A role for nuclear lamins in nuclear envelope assembly.

The molecular interactions responsible for nuclear envelope assembly after mitosis are not well understood. In this study, we demonstrate that a peptide consisting of the COOH-terminal domain of Xenopus lamin B3 (LB3T) prevents nuclear envelope assembly in Xenopus interphase extracts. Specifically, LB3T inhibits chromatin decondensation and blocks the formation of both the nuclear lamina-pore complex and nuclear membranes. Under these conditions, some vesicles bind to the peripheral regions of the chromatin. These "nonfusogenic" vesicles lack lamin B3 (LB3) and do not bind LB3T; however, "fusogenic" vesicles containing LB3 can bind LB3T, which blocks their association with chromatin and, subsequently, nuclear membrane assembly. LB3T also binds to chromatin in the absence of interphase extract, but only in the presence of purified LB3. Additionally, we show that LB3T inhibits normal lamin polymerization in vitro. These findings suggest that lamin polymerization is required for both chromatin decondensation and the binding of nuclear membrane precursors during the early stages of normal nuclear envelope assembly.     

A-type and B-type lamins initiate layer assembly at distinct areas of the nuclear envelope in living cells

To investigate nuclear lamina re-assembly in vivo, Drosophila A-type and B-type lamins were artificially expressed in Drosophila lamin Dm₀null mutant brain cells. Both exogenous lamin C (A-type) and Dm₀ (B-type) formed sub-layers at the nuclear periphery, and efficiently reverted the abnormal clustering of the NPC. Lamin C initially appeared where NPCs were clustered, and subsequently extended along the nuclear periphery accompanied by the recovery of the regular distribution of NPCs. In contrast, lamin Dm₀ did not show association with the clustered NPCs during lamina formation and NPC spacing recovered only after completion of a closed lamin Dm₀ layer. Further, when lamin Dm₀ and C were both expressed, they did not co-polymerize, initiating layer formation in separate regions. Thus, A and B-type lamins reveal differing properties during lamina assembly, with A-type having the primary role in organizing NPC distribution. This previously unknown complexity in the assembly of the nuclear lamina could be the basis for intricate nuclear envelope functions.     

Nuclear envelope localization of human UNC84A does not require nuclear lamins

The SUN proteins are a conserved family of proteins in eukaryotes. Human UNC84A (Sun1) is a homolog of Caenorhabditis elegans UNC-84, a protein involved in nuclear anchorage and migration. We have analyzed targeting of UNC84A to the nuclear envelope (NE) and show that the N-terminal 300 amino acids are crucial for efficient NE localization of UNC84A whereas the conserved C-terminal SUN domain is not required. Furthermore, we demonstrate by combining RNA interference with immunofluorescence and fluorescence recovery after photobleaching analysis that localization and anchoring of UNC84A is not dependent on the lamin proteins, in contrast to what had been observed for C. elegans UNC-84.     

Type B lamins remain associated with the integral nuclear envelope protein p58 during mitosis: implications for nuclear reassembly.

p58 (also referred to as the lamin B receptor) is an integral membrane protein of the nuclear envelope known to form a multimeric complex with the lamins and other nuclear proteins during interphase. To examine the fate of this complex during mitosis, we have investigated the partitioning and the molecular interactions of p58 in dividing chicken hepatoma (DU249) cells. Using confocal microscopy and double immunolabelling, we show here that lamins B1 and B2 co-localize with p58 during all phases of mitosis and co-assemble around reforming nuclei. A close juxtaposition of p58/lamin B-containing vesicles and chromosomes is already detectable in metaphase; however, p58 and lamin reassembly proceeds slowly and is completed in late telophase--G1. Flotation of mitotic membranes in sucrose density gradients and analysis of mitotic vesicles by immunoelectron microscopy confirms that p58 and most of the type B lamins reside in the same compartment. Co-immunoprecipitation of both proteins by affinity-purified anti-p58 antibodies shows that they are physically associated in the context of a mitotic p58 'sub-complex'. This sub-assembly does not include the type A lamins which are fully solubilized during mitosis. Our data provide direct, in vivo and in vitro evidence that the majority of type B lamins remain connected to nuclear membrane 'receptors' during mitosis. The implications of these findings in nuclear envelope reassembly are discussed below.     

