Skip Navigation

This Article
Right arrow Abstract Freely available
Right arrow FREE Full Text (PDF) Freely available
Right arrow Alert me when this article is cited
Right arrow Alert me if a correction is posted
Services
Right arrow Email this article to a friend
Right arrow Similar articles in this journal
Right arrow Similar articles in ISI Web of Science
Right arrow Similar articles in PubMed
Right arrow Alert me to new issues of the journal
Right arrow Add to My Personal Archive
Right arrow Download to citation manager
Right arrow Search for citing articles in:
ISI Web of Science (75)
Right arrowRequest Permissions
Google Scholar
Right arrow Articles by Cartegni, L.
Right arrow Articles by Toniolo, D.
Right arrow Search for Related Content
PubMed
Right arrow PubMed Citation
Right arrow Articles by Cartegni, L.
Right arrow Articles by Toniolo, D.
Social Bookmarking
Add to CiteULike   Add to Connotea   Add to Del.icio.us  
What's this?

Human Molecular Genetics Pages 2257-2264

Heart-specific localization of emerin: new insights into Emery-Dreifuss muscular dystrophy
Introduction
Results
   Emerin is a phosphorylated protein
   The C-terminal hydrophobic domain of emerin is the determinant for nuclear membrane localization
   Emerin is localized to the inner nuclear membrane
   Nuclear localization is insufficient for emerin function
   Subcellular distribution of emerin
   An alternative localization of emerin in heart
Discussion
Materials And Methods
   Cell and tissue fractionation
   Production of antisera
   Immunocytochemistry and Western blots
   Constructs and transfections
Acknowledgements
References

Heart-specific localization of emerin: new insights into Emery-Dreifuss muscular dystrophy

Heart-specific localization of emerin: new insights into Emery-Dreifuss muscular dystrophy Luca Cartegni1, Marina Raffaele di Barletta1, Rita Barresi2, Stefano Squarzoni3, Patrizia Sabatelli3, Nadir Maraldi3,4, Marina Mora2, Claudia Di Blasi2, Ferdinando Cornelio2, Luciano Merlini4, Antonello Villa5, Fabio Cobianchi1 and Daniela Toniolo1,*

1Institute of Genetics, Biochemistry and Evolution CNR, Via Abbiategrasso 207, 27100 Pavia, Italy, 2Besta Neurological Institute, Milano, Italy, 3Institute of Cytomorphology NP-CNR, Bologna, Italy, 4Istituti Ortopedici Rizzoli, Bologna, Italy and 5DIBIT-HSR, Milano, Italy

Received July 17, 1997; Revised and Accepted September 5, 1997

Emery-Dreifuss muscular dystrophy (EDMD) is an X-linked inherited disease characterized by early contracture of the elbows, Achilles tendons and post-cervical muscles, slow progressive muscle wasting and weakness and cardiomyopathy presenting with arrhythmia and atrial paralysis: heart block can eventually lead to sudden death. The EDMD gene encodes a novel ubiquitous protein, emerin, which decorates the nuclear rim of many cell types. Amino acid sequence homology and cellular localization suggested that emerin is a member of the nuclear lamina-associated protein family. These findings did not explain the role of emerin nor account for the skeletal muscle- and heart-specific clinical manifestations associated with the disorder. Now we report that emerin localizes to the inner nuclear membrane, via its hydrophobic C-terminal domain, but that in heart and cultured cardiomyocytes it is also associated with the intercalated discs. We propose a general role for emerin in membrane anchorage to the cytoskeleton. In the nuclear envelope emerin plays a ubiquitous and dispensable role in association of the nuclear membrane with the lamina. In heart its specific localization to desmosomes and fasciae adherentes could account for the characteristic conduction defects described in patients.

INTRODUCTION

Emery-Dreifuss muscular dystrophy (EDMD) is an X-linked muscular disease first described in the early 1960s and characterized by early contracture of the elbows, Achilles tendons and post-cervical muscles and slow progressive muscle wasting and weakness, with humeroperoneal distribution in the early stages of the disease, and cardiomyopathy usually presenting as a heart block (1 ). The cardiomyopathy manifests as a cardiac conduction defect and the associated heart block is a frequent cause of death. Provided that diagnosis is made sufficiently early, the insertion of a cardiac pacemaker can be life saving. In no case has mental retardation, intellectual defect or involvement of other organs been described.

