Nuclear lamins and peripheral nuclear antigens during fertilization and embryogenesis in mice and sea urchins.

Nuclear structural changes during fertilization and embryogenesis in mice and in sea urchins have been followed by using antibodies against the nuclear lamins A/C and B and against antigens at the periphery of nuclei and chromosomes. Lamins are found on all pronuclei and nuclei during mouse fertilization, but with a diminished intensity on the second polar body nucleus. On sperm in both systems, lamins are reduced and detected only at the acrosomal and centriolar fossae. In sea urchin eggs, lamins are found on both pronuclei. Unlike in other dividing cells, the mitotic chromosomes of sea urchin eggs and embryos retain an association with lamins. The peripheral antibodies delineate each chromosome and nucleus except the mature mouse sperm nucleus. A dramatic change from the expected lamin distribution occurs during early development. In mouse morulae or blastocysts, lamins A/C are no longer recognized, although lamin B remains. In sea urchins both lamins A/C and lamin B, as detected with polyclonal antibodies, are lost after the blastula stage, although a different lamin A/C epitope emerges as recognized by a monoclonal antibody. These results demonstrate that pronucleus formation in both systems involves a new association or exposure of lamins, that the polar body nucleus is largely restricted from the cytoplasmic pool of lamins, and that mitotic chromosomes in the rapidly proliferating sea urchin egg retain associated lamins. They also suggest that changes in the expression or exposure of different lamins are a common feature of embryogenesis.     

Lamin expression in human adipose cells in relation to anatomical site and differentiation state

Familial partial lipodystrophy-Dunnigan variety (FPLD) is an autosomal dominant form of lipodystrophy resulting in a loss of sc fat from the trunk and limbs with retention of fat in the visceral depots, face, and neck. Specific point mutations in the gene encoding the nuclear lamina proteins, lamins A and C, have been established to cause this syndrome. We undertook studies to determine which members of the lamin family were expressed in human fat cells, to examine the effect of differentiation state on lamin A and C expression in human preadipocytes, and to test the hypothesis that regional variation in lamin A/C expression might underlie the stereotyped anatomical pattern of FPLD. Lamins A, C, and B1, but not B2, were expressed in sc mature human adipocytes. Subcutaneous preadipocytes expressed all four lamins, with lamin A and C expression increasing with ex vivo differentiation. Consistent with previously reported resistance to ex vivo differentiation, omental preadipocytes did not show an increase in lamin A or C mRNA under these conditions. Lamin A/C mRNA levels were similar in isolated mature adipocytes and preadipocytes from omental, sc, and neck sites. However, lamin C was consistently lower, and the ratio of lamin A/C mRNA was higher in sc mature adipocytes compared with omental mature adipocytes. We conclude that the depot-specific pattern of lamin A/C expression does not provide clues to the mechanism of FPLD. Nonetheless, these studies provide new information regarding the expression of lamin isoforms in normal human adipose cells, which will inform future studies of the molecular pathogenesis of FPLD.     

Evidence that rodent epididymal sperm contain the Mr approximately 94,000 glucocorticoid receptor but lack the Mr approximately 90,000 heat shock protein.

Monoclonal antibodies directed against four different polypeptide epitopes on the Mr approximately 94,000 steroid-binding subunit of the rat liver cytosolic glucocorticoid receptor (GcR) were used to probe Western blots of epididymal spermatozoa from rats and mice. Two sperm polypeptides with apparent molecular weights of 94,000 (indistinguishable in size from the liver GcR subunit) and 150,000 reacted with these antibodies. Other polypeptides that are present in a wide variety of somatic cells [lamin-A, -B, and -C; topoisomerase-I; poly(ADP-ribose) polymerase; the 62-kilodalton internal nuclear matrix protein; the nucleolar protein B23; and histone H1] could not be detected in these preparations of spermatozoa, thus appearing to rule out contamination by somatic cells. Rat and mouse pachytene spermatocytes and round spermatids contained much lower amounts of the Mr approximately 94,000 and 150,000 polypeptides. These results suggested that the steroid-binding subunit of the GcR might be accumulated late in spermatogenesis. Consistent with this view, a 6-kilobase mRNA (identical in size to a mRNA detected in mouse somatic cell lines) was detected when Northern blots of mouse round spermatid RNA were probed with a cDNA to the steroid-binding GcR subunit. Although the results described above suggest the presence of GcR in rodent sperm, high affinity binding of glucocorticoids to epididymal sperm could not be detected in a whole cell binding assay. Further analysis revealed that the Mr approximately 90,000 heat shock protein (hsp90), a component reportedly required for high affinity ligand binding to the GcR, was present in early germ cells, but absent from rodent epididymal sperm. These results suggest that the Mr approximately 94,000 steroid-binding subunit of the GcR and an immunologically related Mr approximately 150,000 polypeptide are specifically accumulated during the later stages of rodent spermatogenesis, but are not assembled into receptor complexes capable of binding steroid. In addition, these results support the view that hsp90 is required for high affinity binding of glucocorticoids to the Mr approximately 94,000 GcR subunit in intact cells.     

