Daigle N , Beaudouin J , Hartnell L , Imreh G , Hallberg E , Lippincott-Schwartz J , Ellenberg J .

	Figure 1. POM121-GFP and GFP-Nup153 label single NPCs and induce AL in live cells. (A–G) Images are confocal z-stacks (A and E) or single sections (B–D, F, and G). (A) Three-dimensional reconstruction of a live NRK cell nucleus expressing POM121-EGFP3. Top, maximum intensity projected of optical sections of the lower nuclear surface (double-pointed arrow). Inset enlarges 1 μm2 to show labeling of single NPCs. Bottom, xz slice at the line indicated in the top panel. (B) Live PtK2 cell coexpressing POM121-YFP3 (red) and SRβ-ECFP (green). AL labeled by POM121 are in direct contact to or colocalize with ER tubules and sheets as marked by SRβ. (C) HeLa cell expressing POM121-EGFP3 (green), fixed and stained for the endogenous nucleoporin p62 (red). Since the p62 antibody did not cross-react in PtK2 cells, HeLa cells were used for this experiment. AL containing POM121 colocalize with p62 antibodies (yellow in the merged lower panel, compare patterns in the split inset images). (D) Live PtK2 cell coexpressing ECFP–lamin B1 (green) and POM121-YFP3 (red). AL labeled by POM121 do not contain lamin B1. (E) Three-dimensional reconstruction of a live NRK cell nucleus expressing EGFP3-Nup153. Projections as in A. (F) Live COS7 cell coexpressing EGFP3-Nup153 (red) and SRβ-ECFP (green). COS7 cells were used for better ER morphology than NRK cells (compare with B). Yellow shows colocalization of AL with ER tubules. (G) COS7 cell expressing EGFP3-Nup153 (red) fixed and stained for the en-dogenous nucleoporin POM121 (red). AL containing Nup153 also label with anti-POM121 antibodies (yellow in the merged lower panel, compare patterns in the split inset images). Some POM121-positive structures do not contain Nup153. (H and I) Cryoimmuno double labeling electron micrographs from HeLa cells expressing POM121-EGFP3. Membrane boundaries are outlined next to the micrographs. Labeled are rat POM121 (10-nm gold) and human p62 (5-nm gold). POM121 and p62 colocalize on fenestrated membrane stacks (AL) in H and nuclear pores in I. M, mitochondria; N, nucleus; C, cytoplasm. Bars: (A–G) 5 μm; (H and I) 200 nm.
	Figure 2. Turnover of NPCs and the lamina measured by FRAP. (A) FRAP of NRKPOM121-YFP3 cells. The boxed area was photobleached to background levels. Recovery was monitored immediately after the bleach and every 30 min by taking a stack of five confocal images after autofocussing. Representative maximum intensity projections are shown. Arrowheads mark the boundary between bleached and nonbleached regions. Time, hh:mm:ss. See Video 1 for the entire sequence. (B) FRAP experiment similar to A of NRK cells transiently expressing EGFP–lamin B1. Single confocal sections 0.5 μm above the coverslip surface were acquired every 15 min after autofocussing. Times, scale, and arrowheads as in A. See Video 2 for the entire sequence. (C) Plot shows fluorescence recovery of POM121 (green) and lamin B1 (black) in the bleached regions. Bleached and nonbleached half of the nuclei were tracked manually to measure mean intensities. Values were background subtracted and then normalized to total loss of fluorescence. Bars, 5 μm. Online supplemental material (Videos 1 and 2) is available at http://www.jcb.org/cgi/content/full/200101089/DC1.
	Figure 3. Turnover of nucleoporins within NPCs and ALPCs measured by FRAP. (A) FRAP of NRK cells expressing POM121-EGFP3 transiently. Boxed regions were photobleached and fluorescence recovery of ALPCs and NPCs was followed immediately after the bleach and then every 28 s in confocal sections. Arrowheads indicate the bleached AL. Note difference in recovery of AL and NPCs. Time, mm:ss. For quantitation see online supplemental Fig. S1 A. (B) FRAP of NRK cells expressing EGFP2-Nup153 transiently. Recovery was monitored immediately after the bleach and then every 5 s. Time and scale as in A. (C) FLIP of PtK2 cells expressing EGFP2-Nup153 transiently. Outlined region was photobleached repetitively 30 times every 30 s. Before and after each bleach the depletion of fluorescence was monitored in a confocal section. Time and scale as in A. (D) Plots of recovery in the bleached half and equilibration between bleached and nonbleached half of a Nup153 FRAP similar to B. Average mean intensities of the bleached region (black, left Y-axis) and standard deviation (n = 4). Data was normalized for total loss of fluorescence. Change of total fluorescence from the nonbleached (green) and bleached half (blue, both right Y-axis) measured for the experiment shown in B. (E) Plots of EGFP2-Nup153 depletion from the nucleus and cytoplasm for the FLIP in C. Average nuclear (black), cytoplasmic (green, both left Y-axis), and ratio of NPC/cytoplasmic fluorescence (blue, right Y-axis) is shown. Data was normalized to total loss of fluorescence. Note that nuclear fluorescence remains constant after initial loss of overlapping cytoplasmic signal, whereas cytoplasmic fluorescence is reduced to background levels. Bars, 5 μm. Online supplemental material (Fig. S1) is available at http://www.jcb.org/cgi/content/full/200101089/DC1.