The EDMD gene was identified among a large number of candidates in a very gene rich region where the disease had been mapped (2 ). The EDMD gene is ubiquitously expressed and encodes a novel ubiquitous protein of 254 amino acids, emerin, localized at the nuclear rim of most cell types analyzed (2 -5 ). Emerin showed limited sequence similarity with LAP2, a ubiquitous integral membrane protein involved in association between the nuclear lamina and nuclear envelope (6 ). The similarities between the two proteins suggested that emerin is a member of the nuclear lamina-associated protein family (6 ). This finding was quite unique, as most muscle or cardiac disorders are caused by alterations in molecules specifically or highly expressed in muscle tissues.

We have further investigated emerin localization and we have conclusively established that emerin is indeed an integral membrane protein of the inner nuclear membrane. In this paper we report that emerin is, however, not exclusively localized at the nuclear membrane but that it is also found associated with cytoplasmic membranes. In heart its specific localization to desmosomes and fasciae adherentes of the intercalated discs could account for the characteristic conduction defects described in patients.

RESULTS

Emerin is a phosphorylated protein

From the sequence analysis emerin appeared to possess multiple phosphorylation sites for a range of kinases (2 ). In vivo labeling of HeLa cells with [32P]orthophosphate confirmed that emerin is phosphorylated in vivo (Fig. 1 a). The antibodies immunoprecipitated two phosphorylated bands of 34 and 36 kDa of the same size as those commonly seen in Western blots. Treatment of HeLa cells with the phosphatase inhibitor okadaic acid (7 ) caused a relative increase in the 36 kDa form over the more abundant 34 kDa form and demonstrated that the two forms correspond to different levels of phosphorylation of emerin (Fig. 1 b).


Figure 1. (a) Immunoprecipitation of emerin from metabolically 32P-labeled HeLa cells (18) was performed using anti-emerin antibodies (D7) or pre-immune serum (C). Phosphorylated emerin was visualized by autoradiography following separation by 10% SDS-PAGE. (b) Western blot analysis of emerin in mock-treated cells (-OA) or cells harvested after 90 min exposure to 1 µM okadaic acid (+OA). (c) Schematic representation of the emerin deletion mutants and their localization in COS cells (Loc). A schematic representation of emerin is shown at the top. The black box represents the hydrophobic domain, gray boxes represent serine-rich regions and open slashed boxes represent LAP homologies. Constructs contained the HA epitope (rightward slashed box) or GFP (oval) fused to the indicated portions of emerin. N.E., nuclear envelope; N, nucleus; N/C, nucleus and cytoplasm. Experiments depicted in (d) are underlined. (d) Immunohistochemical localization of some of the fusion proteins. The HA fusions (HA-wt and HA-[Delta]Trans) were analyzed by indirect immunofluorescence on methanol-fixed cells with anti-HA antibodies. GFP fusions (GFP and GFP-Trans) were analyzed by direct fluorescence as recommended by the manufacturer. (e) Section through a human skeletal muscle. The gold granules are specifically localized along the inner nuclear membrane, corresponding to the nuclear lamina. The outer nuclear membrane (arrow) is not as well labeled as the nucleoplasm (N) or the myofilaments (M). ×75000. (f) Section through a human cardiomyocyte nucleus. The gold granules are mostly localized along the inner nuclear membrane. The cutting plane is sometimes not perpendicular to the nuclear envelope in correspondence with the nuclear indentation. This causes an apparent shift of the gold granule images with respect to the nuclear envelope image. The gold granules, however, follow the external borders of the peripheral heterochromatin, strongly suggesting an association with the nuclear lamina (arrowheads). Few gold granules are visible over the cytoplasm. ×46000.