Decreased and aberrant nuclear lamin expression in gastrointestinal tract neoplasms

BACKGROUND: Altered expression of lamins A/C and B1, constituent proteins of the nuclear lamina, may occur during differentiation and has also been reported in primary lung cancer. AIMS: To examine the expression of these proteins in gastrointestinal neoplasms. PATIENTS: Archival human paraffin wax blocks and frozen tissue from patients undergoing surgical resection or endoscopic biopsy. METHODS: Immunohistochemistry and western blotting using polyclonal antisera against A type lamins and lamin B1. RESULTS: The expression of lamin A/C was reduced and was frequently undetectable by immunohistochemistry in all primary colon carcinomas and adenomas, and in 7/8 primary gastric cancers. Lamin B1 expression was reduced in all colon cancers, 16/18 colonic adenomas, and 6/8 gastric cancers. Aberrant, cytoplasmic labelling with both antibodies occurred in some colonic cancers and around one third of colonic adenomas. Cytoplasmic lamin A/C expression was detected in 3/8 gastric cancers. Lamin expression was reduced in gastric dysplasia, but not intestinal metaplasia, atrophy, or chronic gastritis. Lamin expression was low in carcinomas of oesophagus, prostate, breast, and uterus, but not pancreas. CONCLUSIONS: Reduced expression of nuclear lamins, sometimes together with aberrant, cytoplasmic immunoreactivity is common in gastrointestinal neoplasms. Altered lamin expression may be a biomarker of malignancy in the gastrointestinal tract.     

Meiotic lamin C2: the unique amino-terminal hexapeptide GNAEGR is essential for nuclear envelope association

Meiotic lamin C2 is the only A-type lamin expressed during mammalian spermatogenesis. Typical for this short lamin is the unique hexapeptide GNAEGR, which substitutes the nonhelical amino terminus and part of the alpha-helical rod domain present in somatic lamins. Meiotic lamin C2 also lacks a carboxyl-terminal CaaX box, which is modified by isoprenylation and involved in nuclear envelope (NE) association of somatic isoforms. The mechanism by which lamin C2 becomes localized in the NE is totally unknown. Here we demonstrate that the hexapeptide GNAEGR is essential for this process: (i) Its deletion resulted in a diffuse distribution of lamin C2 within nuclei of transfected COS-7 cells; (ii) Mutated somatic lamin C, containing the sequence GNAEGR at its amino terminus, was located at the NE. The mass spectrometric analysis of the amino terminus of lamin C2 revealed that it is modified by myristoylation. Correspondingly, the substitution of the first glycine residue abolishes the NE association of lamin C2. We conclude that NE association of lamin C2 is achieved by a mechanism different from that of somatic lamins.     

cDNA sequencing of nuclear lamins A and C reveals primary and secondary structural homology to intermediate filament proteins.

The amino acid sequences deduced from cDNA clones of human lamin A and lamin C show identity between these two lamins except for an extra 9.0-kDa carboxyl-terminal tail that is present only in lamin A. Both lamins A and C contain an alpha-helical domain of approximately 360 residues that shows striking homology to a corresponding alpha-helical rod domain that is the structural hallmark of all intermediate filament proteins. However, the lamin alpha-helical domain is 14% larger than that of the intermediate filament proteins. In addition to the extensive homology to intermediate filament proteins as reported [McKeon, F., Kirschner, M. & Caput, D. (1986) Nature (London) 319, 463-468], a different 82-amino acid residue stretch at the carboxyl terminus of lamin A has been deduced and verified by amino acid sequencing. This region contains sequence homology to amino- and carboxylterminal domains of type I and type II epidermal keratins. Implications of the presence of these and other domains in lamins A and C for the assembly of the nuclear lamina are discussed.     