	Figure 4. Tracking of NPC and lamina movement in interphase. (A) Time-lapse of a NRK cell expressing POM121-EGFP3 transiently. The lower nuclear surface was followed in a single confocal section every 2 s for a total of 30 min on a real-time confocal microscope. Sequence was averaged with a running window of five frames. Representative frames show numbered NPCs in a time window of ∼2 min used for tracking in B. Time, mm:ss. NPC movement is difficult to appreciate in still images; see Video 3 for the complete sequence. (B) Tracking of NPC movement. NPCs labeled #1–5 in A in a region of local NE movement are tracked together with two NPCs labeled C1 and C2 in A, which reside in an area of little movement and serve to illustrate global nuclear drift. Note the parallel and synchronous tracks of the NPCs. (C) Pattern FRAP of an NRK cell nucleus transiently expressing EGFP–Lamin B1. 33 1 × 0.5-μm regions were photobleached in the lower nuclear surface. Movement of landmarks was followed in single confocal sections every minute for 30 min (top row). Marks in the boxed area were used to track elastic deformations of the lamin lattice. Global cellular movement was corrected with two reference points. Relative position changes are shown in the bottom row as a network connecting the center of the bleach marks. Time, h:mm:ss; horizontal box length, 6 μm. (D) Pattern FRAP of a NRK nucleus transiently coexpressing POM121-YFP3 and ECFP–lamin B1. The outlined 21 0.9 × 0.6-μm regions were photobleached selectively in the lamina using a 413-nm Kr laser line. Movement of the lamina landmarks and the unbleached NPCs was then followed in single double-labeled confocal sections every 31 s for 30 min. Representative frames show distortion of nuclear shape by cell migration (note lamina folding at 07:56 and 12:40). Marks and NPCs used for tracking in E are red. Time, mm:ss. See Video 4 to better appreciate lamina elasticity. (E) Tracking of NPCs and lamina bleachmarks. Exemplary time-space tracks are shown for NPC #1 (green) and lamin grid marks A1–B2 (black) over 22 min in x, t and y, t plots. Global nuclear drift was normalized using to B5 and B7 marks. Note correlation between the x and y lamina and NPC movement. NPCs #2 and 3 and the surrounding marks behaved identically (not shown). Bars, 5 μm. Online supplemental material (Videos 3 and 4) is available at http://www.jcb.org/cgi/content/full/200101089/DC1.
	Figure 5. Recruitment of nucleoporins and lamin B1 during nuclear assembly. (A) In vivo localization of transiently expressed POM121-YFP3, EGFP3-Nup153, and ECFP–lamin B1 in metaphase NRK cells. Shown are confocal sections and DIC images centered on the metaphase plate. Note reticular pattern for POM121 and diffuse distribution of Nup153 and lamin B1. (B) 4-D sequence (10 slices every 2.5 μm acquired every 10–60 s depending on the dynamics of the cell cycle stage) of an NRK cell transiently expressing EGFP2-Nup153. Transparent projection of the four slices containing chromosomes (top) and DIC images highlighting the position of the chromosomes (bottom) are shown. Recruitment of Nup153 on the surface of chromosomes starts at ∼4 min after metaphase to anaphase transition. Time, h:mm:ss normalized to meta/anaphase transition equals 0. (C) 4-D double label sequence (six slices every 3 μm acquired every 30–120 s depending on the dynamics of the cell cycle stage) of an NRK cell transiently coexpressing POM121-YFP3 (top) and ECFP–lamin B1 (bottom). Shown are maximum intensity projections of the z-slices containing chromosomes. POM121 recruitment starts ∼3.5 min after meta/anaphase transition, whereas lamin B1 is only seen at 9 min (see D). Time, h:mm:ss normalized to meta/anaphase transition equals 0. (D) Plot of mean fluorescence intensity of the reforming NE for POM121 (green) and lamin B1 (black) shown in B. Before visible accumulation of lamin, nuclear rim areas were identified by POM121 localization. Data was background subtracted and normalized for bleaching during the time series. Lines are moving averages of two frames. Note the delay of ∼5 min between peak concentration/area for POM121 versus lamin B1. Bars: (A) 5 μm; (B and C) 10 μm. Online supplemental material (Fig. S2) is available at http://www.jcb.org/cgi/content/full/200101089/DC1.