The C-terminal hydrophobic domain of emerin is the determinant for nuclear membrane localization

Emerin is a small hydrophilic protein with a hydrophobic tail of 21 amino acids, 11 residues from the C-terminus. To establish whether the C-terminal hydrophobic domain of emerin was important for nuclear rim localization, mutants were constructed carrying different short deletions spanning the entire protein and an HA epitope tag at the N-terminus (Fig. 1 c). Upon transfection into COS cells the wild-type protein localized to the nuclear envelope (Fig. 1 d), as did proteins lacking the conserved region at the N-terminus (2 ) or with any of the internal deletions. Only the mutant lacking the last 27 amino acids spanning the C-terminal putative transmembrane domain (HA-[Delta]Trans) was unable to localize to the nuclear envelope and was concentrated inside the nuclei (Fig. 1 d). To confirm that the hydrophobic domain is essential for membrane localization, the transmembrane domain was fused to the C-terminus of the reporter protein GFP (GFP-Trans). The 27 C-terminal amino acids were sufficient to drive most of the transfected chimeric protein to the nuclear periphery (Fig. 1 d).

Emerin is localized to the inner nuclear membrane

Electron microscopy immunogold studies of ultrathin frozen sections of skeletal muscle, heart and HeLa cells showed that emerin is associated with the inner nuclear membrane. In skeletal muscle sections most gold granules localized to the nuclear lamina or the inner nuclear membrane (Fig. 1 ) at positions where the two membranes are well separated by enlargements of the intramembrane cisterna. Similar results were obtained in heart (Fig. 1 f) and HeLa cells (not shown).

Nuclear localization is insufficient for emerin function

Emerin appears to be an integral membrane protein localized in the inner nuclear membrane and the main determinant of this localization resides in the C-terminal hydrophobic stretch, which can be considered a genuine transmembrane domain. A nuclear localization is, however, insufficient to ensure a normal phenotype and the stability and/or the specificity of emerin binding to other proteins must involve determinants in the rest of the protein. This is demonstrated by the behavior of a mutated emerin found in one patient (LB1520) presenting a frameshift mutation in the C-terminal moiety (2 ). In this patient a shorter protein was predicted, deleted of the emerin sequence starting from amino acid 169 but possessing a new hydrophobic tail compatible in amino acid composition and length with a nuclear envelope transmembrane domain (8 ; Fig. 2 a). Such a shorter emerin was indeed synthesized (5 ) and immunohistochemical analysis of a muscle biopsy of the patient demonstrated that a reduced but still detectable amount of emerin was at the nuclear rim (Fig. 2 b).


Figure 2. (a) The predicted hydrophobicity plots (23) of normal emerin (wt) and of protein synthesized by patient LB1520 are shown above the sequence of the last 31 amino acids. The hydrophobic stretches are underlined. Shading identifies the novel C-terminal domain in the patient. (b) Indirect immunofluorescence analysis of emerin expression in muscle cryosections of a normal individual (top) and of patient LB1520 (bottom).

Subcellular distribution of emerin

As previously shown by Manilal et al. (4 ), in brain tissue emerin was not exclusively found in the nuclear envelope. Cell fractionation of several cell types by mechanical shearing in hypotonic buffer separated emerin into nuclear and cytoplasmic `pools'. In HeLa cells (Fig. 3 a) the nuclear emerin (lane 2) was found in the lamina-associated fraction, resistant to nuclease digestion, high salt and detergent (lane 10). The cytoplasmic emerin (lane 3) co-localized with membranes (lane 4) but, unlike that in the nuclear fraction, it was readily solubilized in the presence of detergents (lines 5 and 6). Correct fractionation of lamins in nuclei and vimentin in cytoplasm excluded major cross-contamination between the fractions. The relative abundance of emerin in the cytoplasmic membrane-associated fraction varied slightly in different cell types: fibroblasts, myoblasts, HepG2 and neuroblastoma cells were analyzed and examples are shown in Figure 3 b. No great differences were found in myoblasts compared with myotubes (not shown) and between human, rat and simian cells, though a smaller amount of cytoplasmic emerin was usually found in myoblasts, especially from rat.


