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Nuclear pore complexes (NPCs) fuse the two membranes of the nuclear envelope (NE) to a pore, connecting cytoplasm and nucleoplasm and allowing exchange of macromolecules between these compartments. Most NPC proteins do not contain integral membrane domains and thus it is largely unclear how NPCs are embedded and anchored in the NE. Here, we show that the evolutionary conserved nuclear pore protein Nup53 binds independently of other proteins to membranes, a property that is crucial for NPC assembly and conserved between yeast and vertebrates. The vertebrate protein comprises two membrane binding sites, of which the C-terminal domain has membrane deforming capabilities, and is specifically required for de novo NPC assembly and insertion into the intact NE during interphase. Dimerization of Nup53 contributes to its membrane interaction and is crucial for its function in NPC assembly. IntroductionThe defining feature of the eukaryotic cell is the compartmentalization of genetic material inside the nucleus. The spatial and temporal separation of transcription and translation has enabled eukaryotes to achieve a level of regulatory complexity that is unprecedented in prokaryotes.

This is accomplished by the nuclear envelope (NE), which serves as the physical barrier between the cytoplasm and the nucleoplasm. Nuclear pore complexes (NPCs) are the exclusive gateways in the NE allowing diffusion of small substances and regulated trafficking of macromolecules up to a size of 15 nm for ribosomal subunits or even 50 nm for Balbiani ring particles (for review, see;; ). NPCs form large pores in the NE, having a diameter of ∼130 nm. Unlike other transport channels, NPCs span two lipid bilayers, at sites where the outer and inner membranes of the NE are fused.

Therefore, NPCs are assumed to play an important role in deforming these membranes to form a pore as well as in stabilizing this highly curved pore membrane.Given the structural complexity and extraordinary transport capabilities of NPCs, it is quite surprising that these huge macromolecular assemblies of 40–60 MDa are only composed of ∼30 different proteins. These nucleoporins (Nups) can be roughly categorized into those forming the structure of the pore and those mediating transport through the NPC. The latter class is characterized by a high number of FG repeats. Two evolutionary conserved subcomplexes form the major part of the structural scaffold. The Nup107–160 complex in metazoa, or the corresponding Nup84 complex in yeast, is the best characterized of these owing to an extensive set of genetic, biochemical and structural data. Computational and structural analyses suggest that this complex is related to vesicle coats (;; ). It is possible that these proteins form a coat-like assembly stabilizing the curved pore membrane of the NPC, which is analogous to clathrin or COPI and II during vesicle formation (; ).

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Notably, neither clathrin nor COP coats interact directly with the lipid bilayers. They are rather linked to the deformed membrane via adaptor and integral proteins. Although three integral membrane proteins are known in the vertebrate NPC, it is unclear how a possible link between the Nup107–160 complex and the membrane is established.The second major structural and evolutionarily conserved subcomplex of the NPC is the metazoan Nup93 complex, Nic96 in yeast, which might serve as a link to the pore membrane. In vertebrates, it is composed of five nucleoporins: Nup205, Nup188, Nup155, Nup93 and Nup53. Nup53, also referred to as Nup35 , interacts with Nup93 and Nup155 , corresponding to Nup170 and Nic96 in yeast (; ). Nup155, Nup93 and Nup53 are each indispensable for NPC formation in vertebrates (;;; ).

Interestingly, Nup53 and its corresponding yeast homologues Nup53p and Nup59p interact with the transmembrane nucleoporin NDC1, thereby potentially linking the NPC to the pore membrane (; ). Although NDC1 is essential in both vertebrates and yeast (;;; ) it is not found in all eukaryotes (;; ), suggesting that in some organisms NPCs can form in the absence of a Nup53–NDC1 interaction. Indeed, Aspergillus nidulans is viable in the absence of all three known transmembrane nucleoporins.

This suggests that there are alternative modes of interaction between the nucleoporins and the pore membrane.Here, we show that Nup53 binds membranes directly and independently of other proteins. It possesses two membrane interaction regions, which are important for NPC assembly. Although either site is sufficient for NPC assembly at the end of mitosis, the C-terminal membrane binding site of Nup53 is specifically required for NPC assembly during interphase, probably because of its membrane deforming capabilities.

Nup53 is a membrane binding proteinOverexpression of Nup53 in yeast causes expansion of the NE. Similar membrane proliferation phenotypes have been observed upon overexpression of nuclear membrane binding proteins, such as lamin B. Yeast Nup53 contains a C-terminal region predicted to form an amphipathic helix (; ), which could serve as a membrane binding module.

However, Nup53 interacts with the integral pore membrane protein NDC1 in both yeast and metazoa (; ) and thus might be linked to the membrane via this interaction. We therefore tested whether Nup53 is able to interact with membranes independently of other proteins.To assay for membrane binding, we generated liposomes with an average radius of ∼150 nm. These liposomes were incubated with different, recombinantly expressed nucleoporins and floated through sucrose cushions. Liposome binding proteins were recovered after centrifugation from the top fraction. A Nup133 membrane binding fragment was used as a positive control and found in the liposome containing top fraction. Similarly, Xenopus Nup53 was found in the top fraction, indicating membrane interaction.