Lamin B methylation and assembly into the nuclear envelope

Lamin B is reversibly methyl-esterified and phosphorylated during the mammalian cell cycle. In order to study the role of methylation in lamin B function, we isolated mitotic cells in the presence of the microtubule inhibitor, nocodazole. Following removal of nocodazole, methylation of mitotic lamin B was found to precede its assembly into the nuclear envelope as cells exited mitosis. Very little additional methylation took place on assembled lamins. We were able to slow the rate of lamin B methylation with methylthioadenosine (MTA). A delay in lamin B methylation was accompanied by a corresponding delay in assembly of lamin B into the envelope. The delay was approximately 20-30 min beyond the typical 60-70 min usually required. Assembly of lamins A and C, which are not methylated, was also delayed by MTA, although to a lesser degree, suggesting that an interaction between the lamins is necessary for formation of the nuclear envelope. Chromatin decondensation was also slowed in the presence of MTA. Other inhibitors of methylation which had no inhibitory effect on the methyl esterification of lamin B were tested and found to have no effect on envelope assembly or chromatin decondensation. These results were obtained with Chinese hamster ovary cells as well as with the stem cell line, PC 13. Dephosphorylation of lamin B normally follows a time course similar to that of nuclear envelope assembly. In the presence of MTA, however, lamin B assembly was slowed with little effect on dephosphorylation. This resulted in a large population of dephosphorylated, but unassembled, lamin B protein, demonstrating that dephosphorylation is not sufficient for envelope assembly. The lack of effect on the time course of dephosphorylation also suggests that MTA is not acting upstream of the methylation event.     

Redistribution of nuclear lamins in mitotic cells

The nuclear lamins are directed from the cytoplasm to chromosomes as part of the maturation pathway of the interphase nucleoskeleton. In mitosis, the three polypeptides lamin A, B and C were found in the cytoplasm from prophase until anaphase and shifted to chromosomal surfaces at telophase (Ely, D'Arcy and Jost, 1978; Gerace, Blum and Blobel, 1978). We show here that early events in nucleoskeleton formation could be regulated by extracellular pH. When exponentially growing tissue culture cells and cells arrested in mitosis were exposed to different extracellular pH values, three patterns of distribution of lamins were observed in mitotic cells: exclusively cytoplasmic distribution of mitotic lamins at low pH (6.8 to 7.3); a premature association of a lamin subfraction with metaphase chromosomes at intermediate pH 7.5; a more prominent relocation of lamins onto chromosomes in metaphase and in disorganized metaphase at pH 8.0. Reassembly of lamins occurred at telomeric ends of mitotic chromosomes followed by a lateral fusion to form a nuclear cage. Using immunogold localization, we show that pH-induced, premature, partial deposition of lamins onto condensed chromosomes may occur prior to the formation of the bilamellar nuclear envelope. These results suggest that the pH-induced redistribution of lamins acts to trigger early events of mitosis to interphase transition.     

Ran GTPase cycle and importins alpha and beta are essential for spindle formation and nuclear envelope assembly in living Caenorhabditis elegans embryos