Figure 3.Western blot analysisof emerinin cell fractions. (a) Subcellular fractionation of HeLa cells. Fractions were prepared as described in Materials and Methods and probed with anti-emerin, anti-vimentin, anti-lamin B and anti-lamin A/C antibodies. Lane 1, total extract; lane 2, nuclei; lane 3, cytoplasm; lane 4, high speed cytoplasmic pellet; lane 5, 1% Triton X-100 cytoplasmic pellet wash; lane 6, detergent-resistant cytoplasmic pellet; lane 7, high speed cytoplasmic supernatant. Nuclei were treated as described in Materials and Methods to obtain: lane 8, nucleoplasm; lane 9, 1% Triton X-100 wash; lane 10, nuclear lamina-associated proteins. (b) Fractionation of the cells indicated probed with anti-emerin antibodies. Fractions were prepared as above, except that steps 5 and 6 were omitted. Cells are human and rat fibroblasts (hF and rF), myoblasts (hM and rM) and COS cells. (c) Fractionation of human heart samples with anti-emerin (upper panel) and anti-cadherin (lower panel) antibodies. Equivalents of 25 mg initial sample (see Materials and Methods) were loaded for each fraction. Lane 1, low speed supernatant; lane 2, low speed pellet; lane 3, high speed centrifugation supernatant; lane 4, high speed centrifugation cytoplasmic insoluble fraction; lane 5, purified nuclei; lane 6, 1 M NaCl wash; lane 7, 1% Triton X-100 wash; lane 8, nuclear lamina-associated proteins.

Similar results were obtained by fractionation of human heart tissue, using a slightly different protocol to separate nuclear and cellular membranes (Fig. 3 c) from soluble proteins. The cytoplasmic emerin was found with the cadherins, in cytoplasmic membranes (Fig. 3 c, lane 4).

An alternative localization of emerin in heart

Immunohistochemical analysis of cells and tissues did not show any significant association of emerin with specific cytoplasmic structures. The only notable exception was the heart. In unfixed cryosections of human heart the antibodies also decorated heart intercalated discs (Fig. 4 a). Three different antisera, two raised against the human (5 ) and one against the mouse protein, gave identical results in human, mouse and rat heart. Identical results were obtained with the antisera and with affinity-purified antibodies. No reaction was observed with preimmune serum and all labeling was titrated away when excess recombinant antigen was added to the incubation (not shown). Serial 6 µm thick sections of an entire adult mouse heart demonstrated that emerin stained nuclei and intercalated discs throughout the organ (not shown).


Figure 4. Emerin localization in heart. (a) Indirect immunofluorescence analysis of 6 µm thick human heart cryosections, double stained with antibodies to the indicated proteins. Emerin gives signals on the nuclear rim (arrowhead) and on intercalated discs (arrow). Lamin B stains nuclei; vinculin stains intercalated discs and sarcolemmal membranes; cadherin stains intercalated discs. (b) Emerin localization in cultured fetal rat cardiomyocytes, methanol-fixed 72 h after plating and analyzed by confocal microscopy using a BioRad MRC-1024 confocal microscope equipped with a Kr/Ar laser. Emerin is shown in green, cadherin and vinculin in red. The two images were superimposed to show co-localization (yellow) at the intercalated discs (emerin + cadherin and emerin + vinculin) and at focal adhesions (emerin + vinculin). Arrows indicate the intercalated discs; arrowheads indicate fibroblasts; emerin exclusively stains the nuclei and vinculin the focal adhesions. Focal adhesions are positive to emerin only in cardiomyocytes. The lower panel shows a detail of the intercalated disc between two/three cardiomyocytes.

Primary cultures of cardiomyocytes prepared from 21 d.p.c. rat fetuses (9 ) were also studied. After 2-3 days in culture adjacent cardiomyocytes formed intercalated discs: in such culture conditions we could confirm emerin localization at the nuclear rim of cardiomyocytes and fibroblasts and on newly formed intercalated discs (Fig. 4 b). Confocal analysis of the cultures double stained with anti-emerin and anti-cadherin or anti-vinculin antibodies demonstrated a third site of emerin localization at the base of the cardiomyocytes. The striking similarity between emerin and vinculin distribution, although only in part superimposable, indicated that both mark focal adhesions (10 ,11 ). Vinculin, however, also marked focal adhesions of flanking fibroblasts, whilst emerin in focal adhesions was specific for cultured cardiomyocytes.

Finally, electron microscopic immunogold cytochemistry of ultrathin frozen sections of human heart confirmed that emerin is part of the adhesive junctions of the heart. The gold granules were localized around desmosomes and fasciae adherentes (Fig. 5 a and b), at the periphery of the dense fibrillar material. The regions between adhesion structures (Fig. 5 c) and gap junctions (not shown) were not labeled.


Figure 5.Electron microscopic immunogold cytochemistry of heart intercalated discs. (a) Desmosome.×66 000. (b) Desmosome. ×41 000. (c) Portion of an intercalated disc at low magnification. ×30 000. Gold granules are mainly localized around the dense area of the junctional complexes.