In contrast, a fragment of the FG repeat-containing nucleoporin Nup98 did not bind liposomes. Thus, Xenopus Nup53 binds directly to membranes independently of other interacting proteins. To determine whether this feature is conserved during evolution, we tested the two yeast homologues Nup53p and Nup59p, which both bound liposomes.

Nup53 directly binds membranes. ( A) 3 μM recombinant Xenopus Nup53 (Nup53xl), the two yeast orthologues Nup59sc and Nup53sc as well as fragments of Nup133 and Nup98 as positive and negative controls, respectively, were incubated with 6 mg/ml fluorescently labelled liposomes prepared from E. Coli polar lipids and floated through a sucrose gradient as indicated on the left.

Top fractions of the gradient, as well as 3% of the starting material, were analysed by SDS–PAGE and silver staining. Please note that Nup53 is sensitive to C-terminal degradation (.) and that the full-length protein significantly enriched in the liposome bound fraction. ( B) Full-length (1–320) and different fragments of Xenopus Nup53 as well as fragments of Nup133 and Nup98 were analysed for liposome binding as in ( A). Only fragments comprising the RRM domain (indicated in blue in the schematic representation) bound liposomes.We next sought to define the regions of Xenopus Nup53 important for its membrane interaction. Nup53 can be roughly divided into three parts: the N-terminus (amino acid (aa) 1–166), a middle region (aa 166–267) comprising a conserved RNA recognition motif (RRM) domain and the C-terminus (aa 267–320). We generated different N- and C-terminal truncations of Nup53 and tested them for liposome binding.

While full-length Nup53 (aa 1–320) bound to liposomes, the N-terminal region of the protein (aa 1–166) showed no binding. Extending this fragment by 100 aa to include the RRM domain rendered the protein capable of membrane binding (aa 1–267). The C-terminal half of Nup53 (aa 162–320), which included the RRM domain, also interacted with liposomes. However, a fragment consisting of only the C-terminal region of Nup53 but lacking the RRM domain (aa 254–320) could not bind liposomes. Surprisingly, a fragment comprising only the RRM domain (aa 162–267) did not bind liposomes showing that the RRM domain is necessary but not sufficient for Nup53 membrane binding.

Nup53 dimerization is necessary for membrane binding and NPC formationAs the RRM domain is crucial for Nup53 membrane interaction we investigated the function of this domain. The crystal structure of the mouse domain suggests that it acts as a dimerization rather than an RNA binding module. We designed a mutant of this domain by exchanging two amino acids (F172E/W203E) in the dimerization surface. Size exclusion chromatography in combination with multi-angle laser light scattering revealed that the resulting fragment was monomeric.

Dimerization of the RRM domain is essential for Nup53 membrane binding and nuclear pore complex formation. ( A) Size exclusion chromatography on a Superdex75 10/300 GL column followed by multi-angle static laser light scattering of the Xenopus Nup53 RRM domain and the F172E/W203E mutant, which rendered the domain monomeric. The green dots relate to the secondary axis and show the molecular weight of the eluting particles. ( B) HeLa cells were co-transfected with myc- and HA-tagged Xenopus Nup53 wild-type protein and/or dimerization mutant as indicated (●). Proteins were immunoprecipitated from cell lysates with α-myc or α-HA antibodies, and analysed by western blotting. Ten per cent of the start materials are loaded as input. To exclude complex formation after cell lysis, extracts from single transfected myc–Nup53 and HA–Nup53 cell batches were mixed and processed for immunoprecipitation ( ).

Under these conditions, no co-precipitation was observed. ( C) Full-length Xenopus Nup53 and the respective F172E/W203E mutant (RRM mutant) were analysed for liposome binding as in.

The right panel shows the quantitation of liposome binding analysed by western blotting and normalized to the levels of the wild-type protein (one out of two independent experiments). ( D) Western blot analysis of mock, Nup53-depleted (ΔNup53) and Nup53-depleted extracts supplemented with recombinant wild-type protein (Nup53) or the dimerization mutant (Nup53 RRM mutant), respectively.

Recombinant proteins were added to approximate endogenous Nup53 levels (judged by the full-length protein, please note for both endogenous and recombinant Nup53 proteins C-terminal degradation products (.)). The recombinant Nup53 migrated slightly faster than the endogenous protein due to absence of eukaryotic post-translational modifications. The Nup93 antibody recognizes a slightly slower migrating cross-reactivity by western blotting (.).