The tail domain of lamin Dm0 binds histones H2A and H2B

In multicellular organisms, the higher order organization of chromatin during interphase and the reassembly of the nuclear envelope during mitosis are thought to involve an interaction between the nuclear lamina and chromatin. The nuclear distribution of lamins and of peripheral chromatin is highly correlated in vivo, and lamins bind specifically to chromatin in vitro. Deletion mutants of Drosophila lamin Dm0 were expressed to map regions of the protein that are required for its binding to chromosomes. The binding activity requires two regions in the lamin Dm0 tail domain. The apparent Kd of binding of the lamin Dm0 tail domain was found to be approximately 1 microM. Chromatin subfractions were examined to search for possible target molecules for the binding of lamin Dm0. Isolated polynucleosomes, nucleosomes, histone octamer, histone H2A/H2B dimer, and histones H2A or H2B displaced the binding of lamin Dm0 tail to chromosomes. This displacement was specific, because polyamines or proteins such as histones H1, H3, or H4 did not displace the binding of the lamin Dm0 tail to chromosomes. In addition, DNA sequences, including M/SARs, did not interfere with the binding of lamin Dm0 tail domain to chromosomes. Taken together, these results suggest that the interaction between the tail domain of lamin Dm0 and histones H2A and H2B may mediate the attachment of the nuclear lamina to chromosomes in vivo.     

Mechanical model of blebbing in nuclear lamin meshworks

Much of the structural stability of the nucleus comes from meshworks of intermediate filament proteins known as lamins forming the inner layer of the nuclear envelope called the nuclear lamina. These lamin meshworks additionally play a role in gene expression. Abnormalities in nuclear shape are associated with a variety of pathologies, including some forms of cancer and Hutchinson–Gilford Progeria Syndrome, and often include protruding structures termed nuclear blebs. These nuclear blebs are thought to be related to pathological gene expression; however, little is known about how and why blebs form. We have developed a minimal continuum elastic model of a lamin meshwork that we use to investigate which aspects of the meshwork could be responsible for bleb formation. Mammalian lamin meshworks consist of two types of lamin proteins, A type and B type, and it has been reported that nuclear blebs are enriched in A-type lamins. Our model treats each lamin type separately and thus, can assign them different properties. Nuclear blebs have been reported to be located in regions where the fibers in the lamin meshwork have a greater separation, and we find that this greater separation of fibers is an essential characteristic for generating nuclear blebs. The model produces structures with comparable morphologies and distributions of lamin types as real pathological nuclei. Thus, preventing this opening of the meshwork could be a route to prevent bleb formation, which could be used as a potential therapy for the pathologies associated with nuclear blebs.     

Lamin B1 is required for mouse development and nuclear integrity

Lamins are key structural components of the nuclear lamina, an intermediate filament meshwork that lies beneath the inner nuclear membrane. Lamins play a role in nuclear architecture, DNA replication, and gene expression. Mutations affecting A-type lamins have been associated with a variety of human diseases, including muscular dystrophy, cardiomyopathy, lipodystrophy, and progeria, but mutations in B-type lamins have never been identified in humans or in experimental animals. To investigate the in vivo function of lamin B1, the major B-type lamin, we generated mice with an insertional mutation in Lmnb1. The mutation resulted in the synthesis of a mutant lamin B1 protein lacking several key functional domains, including a portion of the rod domain, the nuclear localization signal, and the CAAX motif (the carboxyl-terminal signal for farnesylation). Homozygous Lmnb1 mutant mice survived embryonic development but died at birth with defects in lung and bone. Fibroblasts from mutant embryos grew under standard cell-culture conditions but displayed grossly misshapen nuclei, impaired differentiation, increased polyploidy, and premature senescence. Thus, the lamin B1 mutant mice provide evidence for a broad and nonredundant function of lamin B1 in mammalian development. These mutant mice and cell lines derived from them will be useful models for studying the role of the nuclear lamina in various cellular processes.     

Protein kinase activity associated with the nuclear lamina.

A nuclear lamina-enriched fraction from Ehrlich ascites tumor cells contains a tightly bound protein kinase activity, which phosphorylates in vitro the nuclear lamins, a 52-kilodalton protein, and several unknown minor components. The enzyme(s) is thermolabile, independent of Ca2+ and cAMP, and inhibited by quercetin. After treatment with 4 M urea it remains bound to the nuclear lamina in an active state, but it is irreversibly inactivated in 6 M urea. The lamin proteins are phosphorylated on serine residues. Their two-dimensional phosphopeptide maps show multiple phosphorylation sites and a considerable similarity to the phosphopeptide maps of lamins labeled in vivo. Photoaffinity labeling experiments revealed several polypeptide fractions in the nuclear lamina fraction that are candidates for the protein kinase(s).     