The small GTPase Ran has been found to play pivotal roles in several aspects of cell function. We have investigated the role of the Ran GTPase cycle in spindle formation and nuclear envelope assembly in dividing Caenorhabditis elegans embryos in real time. We found that Ran and its cofactors RanBP2, RanGAP, and RCC1 are all essential for reformation of the nuclear envelope after cell division. Reducing the expression of any of these components of the Ran GTPase cycle by RNAi leads to strong extranuclear clustering of integral nuclear envelope proteins and nucleoporins. Ran, RanBP2, and RanGAP are also required for building a mitotic spindle, whereas astral microtubules are normal in the absence of these proteins. RCC1(RNAi) embryos have similar abnormalities in the initial phase of spindle formation but eventually recover to form a bipolar spindle. Irregular chromatin structures and chromatin bridges due to spindle failure were frequently observed in embryos where the Ran cycle was perturbed. In addition, connection between the centrosomes and the male pronucleus, and thus centrosome positioning, depends upon the Ran cycle components. Finally, we have demonstrated that both IMA-2 and IMB-1, the homologues of vertebrate importin alpha and beta, are essential for both spindle assembly and nuclear formation in early embryos.     

Relation between nuclear envelope and nuclear lamina in nuclear assembly in vitro

Xenopus laevis egg extracts cell-free nuclear assembly system was used as an experimental model to study the process of nuclear lamina assembly in nuclear reconstitution in vitro. The experimental results showed that lamin was involved in the nuclear assembly in vitro. The assembly of nuclear lamina was preceded by the assembly of nuclear matrix, and probably, inner nuclear matrix assembly provided the basis for nuclear lamina assembly. Inhibition of normal assembly of nuclear lamina, by preincubating egg extracts cell-free system with anti-lamin antibodies, resulted in abnormal assembly of nuclear envelope, suggesting that nuclear envelope assembly is closely associated with nuclear lamina assembly.     

Concentration of Ran on chromatin induces decondensation,nuclear envelope formation and nuclear pore complex assembly

Nuclear envelope (NE) formation can be studied in a cell-free system made from Xenopus eggs. In this system, NE formation involves the small GTPase Ran. Ran associates with chromatin early in nuclear assembly and concentration of Ran on inert beads is sufficient to induce NE formation. Here, we show that Ran binds to chromatin prior to NE formation and recruits RCC1, the nucleotide exchange factor that generates Ran-GTP. In extracts prepared by high-speed centrifugation, increased concentrations of Ran are sufficient to induce chromatin decondensation and NE assembly. Using field emission in-lens scanning electron microscopy (FEISEM), we show that Ran promotes the formation of smoothed membranes and the assembly of nuclear pore complexes (NPCs). In contrast, RanT24N, a mutant that fails to bind GTP and inhibits RCC1, does not support efficient NE assembly, whereas RanQ69L, a mutant locked in a GTP-bound state, permits some membrane vesicle recruitment to chromatin, but inhibits vesicle fusion and NPC assembly. Thus, binding of Ran to chromatin, followed by local generation of Ran-GTP and GTP hydrolysis by Ran, induces chromatin decondensation, membrane vesicle recruitment, membrane formation and NPC assembly. We propose that the biological activity of Ran is determined by its targeting to structures such as chromatin as well as its guanine nucleotide bound state.     

Relation between nuclear envelope and nuclear lamina in nuclear assembly in vitro

Xenopus laevis egg extracts cell-free nuclear assembly system was used as an experimental model to study the process of nuclear lamina assembly in nuclear reconstitutionin vitro. The experimental results showed that lamin was involved in the nuclear assemblyin vitro. The assembly of nuclear lamina was preceded by the assembly of nuclear matrix, and probably, inner nuclear matrix assembly provided the basis for nuclear lamina assembly. Inhibition of normal assembly of nuclear Iknina, by preincubating egg extracts cell-free system with anti-lamin antibodies, resulted in abnormal assembly of nuclear envelope, suggesting that nuclear envelope assembly is closely associated with nuclear lamina assembly. Project supported by the National Natural Science Foundation of China.     

