Involvement of the lamin rod domain in heterotypic lamin interactions important for nuclear organization

The nuclear lamina is a meshwork of intermediate-type filament proteins (lamins) that lines the inner nuclear membrane. The lamina is proposed to be an important determinant of nuclear structure, but there has been little direct testing of this idea. To investigate lamina functions, we have characterized a novel lamin B1 mutant lacking the middle approximately 4/5 of its alpha-helical rod domain. Though retaining only 10 heptads of the rod, this mutant assembles into intermediate filament-like structures in vitro. When expressed in cultured cells, it concentrates in patches at the nuclear envelope. Concurrently, endogenous lamins shift from a uniform to a patchy distribution and lose their complete colocalization, and nuclei become highly lobulated. In vitro binding studies suggest that the internal rod region is important for heterotypic associations of lamin B1, which in turn are required for proper organization of the lamina. Accompanying the changes in lamina structure induced by expression of the mutant, nuclear pore complexes and integral membrane proteins of the inner membrane cluster, principally at the patches of endogenous lamins. Considered together, these data indicate that lamins play a major role in organizing other proteins in the nuclear envelope and in determining nuclear shape.     

A monoclonal antibody against nuclear lamina proteins reveals cell type-specificity in Xenopus laevis

Immunofluorescence microscopy shows that the monoclonal murine antibody PKB8 stains the nuclear lamina of various somatic cells from vertebrates as diverse as mammals, birds and amphibia. It also decorates the nuclear periphery of oocytes from rat and chicken but does not react with spermatocytes, spermatids and spermatozoa. Immunoblotting experiments demonstrate reaction with lamina polypeptides A, B and C of rat, with lamina polypeptide A of chicken, and with lamina polypeptides LI and LII of erythrocytes of the frog, Xenopus laevis. Antibody PKB8 does, however, not bind, on blotted polypeptides and on sections through ovaries, to the pore complex-lamina polypeptide of Mr 68000 present in Xenopus oocytes. These results reveal the existence of a common antigenic determinant in all three lamina polypeptides of mammals, in one lamina polypeptide of chicken and in two amphibian lamina polypeptides. The immunological data also indicate that, in Xenopus laevis, pore complex-lamina polypeptides of somatic cells and oocytes are distinct. The Mr 68000 protein of Xenopus oocytes is also different from polypeptides LI and LII of somatic Xenopus cells by tryptic peptide mapping. The results suggest that nuclear pore complex-lamina polypeptides represent a family of related polypeptides containing regions highly conserved during evolution and that these polypeptides can be differentially expressed in cells of at least one species, Xenopus laevis.     

A carboxyl-terminal interaction of lamin B1 is dependent on the CAAX endoprotease Rce1 and carboxymethylation

The mammalian nuclear lamina protein lamin B1 is posttranslationally modified by farnesylation, endoproteolysis, and carboxymethylation at a carboxyl-terminal CAAX motif. In this work, we demonstrate that the CAAX endoprotease Rce1 is required for lamin B1 endoproteolysis, demonstrate an independent pool of proteolyzed but nonmethylated lamin B1, as well as fully processed lamin B1, in interphase nuclei, and show a role for methylation in the organization of lamin B1 into domains of the nuclear lamina. Deficiency in the endoproteolysis or methylation of lamin B1 results in loss of integrity and deformity of the nuclear lamina. These data show that the organization of the nuclear envelope and lamina is dependent on a mechanism involving the methylation of lamin B1, and they identify a potential mechanism of laminopathy involving a B-type lamin.     

Nuclear protein import is reduced in cells expressing nuclear envelopathy-causing lamin A mutants

Lamins, which form the nuclear lamina, not only constitute an important determinant of nuclear architecture, but additionally play essential roles in many nuclear functions. Mutations in A-type lamins cause a wide range of human genetic disorders (laminopathies). The importance of lamin A (LaA) in the spatial arrangement of nuclear pore complexes (NPCs) prompted us to study the role of LaA mutants in nuclear protein transport. Two mutants, causing prenatal skin disease restrictive dermopathy (RD) and the premature aging disease Hutchinson Gilford progeria syndrome, were used for expression in HeLa cells to investigate their impact on the subcellular localization of NPC-associated proteins and nuclear protein import. Furthermore, dynamics of the LaA mutants within the nuclear lamina were studied. We observed affected localization of NPC-associated proteins, diminished lamina dynamics for both LaA mutants and reduced nuclear import of representative cargo molecules. Intriguingly, both LaA mutants displayed similar effects on nuclear morphology and functions, despite their differences in disease severity. Reduced nuclear protein import was also seen in RD fibroblasts and impaired lamina dynamics for the nucleoporin Nup153. Our data thus represent the first study of a direct link between LaA mutant expression and reduced nuclear protein import.     