( E) Nuclei were assembled in mock, Nup53-depleted extracts or Nup53-depleted extracts supplemented with wild-type protein (Nup53) or the dimerization mutant for 120 min, fixed with 4% PFA and analysed with Nup53 antibodies (red) and mAb414 (green). Chromatin was stained with DAPI. ( F) Nuclei were assembled as in ( E), fixed with 2% PFA and 0.5% glutaraldehyde and analysed for chromatin (blue: DAPI) and membrane staining (red: DiIC18, bar: 10 μm). Right panel shows the quantitation of chromatin substrates with a closed nuclear envelope (averages of three independent experiments with 300 randomly chosen chromatin substrates per sample, error bars represent the range).To confirm that the dimerization occurs also in vivo, we performed co-transfection experiments in HeLa cells using HA- and myc-tagged Xenopus Nup53. Either α-HA or α-myc antibodies immunoprecipitated both HA- and myc-tagged wild-type Nup53 indicating that the proteins formed a complex (, lanes 5 and 10). If cells were transfected with either construct separately before they were mixed for protein extraction, then no co-immunoprecipitation was observed (, lanes 9 and 14) demonstrating that complex formation cannot occur under the conditions of the immunoprecipitation.

Co-transfections of RRM mutants as well as RRM mutants and wild-type protein did not result in complex formation (, lanes 6–8 and 11–13) indicating that the F172E/W203E exchange inhibited dimerization/oligomerization.Next, we tested the effect of these mutations on membrane binding. In the context of the full-length protein, these mutations decreased liposome binding by 70% suggesting that the dimerization of Nup53 is important for its membrane interaction.As Nup53 is essential for postmitotic NPC formation we examined the relevance of Nup53 membrane binding for this.

We employed Xenopus laevis egg extracts to study nuclear reformation in vitro. With antibodies against Nup53 we depleted the endogenous protein without co-depletion of other nucleoporins including the other members of the Nup93 complex: Nup93, Nup155, Nup205 and Nup188. These depleted extracts were incubated with sperm heads serving as chromatin template. In the absence of Nup53, NPC formation was blocked as reported. This was indicated by the absence of immunofluorescent signal on the chromatin surface for mab414, an antibody recognizing several nucleoporins that represent a major subfraction of the NPC. Addition of recombinantly expressed wild-type Nup53 to the depleted extracts at levels similar to the endogenous protein restored NPC formation.

The recombinant protein was integrated into NPCs as indicated by immunostaining with a Nup53 antibody. In contrast, the dimerization and membrane binding defective Nup53 mutant (1–320 F172E/W203E) was unable to substitute for the endogenous protein in NPC formation.Individual depletion of several nucleoporins essential for NPC assembly from Xenopus egg extracts also blocks formation of a closed NE. These nucleoporins include POM121, NDC1, Nup155, Nup93 (;;; ) and Nup53.

Upon Nup53 depletion, membrane vesicles bound to the chromatin surface but did not fuse to form a closed NE (; ). This phenotype was rescued by the wild-type Nup53 protein, but not by the dimerization defective mutant. Together with the liposome-binding assay, this suggests that Nup53 membrane binding could be important for NPC assembly and formation of a closed NE. However, we cannot exclude that the RRM mutant also affects interaction of Nup53 with other nucleoporins. Indeed, in GST pull-down assays we observed a slight reduction of Nup93, Nup205 and Nup155 binding to Nup53 in the context of the RRM mutant as compared to the wild-type protein. In contrast, NDC1 binding to Nup53 was unaffected by the dimerization mutant. Nup53 possesses two membrane binding regionsThese results reveal a crucial role for Nup53 dimerization via its RRM domain in NE reformation.

However, the RRM domain alone did not bind to membranes. We tested different Nup53 truncations for liposome binding to map the membrane interaction sites (; shows the purity of all recombinant proteins used in the different liposome experiments). An N-terminal fragment of Nup53 including the RRM domain (aa 1–267) bound to liposomes with only a slightly decreased binding efficiency, 83% of the levels of the full-length protein. Further truncations from the N-terminus revealed a minimal membrane binding region between aa 93 and 107 as indicated by a four-fold decrease in liposome binding upon removal of these 15 amino acids. This region comprises a patch of basic residues, which as in other membrane binding proteins might be important for the interaction with negatively charged lipids.

Indeed, changing two residues to negatively charged residues (R105E/K106E) abolished membrane binding (, 83% reduction as compared to the 93–267 fragment). Nup53 possesses two independent membrane binding regions. ( A) Full-length protein (1–320) and different fragments of Xenopus Nup53 were quantitatively analysed for liposome binding as in (normalized to the full-length protein, three independent experiments). ( B) A fragment comprising the first membrane binding region and the RRM domain (93–267) as well as a phosphomimetic (93–267 S94E/T100E) and a non-phosphorylatable mutant (93–267 S94A/T100A) was treated with CyclinB/CDK1.

Samples were tested for liposome binding as in and analysed by western blotting (left panel) and quantified (right panel: two independent experiments, normalized to liposome binding of wild-type fragment without CDK1 pretreatment). Nup53 membrane binding is necessary for NPC formationThe Nup53 mutant defective in RRM dimerization, which showed reduced membrane binding, was unable to substitute for the endogenous protein in nuclear assembly. We therefore analysed the contribution of each of the membrane interaction sites to NPC assembly by substituting endogenous Nup53 with constructs defective in the N-terminal membrane interaction site, lacking the C-terminal membrane interaction site, or comprising a combination of both deficient sites. Surprisingly, mutants of the N-terminal membrane binding site (1–320 R105E/K106E and 1–320 S94E/T100E) supported NPC formation as indicated by mAB414 staining.