Temporal control of nuclear envelope assembly by phosphorylation of lamin B receptor

The nuclear envelope of metazoans disassembles during mitosis and reforms in late anaphase after sister chromatids have well separated. The coordination of these mitotic events is important for genome stability, yet the temporal control of nuclear envelope reassembly is unknown. Although the steps of nuclear formation have been extensively studied in vitro using the reconstitution system from egg extracts, the temporal control can only be studied in vivo. Here, we use time-lapse microscopy to investigate this process in living HeLa cells. We demonstrate that Cdk1 activity prevents premature nuclear envelope assembly and that phosphorylation of the inner nuclear membrane protein lamin B receptor (LBR) by Cdk1 contributes to the temporal control. We further identify a region in the nucleoplasmic domain of LBR that inhibits premature chromatin binding of the protein. We propose that this inhibitory effect is partly mediated by Cdk1 phosphorylation. Furthermore, we show that the reduced chromatin-binding ability of LBR together with Aurora B activity contributes to nuclear envelope breakdown. Our studies reveal for the first time a mechanism that controls the timing of nuclear envelope reassembly through modification of an integral nuclear membrane protein.     

The integral membrane nucleoporin pom121 functionally links nuclear pore complex assembly and nuclear envelope formation

The metazoan nuclear envelope (NE) breaks down and reforms at each mitosis. Nuclear pore complexes (NPCs), which allow nucleocytoplasmic transport during interphase, assemble into the reforming NE at the end of mitosis. Using in vitro NE assembly assays, we show that one of the two transmembrane nucleoporins, pom121, is essential for NE formation, whereas the second, gp210, is dispensable. Depletion of either pom121-containing membrane vesicles or the protein alone does not affect vesicle binding to chromatin but prevents their fusion to form a closed NE. When the Nup107-160 complex, which is essential for integration of NPCs into the NE, is also depleted, pom121 becomes dispensable for NE formation, suggesting a close functional link between NPC and NE formation and the existence of a checkpoint that monitors NPC assembly state.     

Structural organization of nuclear lamins A,C, B1, and B2 revealed by superresolution microscopy

The nuclear lamina is a key structural element of the metazoan nucleus. However, the structural organization of the major proteins composing the lamina is poorly defined. Using three-dimensional structured illumination microscopy and computational image analysis, we characterized the supramolecular structures of lamin A, C, B1, and B2 in mouse embryo fibroblast nuclei. Each isoform forms a distinct fiber meshwork, with comparable physical characteristics with respect to mesh edge length, mesh face area and shape, and edge connectivity to form faces. Some differences were found in face areas among isoforms due to variation in the edge lengths and number of edges per face, suggesting that each meshwork has somewhat unique assembly characteristics. In fibroblasts null for the expression of either lamins A/C or lamin B1, the remaining lamin meshworks are altered compared with the lamin meshworks in wild-type nuclei or nuclei lacking lamin B2. Nuclei lacking LA/C exhibit slightly enlarged meshwork faces and some shape changes, whereas LB1-deficient nuclei exhibit primarily a substantial increase in face area. These studies demonstrate that individual lamin isoforms assemble into complex networks within the nuclear lamina and that A- and B-type lamins have distinct roles in maintaining the organization of the nuclear lamina.     

Nuclear envelope disassembly and nuclear lamina depolymerization during germinal vesicle breakdown in starfish

During germinal vesicle breakdown (GVBD) in starfish, the nuclear envelope disassembles before the nuclear lamina completely depolymerizes, judging from correlative ultrastructural, immunolabeling, and light microscopic analyses. At 13 degrees C, prophase-arrested oocytes of Pisaster ochraceus begin GVBD and rapidly undergo nuclear envelope disassembly about 50 min after addition of the maturation-inducing hormone 1-methyladenine (1-MA). The nuclear lamina of these oocytes, however, remains present for 10-20 min following the vesiculation of the nuclear envelope. Completion of GVBD, as evidenced by a blending of the nuclear contents with the surrounding cytoplasm, occurs within about 15 min after the nuclear lamina has fully depolymerized. Immunofluorescence studies also indicate that a marked increase in the phosphorylations of nuclear proteins precedes the structural reorganizations of the nuclear envelope and nuclear lamina during GVBD.