The nuclear lamina and heterochromatin: a complex relationship

In metazoan cells, the heterochromatin is generally localized at the nuclear periphery, whereas active genes are preferentially found in the nuclear interior. In the present paper, we review current evidence showing that components of the nuclear lamina interact directly with heterochromatin, which implicates the nuclear lamina in a mechanism of specific gene retention at the nuclear periphery and release to the nuclear interior upon gene activation. We also discuss recent data showing that mutations in lamin proteins affect gene positioning and expression, providing a potential mechanism for how these mutations lead to tissue-specific diseases.     

Degradation of the nuclear matrix is a common element during radiation-induced apoptosis and necrosis

Human promyelocytic leukemia (HL60) cells were irradiated with 10 or 50 Gy of X rays and studied for up to 72 h postirradiation to determine the mode of death and assess changes in the nuclear matrix. After 50 Gy irradiation, cells were found to die early, primarily by apoptosis, while cells irradiated with 10 Gy died predominantly by necrosis. Disassembly of the nuclear lamina and degradation of the nuclear matrix protein lamin B occurred in cells undergoing radiation-induced apoptosis or necrosis. However, using Western blotting and a recently developed flow cytometry assay to detect changes in nuclear matrix protein content, we found that the kinetics and mechanisms of disassembly of the nuclear lamina are different for each mode of cell death. During radiation-induced apoptosis, cleavage and degradation of lamin B to a approximately 28-kDa fragment was detected in most cells within 4-12 h after irradiation. Measurements of dual-labeled apoptotic cells revealed that nonrandom DNA fragmentation was evident prior to or concomitant with breakdown of the nuclear lamina. Disassembly of the nuclear lamina during radiation-induced necrosis occurred much later (between 30-60 h after irradiation), and a different cleavage pattern of lamin B was observed. Degradation of the nuclear lamina was also inhibited in apoptosis-resistant BCL2-overexpressing HL60 cells exposed to 50 Gy until approximately 48 h after irradiation. These data indicate that breakdown of the nuclear matrix may be a common element in radiation-induced apoptosis and necrosis, but that the mechanisms and temporal patterns of breakdown of the nuclear lamina during apoptosis are distinct from those of necrosis.     

Review: nuclear lamins--structural proteins with fundamental functions

The nuclear lamina is located between the inner nuclear membrane and the peripheral chromatin. It is composed of both peripheral and integral membrane proteins, including lamins and lamina-associated proteins. Lamins can interact with one another, with lamina-associated proteins, with nuclear scaffold proteins, and with chromatin. Likewise, most of the lamina-associated proteins are likely to interact directly with chromatin. The nuclear lamina is required for proper cell cycle regulation, chromatin organization, DNA replication, cell differentiation, and apoptosis. Mutations in proteins of the nuclear lamina can disrupt these activities and cause genetic diseases. The structure and assembly of the nuclear lamina proteins and their roles in chromatin organization and cell cycle regulation were recently reviewed. In this review, we discuss the roles of the nuclear lamina in DNA replication and apoptosis and analyze how mutations in nuclear lamina proteins might cause genetic diseases.     

Breaking and making of the nuclear envelope

During mitosis, a single nucleus gives rise to two nuclei that are identical to the parent nucleus. Mitosis consists of a continuous sequence of events that must be carried out once and only once. Two such important events are the disassembly of the nuclear envelope (NE) during the first stages of mitosis, and its accurate reassembly during the last stages of mitosis. NE breakdown (NEBD) is initiated when maturation-promoting factor (MPF) enters the nucleus and starts phosphorylating nuclear pore complexes (NPCs) and nuclear lamina proteins, followed by NPC and lamina breakdown. Nuclear reassembly starts when nuclear membranes assemble onto the chromatin. This article focuses on the different models of NEBD and reassembly with emphasis on recent data.     