They also supported formation of a closed NE. Correspondingly, mutations in the N-terminal binding region did not alter the NE localization of any other nucleoporins. These nucleoporins include members of the Nup93 complex (Nup93, Nup188, Nup205 and Nup155) as well as the transmembrane nucleoporins NDC1 and POM121.

Accordingly, interactions of these mutants with Nup93 and Nup205, which bind the N-terminal part of Nup53 (; ), were unaffected as shown by GST pull downs. Either of the two membrane binding regions of Nup53 is sufficient for postmitotic NPC assembly. ( A) Nuclei were assembled in mock, Nup53-depleted extracts or Nup53-depleted extracts supplemented with wild-type Nup53 (1–320), constructs featuring mutations in the N-terminal membrane binding site (1–320 R105E/K106E, 1–320 S94E/T100E), constructs lacking the C-terminal membrane binding site (1–319, 1–312) or both (1–319 R105E/K106E, 1–319 S94E/T100E, 1–312 R105E/K106E, 1–312 S94E/T100E), respectively. Samples were fixed after 120 min with 4% PFA and analysed with Nup53 antibodies (red) and mAb414 (green, upper panel) or with 2% PFA and 0.5% glutaraldehyde and analysed for chromatin (blue: DAPI) and membrane staining (red: DiIC18, lower panel). ( B) Quantitation of chromatin substrates with a closed NE was done as in. ( C) Western blot analysis of extracts used in ( A) showing the re-addition of the recombinant proteins to approximately endogenous Nup53 levels. ( D) Nuclei were assembled as in ( A), fixed with 4% PFA and analysed with respective antibodies.

Bar: 10 μm.The fragment lacking the C-terminal tryptophan (1–319) also supported NPC assembly and formation of a closed NE. Deletion of this tryptophan did not interfere with Nup53 binding to NDC1 or Nup155 , two binding partners interacting with the C-terminal region. The truncation lacking the last eight C-terminal amino acids (1–312) also allowed for NPC assembly and formation of a closed NE. All tested nucleoporins were located at the NE in these nuclei. Notably, this truncation did not bind to NDC1 , supporting the view that the Nup53–NDC1 interaction is not required for postmitotic NPC formation. These observations suggest that a single Nup53 membrane binding region is sufficient for NPC assembly at the end of mitosis.In contrast to the Nup53 mutants and truncations that abrogate one membrane binding region, mutants affecting both membrane binding sites (1–319 R105E/K106E, 1–319 S94E/T100E, 1–312 R105E/K106E and 1–312 S94E/T100E) did not support NPC assembly and NE reformation.

Under these conditions, MEL28 (also referred to as ELYS) as well as Nup107, which both bind early to chromatin during the NPC assembly process (;; ), as well as the transmembrane nucleoporins, NDC1 and POM121, were detected on the chromatin. In contrast, Nup205, Nup188, Nup155 and Nup93 were not recruited. However, this lack of recruitment as well as the block in NPC assembly is unlikely to be caused by disrupting Nup53 binding to these interaction partners as the mutations introduced did not affect binding to Nup93, Nup205 and Nup155 in GST pull downs. It is also unlikely that the loss of the Nup53–NDC1 interaction caused this phenotype as the Nup53 fragment 1–312 still allowed for postmitotic NPC assembly but was not able to bind NDC1. Nup58 representing an FG-containing nucleoporin of the central channel as well as the peripheral nucleoporin Nup88 was also absent on chromatin in the presence of a Nup53 construct that lacked both membrane binding regions (1–312 R105E/K106E). These data support the conclusion that the direct Nup53 membrane interaction is important for postmitotic NPC formation. Interphasic NPC assembly requires the C-terminal membrane binding site of Nup53Metazoan NPC assembly occurs in two different stages of the cell cycle: at the end of mitosis when NPCs assemble concomitantly with the reforming NE and during interphase when new NPCs are assembled and integrated into the intact NE (; ).

Recent data suggest that there are different requirements for these two possible modes of NPC assembly. The in vitro nuclear assemblies described up to now reflect the situation at the end of mitosis. We therefore assayed whether the mutants that support postmitotic NPC assembly also support NPC formation during interphase. In an experimental set-up developed by the Hetzer laboratory , nuclei with newly integrated NPCs can be visualized by an influx of dextrans when nucleoporins forming the permeability barrier of newly formed NPCs are depleted. Under these conditions, mutants defective in the N-terminal membrane binding site of Nup53 (1–320 R105E/K106E and 1–320 S94E/T100E) supported interphasic NPC formation. Conversely, Nup53 truncations affecting the C-terminal membrane binding site did not substitute for the wild-type protein in this mode of NPC assembly.

This indicates that, in contrast to postmitotic NPC assembly where both membrane binding regions individually support NPC formation, only the C-terminal membrane binding site of Nup53 is required for interphasic NPC formation. The C-terminal Nup53 membrane binding site is essential for interphasic nuclear pore complex (NPC) formation. ( A) Nuclei were preassembled in mock or Nup53-depleted extracts supplemented with wild-type full-length protein (1–320), constructs with a mutated N-terminal membrane binding site (1–320 R105E/K106E, 1–320 S94E/T100E), or constructs lacking the C-terminal membrane interaction site (1–319, 1–312), respectively. After 90 min, the samples were supplemented with cytosol depleted of Nup53 and FG-containing nucleoporins.