	Figure 6. POM121 is immobilized during nuclear assembly in anaphase. FRAP of a NRK cell transiently expressing POM121-EGFP3. (A) Boxed area was photobleached to background levels in metaphase. Recovery was monitored every 9 s in a single image acquired with open pinhole. Note rapid recovery of fluorescence into the ER as the cell reaches metaphase/anaphase transition (02:15). (B) FRAP of the same cell as in A ∼6 min after anaphase onset. Note the absence of complete recovery during the transition to telophase. Times, hh:mm:ss. (C) Plot of recovery in the bleached areas shown in A and B for metaphase (green)and anaphase (black). Data was normalized to total loss of fluorescence, time 0 corresponds to the midpoint of the bleach. Note the difference in IFs 4 min after the bleach. Bars, 5 μm.

Akey, Interactions and structure of the nuclear pore complex revealed by cryo-electron microscopy. 1989, Pubmed, Xenbase

Akey, Interactions and structure of the nuclear pore complex revealed by cryo-electron microscopy. 1989, Pubmed , Xenbase
Allen, The nuclear pore complex: mediator of translocation between nucleus and cytoplasm. 2000, Pubmed
Bastos, Targeting and function in mRNA export of nuclear pore complex protein Nup153. 1996, Pubmed
Belgareh, Dynamics of nuclear pore distribution in nucleoporin mutant yeast cells. 1997, Pubmed
Bodoor, Sequential recruitment of NPC proteins to the nuclear periphery at the end of mitosis. 1999, Pubmed
Broers, Dynamics of the nuclear lamina as monitored by GFP-tagged A-type lamins. 1999, Pubmed
Bucci, In vivo dynamics of nuclear pore complexes in yeast. 1997, Pubmed
Chaudhary, Stepwise reassembly of the nuclear envelope at the end of mitosis. 1993, Pubmed
Collas, Sorting nuclear membrane proteins at mitosis. 2000, Pubmed
Cordes, Cytoplasmic annulate lamellae in cultured cells: composition, distribution, and mitotic behavior. 1996, Pubmed
Cordes, Mediators of nuclear protein import target karyophilic proteins to pore complexes of cytoplasmic annulate lamellae. 1997, Pubmed , Xenbase
Cordes, High content of a nuclear pore complex protein in cytoplasmic annulate lamellae of Xenopus oocytes. 1995, Pubmed , Xenbase
Cordes, Intranuclear filaments containing a nuclear pore complex protein. 1993, Pubmed , Xenbase
Ellenberg, Nuclear membrane dynamics and reassembly in living cells: targeting of an inner nuclear membrane protein in interphase and mitosis. 1997, Pubmed
Ewald, A biochemical and immunological comparison of nuclear and cytoplasmic pore complexes. 1996, Pubmed
Galy, Nuclear pore complexes in the organization of silent telomeric chromatin. 2000, Pubmed
Gerace, The nuclear envelope lamina is reversibly depolymerized during mitosis. 1980, Pubmed
Gerace, Functional organization of the nuclear envelope. 1988, Pubmed
Goldberg, The nuclear pore complex: three-dimensional surface structure revealed by field emission, in-lens scanning electron microscopy, with underlying structure uncovered by proteolysis. 1993, Pubmed , Xenbase
Goldberg, Dimples, pores, star-rings, and thin rings on growing nuclear envelopes: evidence for structural intermediates in nuclear pore complex assembly. 1997, Pubmed , Xenbase
Goldberg, Structural and functional organization of the nuclear envelope. 1995, Pubmed , Xenbase
Gruenbaum, Review: nuclear lamins--structural proteins with fundamental functions. 2000, Pubmed
Hallberg, An integral membrane protein of the pore membrane domain of the nuclear envelope contains a nucleoporin-like region. 1993, Pubmed
Haraguchi, Live fluorescence imaging reveals early recruitment of emerin, LBR, RanBP2, and Nup153 to reforming functional nuclear envelopes. 2000, Pubmed
Houtsmuller, Action of DNA repair endonuclease ERCC1/XPF in living cells. 1999, Pubmed
Imreh, An integral membrane protein from the nuclear pore complex is also present in the annulate lamellae: implications for annulate lamella formation. 2000, Pubmed
Kessel, Annulate lamellae: a last frontier in cellular organelles. 1992, Pubmed