Heterotypic and homotypic associations between the nuclear lamins: site-specificity and control by phosphorylation.

Using purified components in affinity chromatography and blot binding assays, we have found that rat liver lamins A, B, and C can associate in homotypic and heterotypic fashions. Heterotypic A-B and C-B complexes are unusually stable and involve the common amino-terminal domain of lamins A and C, but not their helical "rod" domain. A synthetic peptide, comprising the first 32 amino acid residues of lamins A and C, is able to fully compete with the intact molecules for binding to lamin B. Conversely, heterotypic A-C associations and homotypic A-A and C-C interactions appear significantly weaker than A/C-B binding and do not involve the lamin A and C amino-terminal domain. Homotypic B-B complexes are not formed to any considerable extent unless isolated lamin B subunits are "superphosphorylated" in vitro with protein kinase A. However, when lamins A and C are similarly modified, no changes in their binding specificity can be detected. These data suggest that the nuclear lamina, unlike other multicomponent intermediate filaments, constitutes a nonobligatory heteropolymer. They also indicate that cAMP-dependent phosphorylation of interphase lamin B could cause remodeling of the lamina and establishment of homopolymeric domains.     

Abnormal development of the cerebral cortex and cerebellum in the setting of lamin B2 deficiency

Nuclear lamins are components of the nuclear lamina, a structural scaffolding for the cell nucleus. Defects in lamins A and C cause an array of human diseases, including muscular dystrophy, lipodystrophy, and progeria, but no diseases have been linked to the loss of lamins B1 or B2. To explore the functional relevance of lamin B2, we generated lamin B2-deficient mice and found that they have severe brain abnormalities resembling lissencephaly, with abnormal layering of neurons in the cerebral cortex and cerebellum. This neuronal layering abnormality is due to defective neuronal migration, a process that is dependent on the organized movement of the nucleus within the cell. These studies establish an essential function for lamin B2 in neuronal migration and brain development.     

Biogenesis of the nuclear lamina: in vivo synthesis and processing of nuclear protein precursors.

Utilizing antibodies against lamins A, B1, and B2, we have studied the biogenesis of the nuclear lamina in chicken embryo fibroblasts. (Lamins B1 and B2 have been identified recently as structurally distinct "lamin B" proteins.) We demonstrate that, unique among the nuclear proteins studied to date, lamin A is synthesized as a higher molecular mass precursor. A short-lived higher molecular mass variant (t 1/2 approximately equal to 3 min) accompanying the mature-size protein was also detected in the case of lamin B2 biosynthesis, but no precursor was found for lamin B1. By combining pulse-chase experiments with subcellular fractionation, we provide evidence that synthesis of lamin proteins occurs on free polysomes; subsequently, the newly synthesized proteins become rapidly associated with a crude nuclear fraction. The lamin A precursor is processed within the nucleus with a half-time of about 30 min. Concomitantly, lamin proteins acquire a characteristic resistance to detergent extraction, suggesting their insertion into a submembraneous protein network. The described biogenetic pathway involving precursor synthesis and processing is very unusual for nuclear proteins; it may have interesting implications for the mechanisms of transport and assembly of poorly soluble nuclear proteins.     

Methylation patterns of testis-specific genes.

The methylation patterns of genes expressed in the mouse male germ line have been examined. Int-1, Hox-2.1, and Prm-1, all of which contain 5' CpG islands, were found to be completely unmethylated at many sites in these domains, both in somatic tissues and in sperm DNA. Many other testis-specific genes have a similar structure and are probably also constitutively unmethylated. Pgk-2, a non-CpG-island gene, is similar to somatic tissue-specific genes in that it is highly methylated in nonexpressing cell types but undermethylated in pachytene spermatocytes and round spermatids, where it is actively transcribed. At later stages of spermatogenesis, however, the gene becomes remethylated and thus acquires the full modification pattern in sperm DNA. In all these cases, the sperm DNA that emerges from the testis does not contain any germ-line-specific unmethylated sites and thus carries the methylation pattern typical of that in somatic tissues.     