After 60 min, FITC-labelled 70-kDa dextran and Hoechst was added. The right panel shows the quantitation of three independent experiments with 300 randomly chosen chromatin substrates per sample.

Error bars represent the range. ( B) Nuclei were assembled in Nup53-depleted extracts supplemented with wild-type full-length protein (1–320), a construct with a mutated N-terminal membrane binding site (1–320 R105E/K106E), or a construct lacking the last C-terminal amino acid (1–319), respectively, for 120 min.

Where indicated, de novo NPC assembly was blocked by the addition of 2 μM importin β after 50 min and nuclei were further incubated for 70 min. For each construct, total NPC numbers per nucleus identified by mAB414 immunofluorescence were quantified from 20 nuclei in 2 independent experiments and normalized to the wild-type full-length protein. Error bars represent the s.e.

Of the mean.Interestingly, the Nup53 truncation lacking the C-terminal tryptophan (1–319) did not support interphasic NPC assembly in the dextran influx assay despite the fact that membrane interaction is only slightly reduced. We confirmed these findings in an independent assay directly counting NPCs identified by mAB414 immunostaining (; ). NPC numbers were determined on nuclei where NPCs assembled in the postmitotic and interphasic mode and nuclei where interphasic NPC formation was specifically blocked by addition of 2 μM importin β (; ).

The NPC numbers of nuclei assembled for 120 min in the presence of recombinant wild-type Nup53 as well as the Nup53 mutant defective in the N-terminal membrane binding site (1–320 R105E/K106E) were reduced by importin β addition after 50 min, i.e., when a closed NE with intact NPC was formed. In contrast, the Nup53 truncation lacking the C-terminal tryptophan showed after 120 min a lower number of NPCs, which was not sensitive to importin β addition, indicating that in this condition interphasic NPC assembly did not occur. Nup53 can deform membranesMany membrane binding proteins induce membrane deformation.

Such a function is of special interest in the context of NPC formation as NPCs are integrated in the NE at sites where both nuclear membranes are deformed and fused to a pore. We therefore analysed the morphology of Nup53-bound liposomes using electron microcopy. As reported , tubulation of liposomes is induced by the EH domain-containing protein EHD2. Interestingly, a Nup53 fragment containing both membrane binding sites (93–320) strongly induced liposome tubulation indicating a membrane deformation capability.

A shorter fragment containing only the N-terminal membrane binding site and including the RRM domain (93–267) did not induce membrane tubulation, despite the fact that it was able to bind liposomes. In contrast, a fragment comprising the RRM domain and the full C-terminus of Nup53 (130–320) strongly induced membrane tubulation indicating that the second, C-terminal membrane binding domain deforms membranes. Accordingly, fragments lacking the last eight residues (130–312), and therefore the second membrane binding site or only the last C-terminal tryptophan (130–319) did not cause membrane tubulation. Consistently, fragments mutated in the first, or N-terminal, membrane binding region of Nup53 (93–320 R105E/K106E and 93–320 S94E/T100E) induced membrane deformation. Efficient membrane binding of Nup53 depends not only on the individual membrane binding domains but also on dimerization (; ).

To determine the importance of the dimerization of Nup53 for membrane tubulation the RRM mutants of fragments that contained either both (93–320 RRM mutant) or only the C-terminal binding site (130–320 RRM mutant) were tested. Neither of the two fragments induced membrane tubulation emphasizing that membrane interaction is indeed required for this phenotype. The membrane binding fragment of Nup133 did not induce detectable tubulation, emphasizing that membrane binding alone does not account for membrane deformation. The C-terminus of Nup53 binds and deforms membranes. ( A) Folch fraction I liposomes were incubated where indicated with 3 μM recombinant Nup53 fragments containing both (93–320), the N-terminal (93–267) or C-terminal (130–320) membrane binding sites including the RRM domain as well as fragments and mutants where the C-terminal (93–312, 93–319), the N-terminal (93–320 R105E/K106E, 93–320 S94E/T100E) membrane interaction site or the dimerization (93–320 RRM mutant and 130–320 RRM mutant) is compromised.

The liposome deforming protein EHD2 (aa 1–543) and a fragment of Nup133 were used as positive and negative control, respectively. ( B) 3 μM recombinant yeast Nup53 and Nup59 protein was incubated with liposomes and analysed. Bars: 400 nm.Similar to Xenopus Nup53 both yeast isoforms—Nup53p and Nup59p—induced membrane tubulation. This indicates that, in addition to membrane binding , the membrane bending activity of Nup53 is conserved during evolution which suggests an important role for Nup53-induced membrane deformation in NPC formation and/or function. DiscussionHere, we show that Nup53 binds membranes directly and independently of other proteins. We demonstrate that dimerization of the protein via its RRM domain is necessary for membrane interaction and identify two separate membrane binding regions within the protein. Binding of Nup53 to membranes is important for NPC assembly.