Kubitscheck, Single nuclear pores visualized by confocal microscopy and image processing. 1996, Pubmed
Lenz-Böhme, Insertional mutation of the Drosophila nuclear lamin Dm0 gene results in defective nuclear envelopes, clustering of nuclear pore complexes, and accumulation of annulate lamellae. 1997, Pubmed
Liou, Improving structural integrity of cryosections for immunogold labeling. 1996, Pubmed
Liu, Essential roles for Caenorhabditis elegans lamin gene in nuclear organization, cell cycle progression, and spatial organization of nuclear pore complexes. 2000, Pubmed
Lyman, Nuclear pore complexes: dynamics in unexpected places. 2001, Pubmed
Marelli, A link between the synthesis of nucleoporins and the biogenesis of the nuclear envelope. 2001, Pubmed
Maul, Time sequence of nuclear pore formation in phytohemagglutinin-stimulated lymphocytes and in HeLa cells during the cell cycle. 1972, Pubmed
Maul, Investigation of the determinants of nuclear pore number. 1980, Pubmed , Xenbase
McNally, The glucocorticoid receptor: rapid exchange with regulatory sites in living cells. 2000, Pubmed
Moir, Nuclear lamins A and B1: different pathways of assembly during nuclear envelope formation in living cells. 2000, Pubmed
Nakielny, Nup153 is an M9-containing mobile nucleoporin with a novel Ran-binding domain. 1999, Pubmed
Nehls, Dynamics and retention of misfolded proteins in native ER membranes. 2000, Pubmed
Ostlund, Intracellular trafficking of emerin, the Emery-Dreifuss muscular dystrophy protein. 1999, Pubmed
Panté, Recombinant Nup153 incorporates in vivo into Xenopus oocyte nuclear pore complexes. 2000, Pubmed , Xenbase
Panté, Toward a molecular understanding of the structure and function of the nuclear pore complex. 1995, Pubmed
Patterson, Use of the green fluorescent protein and its mutants in quantitative fluorescence microscopy. 1997, Pubmed
Pollard, In vitro posttranslational modification of lamin B cloned from a human T-cell line. 1990, Pubmed
Rout, The yeast nuclear pore complex: composition, architecture, and transport mechanism. 2000, Pubmed
Ryan, The nuclear pore complex: a protein machine bridging the nucleus and cytoplasm. 2000, Pubmed
Sciaky, Golgi tubule traffic and the effects of brefeldin A visualized in living cells. 1997, Pubmed
Shah, Separate nuclear import pathways converge on the nucleoporin Nup153 and can be dissected with dominant-negative inhibitors. , Pubmed , Xenbase
Smythe, Incorporation of the nuclear pore basket protein nup153 into nuclear pore structures is dependent upon lamina assembly: evidence from cell-free extracts of Xenopus eggs. 2000, Pubmed , Xenbase
Söderqvist, Formation of nuclear bodies in cells overexpressing the nuclear pore protein POM121. 1996, Pubmed
Söderqvist, Intracellular distribution of an integral nuclear pore membrane protein fused to green fluorescent protein--localization of a targeting domain. 1997, Pubmed
Stafstrom, Are annulate lamellae in the Drosophila embryo the result of overproduction of nuclear pore components? 1984, Pubmed
Stick, The fates of chicken nuclear lamin proteins during mitosis: evidence for a reversible redistribution of lamin B2 between inner nuclear membrane and elements of the endoplasmic reticulum. 1988, Pubmed
Sukegawa, A nuclear pore complex protein that contains zinc finger motifs, binds DNA, and faces the nucleoplasm. 1993, Pubmed
Ullman, The nucleoporin nup153 plays a critical role in multiple types of nuclear export. 1999, Pubmed , Xenbase
Wilson, The nuclear envelope, muscular dystrophy and gene expression. 2000, Pubmed
Winey, Nuclear pore complex number and distribution throughout the Saccharomyces cerevisiae cell cycle by three-dimensional reconstruction from electron micrographs of nuclear envelopes. 1997, Pubmed
Wozniak, The single transmembrane segment of gp210 is sufficient for sorting to the pore membrane domain of the nuclear envelope. 1992, Pubmed
Zaal, Golgi membranes are absorbed into and reemerge from the ER during mitosis. 1999, Pubmed