nature of the NPC-mediated traffic is essential for regulating the fundamental functions of the nucleus, such as gene regulation, protein synthesis, and mechanotransduction. Despite the fundamental role of the NPC in cell and nuclear biology, the detailed mechanisms underlying how the NPC works have remained largely unknown. The critical components of NPCs enabling their selective barrier function are the natively unfolded phenylalanine- and glycine-rich proteins called “FG-nucleoporins” (FG Nups). These intrinsically disordered proteins are tethered to the inner wall of the NPC, and together form a highly dynamic polymeric meshwork whose physicochemical conformation has been the subject of intense debate. We observed that specific sequence features (called largest positive like-charge regions, or lpLCRs), characterized by extended subsequences that only possess positively charged amino acids, significantly affect the conformation of FG Nups inside the NPC. Here we investigate how the presence of lpLCRs affects the interactions between FG Nups and their interactions with the cargo complex. We combine coarse-grained molecular dynamics simulations with time-resolved force distribution analysis to disordered proteins to explore the behavior of the system. Our results suggest that the number of charged residues in the lpLCR domain directly governs the average distance between Phe residues and the intensity of interaction between them. As a result, the number of charged residues within lpLCR determines the balance between the hydrophobic interaction and the electrostatic repulsion and governs how dense and disordered the hydrophobic network formed by FG Nups is. Moreover, changing the number of charged residues in an lpLCR domain can interfere with ultrafast and transient interactions between FG Nups and the cargo complex.     

Pom121 links two essential subcomplexes of the nuclear pore complex core to the membrane

Nuclear pore complexes (NPCs) control the movement of molecules across the nuclear envelope (NE). We investigated the molecular interactions that exist at the interface between the NPC scaffold and the pore membrane. We show that key players mediating these interactions in mammalian cells are the nucleoporins Nup155 and Nup160. Nup155 depletion massively alters NE structure, causing a dramatic decrease in NPC numbers and the improper targeting of membrane proteins to the inner nuclear membrane. The role of Nup155 in assembly is likely closely linked to events at the membrane as we show that Nup155 interacts with pore membrane proteins Pom121 and NDC1. Furthermore, we demonstrate that the N terminus of Pom121 directly binds the β-propeller regions of Nup155 and Nup160. We propose a model in which the interactions of Pom121 with Nup155 and Nup160 are predicted to assist in the formation of the nuclear pore and the anchoring of the NPC to the pore membrane.