Although either of the two membrane interaction regions is sufficient for postmitotic NPC formation, NPC assembly in interphase specifically requires the C-terminal membrane binding site, probably because of its capacity to induce membrane deformation.Our results support the view that Nup53 is crucial for postmitotic NPC assembly in Xenopus egg extracts. Depletion of Nup53 blocks NPC assembly and the formation of a closed NE. This phenotype is rescued by the addition of recombinant Nup53, confirming the specificity of the depletion (; and ). In agreement with the cell-free data, RNAi-mediated depletion of Nup53 in HeLa cells results in severe nuclear morphology defects and reduced levels of Nup93, Nup205 and Nup155 at the nuclear rim, suggestive of defects in NPC assembly. Elegans, RNAi knockdown of Nup53 as well as a deletion within the protein blocks postmitotic nuclear reformation and results in embryonic lethality (; ), suggesting that Nup53 function is conserved in metazoa.

Notably, Nup53 is found in all eukaryotic supergroups indicating that it is part of the NPC in the last common ancestor of eukaryotes. However, its absence in some eukaryotic organisms shows that its loss can be compensated (; ). Double deletion of both S. Cerevisiae orthologues, Nup53p and Nup59p, is viable (; ). However, these strains exhibit growth defects and Nup53 becomes essential when interacting nucleoporins, including integral membrane proteins, are deleted (;; ).NPC assembly is a highly ordered process. In metazoa the NE and NPCs break down and reform during each round of mitosis. Postmitotic reassembly occurs on the decondensing chromatin.

The earliest step involves the recruitment of the Nup107–160 subcomplex to the chromatin surface by MEL28/ELYS (;; ), a DNA-binding protein that acts as a seeding point for NPC assembly. Membranes are subsequently recruited to chromatin causing an enrichment of NE/NPC-specific membrane proteins, including the transmembrane nucleoporins POM121 and NDC1 (;; ). The order of these initial steps has been defined using both in vitro experiments and live-cell imaging ; however, less is known about the order of nucleoporin assembly following these events.

MEL28 and Nup107 as well as POM121 and NDC1 containing membranes are detectable on the chromatin in Nup53-depleted nuclear assemblies. The same pattern was seen in Nup93-depleted extracts. Our results suggest that Nup53, which is part of the Nup93 complex, is a key determinant for the recruitment of the other members of this complex. In the absence of Nup53, the chromatin recruitment of Nup155, Nup205, Nup188 and Nup93 was impaired.

Similarly, C. Elegans Nup53 is necessary for the efficient accumulation of Nup155 and Nup58 but not Nup107 at the NE.

This is also supported by live-cell imaging experiments in HeLa cells, which capture the recruitment of Nup58 slightly after Nup93. Accordingly, we have found that upon depletion of the two Nup93 containing subcomplexes, Nup93–Nup188 and Nup93–205, the two other members of the complex, Nup155 and Nup53, are still detectable, albeit at reduced levels on the assembling NPCs. Recruitment of the Nup62 complex to the chromatin template is prevented in the absence of both Nup53 (see lack of a Nup58 immunostaining, which is a constituent of the Nup62 complex, in ) and Nup93 consistent with the notion that Nup93 is a key determinant in recruiting the Nup62 complex during vertebrate NPC assembly at the end of mitosis. Taken together, these data suggest that after the binding of the Nup107–160 complex and nuclear membranes to the chromatin surface, Nup53 recruitment is the next decisive step in NPC assembly.

Nup93 (Nup93–Nup188/Nup93–Nup205) binding and the subsequent recruitment of the Nup62 complex follow.Nup53 interacts with a number of other nucleoporins, including NDC1, Nup155 and Nup93 (;,;; ) a feature that is conserved in yeast (;; ). As previously reported , the interaction of Nup53 with NDC1 is not necessary for postmitotic NPC assembly in Xenopus egg extracts. A possible explanation might be that Nup53 can interact directly with membranes and that one of its two membrane binding regions is sufficient for postmitotic NPC formation. In addition, Nup53 interaction with other nucleoporins such as Nup155, which in turn binds POM121 (; ) could be a possible mechanism linking Nup53 to the pore membrane which might compensate for the loss of the direct Nup53–NDC1 interaction.The interaction of Nup53 with Nup155 is thought to be important for NPC assembly. A previous study found that after depleting Nup53 from Xenopus egg extracts, only fragments capable of binding to Nup155 allow for NPC formation. However, in this case all fragments that rescued the NE/NPC assembly defect included the RRM domain and all fragments defective in NPC assembly and the Nup155 interaction lacked the intact RRM domain. Similarly, a deletion in C.