Nuclear envelope proteins from Spisula solidissima germinal vesicles

Biochemical characterization of the nuclear pore complex requires quantities of highly enriched nuclear pore complex material which could not be obtained with available procedures. We have developed a technique for the mass isolation of nuclear envelopes from germinal vesicles of Spisula solidissima oocytes. The nuclear pore complex is intact after isolation as judged ultrastructurally. The nuclear envelope and the pore complex fibrous lamina fraction are highly purified with respect to nuclear and cytoplasmic protein contaminants. The fibrous lamina pore complex (FLPC) as presently isolated consists of about eight major proteins, three of which are phosphorylated. Comparison of the FLPC of clams with that of rat reveals three proteins of similar molecular weights, which may be pore complex-specific proteins. The clam nuclear envelope has only one protein (67000) in the molecular weight range which is comparable to the three lamina of rat nuclei. The solubility, intermolecular cross-linking and in vitro phosphorylation of this protein resemble that of one of the lamina of rat nuclei. The other lamina of the rat nuclear envelope are not essential proteins of the pore complex because they are not present in the clam FLPC preparation. They also seem non-essential for the maintenance of the fibrous lamina.     

Disappearance and reformation of the nuclear lamina structure during specific stages of meiosis in oocytes

The nuclear lamina is a rigid, proteinaceous layer underlying the inner nuclear membrane of eucaryotic cells. It is present in somatic cell nuclei, disappears during mitosis, and is absent from male meiotic cells. We have investigated the disappearance and reformation of the nuclear lamina during meiosis in oocytes, using immunofluorescence and electron microscopy. We find that the status of the nuclear lamina during meiosis of oocytes differs from the reversible depolymerization seen in mitosis in two respects. First, the lamina disappears during meiotic prophase without affecting the structure of the nuclear membranes or the nuclear pores. Second, the proteins of the dissociated lamina are undetectable by immunological methods in pachytene oocytes, whereas they persist in the cytoplasm during mitosis.     

Identification of a short nuclear lamin protein selectively expressed during meiotic stages of rat spermatogenesis

The nuclear lamina is a karyoskeletal structure located at the nuclear periphery and intimately associated with the inner nuclear membrane. It is composed of a multigene family of proteins, the lamins, which show a conspicuous cell type-specific expression pattern. The functional role of lamins has not been definitively established but available information indicates that they are involved in the organization of nuclear envelope and interphase chromatin. Spermatogenesis is characterized, among other features, by stage-specific changes in chromatin organization and function. These changes are accompanied by modifications in the organization and composition of the nuclear lamina. In previous experiments we have determined that rat spermatogenic cells express a lamin closely related, if not identical, to lamin B1 of somatic cells; whereas rat somatic lamins A, C, D and E were not detected. Considering that chromatin reorganizations during spermatogenesis may be directly or indirectly related to changes of the nuclear lamina we have decided to further investigate lamin expression during this process. Here we report on the identification of a 52 kDa protein of the rat which, according to immunocytochemical and biochemical data, appears to be a novel nuclear lamin. Using meiotic stage-specific markers, we have also demonstrated that this short lamin is selectively expressed during meiotic stages of spermatogenesis.     

Fate of the inner nuclear membrane protein lamin B receptor and nuclear lamins in herpes simplex virus type 1 infection

During herpesvirus egress, capsids bud through the inner nuclear membrane. Underlying this membrane is the nuclear lamina, a meshwork of intermediate filaments with which it is tightly associated. Details of alterations to the lamina and the inner nuclear membrane during infection and the mechanisms involved in capsid transport across these structures remain unclear. Here we describe the fate of key protein components of the nuclear envelope and lamina during herpes simplex virus type 1 (HSV-1) infection. We followed the distribution of the inner nuclear membrane protein lamin B receptor (LBR) and lamins A and B(2) tagged with green fluorescent protein (GFP) in live infected cells. Together with additional results from indirect immunofluorescence, our studies reveal major morphologic distortion of nuclear-rim LBR and lamins A/C, B(1), and B(2). By 8 h p.i., we also observed a significant redistribution of LBR-GFP to the endoplasmic reticulum, where it colocalized with a subpopulation of cytoplasmic glycoprotein B by immunofluorescence. In addition, analysis by fluorescence recovery after photobleaching reveals that LBR-GFP exhibited increased diffusional mobility within the nuclear membrane of infected cells. This is consistent with the disruption of interactions between LBR and the underlying lamina. In addition to studying stably expressed GFP-lamins by fluorescence microscopy, we studied endogenous A- and B-type lamins in infected cells by Western blotting. Both approaches reveal a loss of lamins associated with virus infection. These data indicate major disruption of the nuclear envelope and lamina of HSV-1-infected cells and are consistent with a virus-induced dismantling of the nuclear lamina, possibly in order to gain access to the inner nuclear membrane.     