Distinct structural and mechanical properties of the nuclear lamina in Hutchinson-Gilford progeria syndrome

The nuclear lamina is a network of structural filaments, the A and B type lamins, located at the nuclear envelope and throughout the nucleus. Lamin filaments provide the nucleus with mechanical stability and support many basic activities, including gene regulation. Mutations in LMNA, the gene encoding A type lamins, cause numerous human diseases, including the segmental premature aging disease Hutchinson-Gilford progeria syndrome (HGPS). Here we show that structural and mechanical properties of the lamina are altered in HGPS cells. We demonstrate by live-cell imaging and biochemical analysis that lamins A and C become trapped at the nuclear periphery in HGPS patient cells. Using micropipette aspiration, we show that the lamina in HGPS cells has a significantly reduced ability to rearrange under mechanical stress. Based on polarization microscopy results, we suggest that the lamins are disordered in the healthy nuclei, whereas the lamins in HGPS nuclei form orientationally ordered microdomains. The reduced deformability of the HGPS nuclear lamina possibly could be due to the inability of these orientationally ordered microdomains to dissipate mechanical stress. Surprisingly, intact HGPS cells exhibited a degree of resistance to acute mechanical stress similar to that of cells from healthy individuals. Thus, in contrast to the nuclear fragility seen in lmna null cells, the lamina network in HGPS cells has unique mechanical properties that might contribute to disease phenotypes by affecting responses to mechanical force and misregulation of mechanosensitive gene expression.     

Autoimmune response directed against conserved determinants of nuclear envelope proteins in a patient with linear scleroderma.

We have studied the autoantibodies in the serum of a patient with linear scleroderma that specifically recognize the nuclear envelope of cultured cells. These antibodies bind to conserved determinants of nuclear lamins, the predominant mammalian nuclear envelope proteins. Of the three mammalian nuclear lamin proteins (970, P68, and P60), only P70 and P60 bind the autoantibodies. In addition, two proteins of the Drosophila embryonic nuclear matrix, P70 and P68, bind these autoantibodies. We have used nuclear matrices to isolate the autoantibodies from the patient's serum that react to the nuclear lamins. At least three different IgG heavy chains were found to be involved in this autoimmune response to nuclear lamins, indicating that this response is not due to the expansion of a single B-cell clone.     

Keratin-like proteins that coisolate with intermediate filaments of BHK-21 cells are nuclear lamins.

Four proteins of Mr approximately equal to 60,000, 65,000, 67,000, and 70,000 coisolate with the major intermediate filament (IF) structural proteins of BHK-21 cells. These proteins are keratin-like, they form distinctive paracrystals in vitro, and they are concentrated at the nuclear surface. Since these properties indicate similarities with the nuclear lamins, we have prepared conventional fractions of BHK-21 nuclei from which the same type of paracrystal is obtained. Furthermore, biochemical and immunological data demonstrate that the lamins are identical to the Mr 60,000-70,000 proteins found in IF preparations, and both sets of proteins are similar to keratin. These results suggest that an IF-like protein network is present in the nuclear lamina. We speculate that in some unknown way this network connects to the cytoplasmic IF network that courses from the juxtanuclear region to the cell surface. These proposed interconnecting networks may form part of the infrastructure of cytoskeletal-nuclear matrix-connecting links involved in signal transmission between the nuclear and cytoplasmic compartments of eukaryotic cells.     

A progeria mutation reveals functions for lamin A in nuclear assembly,architecture, and chromosome organization

Numerous mutations in the human A-type lamin gene (LMNA) cause the premature aging disease, progeria. Some of these are located in the α-helical central rod domain required for the polymerization of the nuclear lamins into higher order structures. Patient cells with a mutation in this domain, 433G>A (E145K) show severely lobulated nuclei, a separation of the A- and B-type lamins, alterations in pericentric heterochromatin, abnormally clustered centromeres, and mislocalized telomeres. The induction of lobulations and the clustering of centromeres originate during postmitotic nuclear assembly in daughter cells and this early G1 configuration of chromosomes is retained throughout interphase. In vitro analyses of E145K-lamin A show severe defects in the assembly of protofilaments into higher order lamin structures. The results show that this central rod domain mutation affects nuclear architecture in a fashion distinctly different from the changes found in the most common form of progeria caused by the expression of LAΔ50/progerin. The study also emphasizes the importance of lamins in nuclear assembly and chromatin organization.