Elegans Nup53 blocked NE assembly also impaired the RRM domain. We demonstrate here that the RRM domain is important for Nup53 dimerization and in turn for membrane binding. Therefore, we currently cannot rule out that the primary cause for the previously described defects was a loss of the Nup53 membrane interaction.Nup93 binds directly Nup53 (; ) and the interaction domain resides in the N-terminal half of Nup53. This interaction was previously considered to be dispensable for NPC assembly as a fragment lacking the N-terminal region as well as the C-terminal 26 amino acids replaced endogenous Nup53 in nuclear assemblies in Xenopus egg extracts. This is quite surprising in the light of the results presented here, as this fragment also lacked both membrane binding regions identified in this study and does not allow for Nup93 recruitment which is an essential factor for postmitotic NPC assembly. Using a number of different Nup53 fragments that lacked the Nup93 binding region we were not able to replace endogenous Nup53 in NPC assembly.

Currently, we cannot rule out that this discrepancy is due to different Nup53 depletion efficiencies. In fact, we found that a small percentage of floated membrane preparations used in the nuclear assembly reactions contained minor amounts of Nup53, and we were careful to exclude these from our experiments.Nup53 is also known as mitotic phosphoprotein of 44 kDa.

Indeed, Nup53 from mitotic extracts migrates significantly slower in SDS–PAGE compared to Nup53 from interphasic extracts. We identified a number of mitosis-specific phosphorylation sites on Nup53, of which a subset were consensus sites for CDK1. These findings are consistent with the fact that Nup53 has been identified as a CDK1 target in both yeast and humans (; ). The N-terminal membrane binding region of Nup53 is phosphorylated during mitosis. Phosphomimetic mutations and in vitro phosphorylation experiments suggest that CDK1-mediated phosphorylation renders this region incompetent for membrane interaction. It is therefore possible that this mitotic phosphorylation weakens the interaction of Nup53 with the pore membrane to facilitate NPC disassembly during prophase.Proteins without integral membrane regions can associate with cellular membranes by a variety of mechanisms. First, they can be covalently attached to a lipid moiety.

However, we have no indication that Nup53 is modified in such a way. Second, peripheral membrane proteins are recruited to the lipid bilayer by specific protein–lipid interactions that involve binding to particular lipid head groups. In this regard, lipid arrays performed to date have not demonstrated an affinity of Nup53 for any specific lipid (unpublished observation). Furthermore, recombinant Nup53 binds to liposomes prepared from different lipid sources like pure DOPC (1,2-dioleoyl- sn-glycero-3-phosphocholine), a lipid mixture mimicking the ER/NE lipid composition (; ) or folch fraction I (unpublished observation). Third, some proteins are recruited to membranes via electrostatic interactions.

As a fraction of the lipid head groups are negatively charged this involves positively charged clusters on the protein surface. Indeed, we found that the first membrane binding region of Nup53 contains such a cluster. Replacing these positive with negative residues as well as introducing negative charge by phosphorylation rendered this site incapable of membrane interaction. Finally, peripheral membrane proteins can associate with lipid bilayers via hydrophobic regions. It has been suggested that the C-terminal region of Nup53 contains an amphipathic helix, which could serve as a hydrophobic module (; ). In fact, the C-terminus of Nup53 contains a membrane binding region and deleting the last eight amino acids abolished its membrane interaction.

Deletion of the C-terminal tryptophan only slightly reduced membrane binding of Nup53 in the full-length protein , but inhibited interphasic NPC assembly suggesting that this residue fulfills an important additional function. Indeed, the insertion of hydrophobic parts of a protein into a membrane is one of several mechanisms by which proteins can deform membranes. Our data suggest that the C-terminal membrane binding region and especially the last tryptophan of Nup53 fulfills this task.

Interestingly, in vivo intranuclear tubular membranes are induced upon overexpression of yeast Nup53p which is dependent on its C-terminus. Thus, Nup53 might not only have an important function in binding to the pore membrane in turn promoting the recruitment of other nucleoporins, especially members of the Nup93 complex, but may additionally function to deform the NE membrane into a pore. In the latter instance, the insertion of the Nup53 C-terminus into the hydrophobic phase of the membrane would result in displacement of lipid head groups and reorientation of the hydrophobic lipid side chains, bending the lipid bilayer into a convex shape and inducing membrane curvature necessary to form and stabilize the pore. The doughnut-like shape of the pore requires likewise stabilization of a concave curvature in the plane of the pore in addition to the convex curved membrane connection between outer and inner nuclear membrane (see ).

This curvature might be induced and stabilized by a number of at least partially redundant mechanisms, such as formation of a coat-like structure by the Nup107–160 complex (;; ) or oligomerization of pore membrane proteins, although it is not clear how the different proteins contribute to the different modes of membrane bending. Similarly, in the context of the protein interaction network of an assembled NPC the N-terminal membrane binding region of Nup53, in addition to membrane interaction, might induce and/or stabilize curved membranes.

Indeed, Nup53 is only functional when it dimerizes probably because this increases the avidity of the Nup53 membrane interaction. In addition, all the factors might also impose geometrical constrains to the membranes supporting a pore structure.