Overexpression of the lamina proteins Lamin and Kugelkern induces specific ultrastructural alterations in the morphology of the nuclear envelope of intestinal stem cells and enterocytes

The nuclear envelope has a stereotypic morphology consisting of a flat double layer of the inner and outer nuclear membrane, with interspersed nuclear pores. Underlying and tightly linked to the inner nuclear membrane is the nuclear lamina, a proteinous layer of intermediate filament proteins and associated proteins. Physiological, experimental or pathological alterations in the constitution of the lamina lead to changes in nuclear morphology, such as blebs and lobulations. It has so far remained unclear whether the morphological changes depend on the differentiation state and the specific lamina protein. Here we analysed the ultrastructural morphology of the nuclear envelope in intestinal stem cells and differentiated enterocytes in adult Drosophila flies, in which the proteins Lam, Kugelkern or a farnesylated variant of LamC were overexpressed. Surprisingly, we detected distinct morphological features specific for the respective protein. Lam induced envelopes with multiple layers of membrane and lamina, surrounding the whole nucleus whereas farnesylated LamC induced the formation of a thick fibrillary lamina. In contrast, Kugelkern induced single-layered and double-layered intranuclear membrane structures, which are likely be derived from infoldings of the inner nuclear membrane or of the double layer of the envelope.     

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.     

Stepwise reassembly of the nuclear envelope at the end of mitosis

The nuclear envelope consists of three distinct membrane domains: the outer membrane with the bound ribosomes, the inner membrane with the bound lamina, and the pore membrane with the bound pore complexes. Using biochemical and morphological methods, we observed that the nuclear membranes of HeLa cells undergoing mitosis are disassembled in a domain-specific manner, i.e., integral membrane proteins representing the inner nuclear membrane (the lamin B receptor) and the nuclear pore membrane (gp210) are segregated into different populations of mitotic vesicles. At the completion of mitosis, the inner nuclear membrane- derived vesicles associate with chromatin first, beginning in anaphase, whereas the pore membranes and the lamina assemble later, during telophase and cytokinesis. Our data suggest that the ordered reassembly of the nuclear envelope is triggered by the early attachment of inner nuclear membrane-derived vesicles to the chromatin.     

Immunological analysis of nuclear lamina proteins

Antibodies have been obtained against specific fractions of the nuclear lamina from chick red blood cells. Immunofluorescent staining of acrylamide gels from nuclear lamina preparations revealed a spectrum of at least 8–10 proteins cross-reacting immunologically with each other. These proteins are not the result of proteolysis in the course of preparation. The antigens are localized in the nuclear periphery and do not extend into the chromatin. Interspecies cross-reactions enabled us to localize the antigens in the envelope of Xenopus oocyte nuclei. In this case any association with the chromatin is unlikely. During mitosis the antigens are released from the nuclear lamina and are recovered from the postmicrosomal supernatant. The molecular weights of the nuclear lamina proteins do not change during mitosis.     

Disruption of Nuclear Lamin Organization Alters the Distribution of Replication Factors and Inhibits DNA Synthesis

The nuclear lamina is a fibrous structure that lies at the interface between the nuclear envelope and the nucleoplasm. The major proteins comprising the lamina, the nuclear lamins, are also found in foci in the nucleoplasm, distinct from the peripheral lamina. The nuclear lamins have been associated with a number of processes in the nucleus, including DNA replication. To further characterize the specific role of lamins in DNA replication, we have used a truncated human lamin as a dominant negative mutant to perturb lamin organization. This protein disrupts the lamin organization of nuclei when microinjected into mammalian cells and also disrupts the lamin organization of in vitro assembled nuclei when added to Xenopus laevis interphase egg extracts. In both cases, the lamina appears to be completely absent, and instead the endogenous lamins and the mutant lamin protein are found in nucleoplasmic aggregates. Coincident with the disruption of lamin organization, there is a dramatic reduction in DNA replication. As a consequence of this disruption, the distributions of PCNA and the large subunit of the RFC complex, proteins required for the elongation phase of DNA replication, are altered such that they are found within the intranucleoplasmic lamin aggregates. In contrast, the distribution of XMCM3, XORC2, and DNA polymerase α, proteins required for the initiation stage of DNA replication, remains unaltered. The data presented demonstrate that the nuclear lamins may be required for the elongation phase of DNA replication.