The role of Nup53 in NPC assembly. Schematic drawing of the postmitotic and interphasic modes of nuclear pore assembly focused on the membrane interacting function of Nup53. For the sake of clarity other membrane associated and integral proteins, including nucleoporins, participating in this process are omitted. Left pathway: after mitosis, outgrowing ER tubules (yellow) surround assembling NPCs providing negative/concave (red) and positive/convex (green) curvature which is stabilized by membrane binding Nup53 dimers (blue) for pore formation. Right pathway: in interphase, the intact nuclear envelope membranes (yellow) are deformed by the C-terminal membrane binding site of Nup53 introducing a convex membrane curvature for the approximation and following fusion of the two membranes leading to pore formation.Although either one of the two membrane binding regions of Nup53 is sufficient for postmitotic NPC assembly and stability, the C-terminal site is specifically required for NPC assembly during interphase. It is a matter of debate whether NPC assembly during these different cell-cycle phases occurs by distinct mechanisms (;; ).

At the end of mitosis, NPC assembly occurs concomitantly with formation of a closed NE. It is possible that this mode of NPC formation does not require fusion between the outer and inner nuclear membrane to form a nuclear pore, in contrast to interphasic NPC assembly. Postmitotic pore assembly could rather arise by the enclosement of the assembling NPCs on the chromatin surface by an outgrowing ER network. In this scenario, Nup53 would stabilize the membrane curvature provided by the ER tubules rather than induce membrane deformation (see, left pathway).

The different requirements for Nup53 membrane binding regions in postmitotic and interphasic NPC assembly support the view of two different mechanistic pathways. A loss of the membrane deforming capability of Nup53 in postmitotic NPC assembly and NPC stability might be compensated by other factors such as the Nup107–160 complex or integral membrane proteins. However, during metazoan interphasic NPC assembly Nup53-mediated membrane deformation might be crucial for the initial approximation and/or fusion of both membrane layers (see, right pathway).

Interestingly, ER bending proteins of the reticulon family that induce convex membrane curvature were shown to be important for NPC assembly into the intact NE both in yeast and in vertebrates. Currently, it is unknown whether these proteins do also contribute to postmitotic NPC assembly. As their effect on ER membrane reorganization at the end of mitosis is a prerequisite for NE reformation it is difficult to separate these two functions. Finally, how the fusion of outer and inner nuclear membranes is achieved is largely unclear but our results suggest that Nup53, importantly its C-terminal membrane binding region, is critical for this process. Materials and methodsAntibodies against POM121 and GP210 , NDC1 , Nup155 , MEL28/ELYS , Nup107 , Nup53 and Nup58 as well as Nup188, Nup205, Nup98 and Nup53 have been described. MAB414 and Nup88 antibodies were from Babco or BD Bioscience, respectively. For quantitation of Nup53 liposomes binding the antibody was affinity purified with a fragment comprising the RRM domain as this domain is included in all tested fragments (please see for list of all DNA constructs used in this study).

Protein expression and purificationConstructs for full-length Xenopus Nup53 and fragments, S. Cerevisiae Nup53 and Nup59 were generated from a synthetic DNA optimized for codon usage in E. Coli (Geneart, see ) and cloned into a modified pET28a vector with a yeast SUMO solubility tag followed by a TEV site upstream of the Nup53 fragments. Proteins were expressed in E.

Coli, purified using Ni-agarose, His 6 and SUMO tags were cleaved by TEV protease, concentrated using VIVASPIN columns (Sartorius) and purified by gel filtration (Superdex200 10/300 GL or Superdex200 PC 3.2/30, GE Healthcare) either in PBS for liposome binding experiments or in sucrose buffer for nuclear assemblies, respectively. Nup53 fragments aa 162–320 and aa 254–320 were purified by size exclusion chromatography without removal of the tags to retain stability. Fragments of Xenopus Nup98 (aa 676-863) as well as human Nup133 (aa 67–514) were expressed from modified pET28a vectors with a His 6-NusA or His 6 tag, which was cleaved of by thrombin or precision protease, respectively. ImmunoprecipitationXenopus Nup53 as well as the RRM dimerization mutant (F172E/W203E) was cloned with N-terminal myc or HA tag, respectively, into a pSI vector (Promega). HeLa cells were transfected using Fugene 6 (Roche) following manufacturer's instructions, harvested 24 h post transfection and solubilized in 1% Triton X-100 in PBS supplemented with protease inhibitors (2 μg/ml leupeptin, 1 μg/ml pepstatin, 2 μg/ml aprotinin, 0.1 mg/ml AEBSF final concentration) for 10 min at 4°C.

After centrifugation for 10 min at 15 000 g samples were diluted five-fold in PBS and employed for immunoprecipitation using α-myc or α-HA antibodies (Roche). MiscellaneousFor in vitro phosphorylation, 3 μM proteins were incubated with 0.33 U/μl CDK1-CyclinB (NEB), 1 mM ATP, 10 mM MgCl 2 and 1 mM EDTA in PBS for 1 h at 30°C.For liposome tubulation copper grids filmed with pioloform and carbon-coated were glow discharged before usage. Proteins were incubated with 1 mg/ml folch fraction I liposomes for 7 min on grids, washed with buffer (10 mM Hepes, 150 mM NaCl, 4.5 mM KCl) and stained with 2% UAc for 2 min and examined on a FEI Technai spirit 120 kV microscope.