DISCUSSION

The data presented in this paper confirm the suggestion that emerin, the product of the X-linked EDMD gene is a ubiquitous highly phosphorylated integral membrane protein of the nuclear envelope, tightly associated with the nuclear lamina. As predicted, emerin is indeed phosphorylated in vivo and the different phosphorylated forms may play important roles in interactions with the nuclear membrane and other nuclear proteins, during the cell cycle or in different cell types (12 ,13 ). Our data showed that the main determinant for inner nuclear membrane targeting is the C-terminal hydrophobic domain, which can be considered a genuine transmembrane domain. In the absence of the C-terminal domain in transfected COS cells most of the protein was localized in the nucleus, suggesting that a nuclear localization signal exists in the remaining portion of the protein. In vivo synthesis of a mutated emerin having a new C-terminal hydrophobic domain with an amino acid composition compatible with nuclear membrane insertion was sufficient for nuclear envelope localization.

In many cell types and tissues subcellular fractionation experiments demonstrated that a relevant fraction of emerin is also associated with cytoplasmic membranes. The finding of this fraction in tissues (see Results; 4 ) as well as in dividing cells indicates that it may not merely represent newly synthesized emerin on its way to the nuclear membrane and suggests different and possibly specific roles for emerin. In heart the cytoplasmic membrane-associated fraction appears to be part of the highly specialized heart adhesive junctions, desmosomes and fasciae adherentes of the intercalated discs. The evidence came primarily from immunohistochemical analysis using three different affinity-purified antibodies. Two were previously described (5 ), raised against a human protein lacking the C-terminal domain (amino acids 1-168). The third was raised in rabbits against a similar protein (amino acids 1-168) deduced from a mouse emerin cDNA sequence presenting 75% amino acid identity to the human sequence (Cartegni et al., in preparation). In Western blots the three antibodies reacted almost exclusively with emerin and did not show heart-specific bands. This result was confirmed by electron microscopic analysis of heart sections, by immunohistochemistry of cardiomyocyte cultures and subcellular fractionation experiments. Moreover, confocal analysis of cardiomyocyte cultures demonstrated that cardiac emerin and not emerin from fibroblasts could be recruited to newly formed focal adhesions, strongly indicating that emerin is part of a heart-specific adhesion complex. Nagano et al. (3 ) had previously shown that one of their polyclonal antibodies raised against a synthetic peptide (ED1, amino acids 173-188) showed positive immunostaining of the surface membrane of control skeletal and cardiac muscle. The staining in this case was very likely non-specific, as EDMD patients with a null mutation still had a positive immunoreaction at the cell surface. We did not have samples from patient hearts to study, but we never observed staining of the sarcolemma or of the cardiac cell outer membrane with our antibodies, which specifically stained only intercalated discs. The two reagents are, however, also very different, as both the antibodies raised by Nagano et al. were against C-terminal peptide sequences not contained in our antigen and may not recognize the same epitope(s).

Desmosomes and fasciae adherentes anchor desmin-containing intermediate filaments and the bundles of sarcomeric myofilaments respectively (10 ). They consist of transmembrane adhesive glycoproteins, members of the cadherin superfamily, and of cytoplasmic proteins such as vinculin, catenins and actin binding proteins (10 ). Different assortments of the same or similar proteins in desmosomes, fasciae adherentes, focal adhesions and other adhesive junctions seem to confer specific functions to ensure cell-cell communication and tight adhesion between cells and to the extracellular matrix. The role of this complex assortment of proteins is best demonstrated by the existence of many genetic diseases that perturb adhesion and in heart by the dramatic consequences of plakoglobin ([gamma]-catenin) knock out (14 ): plakoglobin -/- mice die at mid-gestation due to rupture of the ventricles.

The cardiac conduction defect in EDMD patients is the most severe and life threatening clinical manifestation of the disease. Cardiac alterations have also been described in female carriers (1 ) in the absence of any skeletal muscle abnormality, suggesting a prominent role in cardiac conduction for emerin. Localization of emerin in heart adhesive junctions suggests that lack of emerin in heart may have a direct effect on cardiac conduction abnormalities. We propose that lack or a decreased amount of emerin in heart alters cardiomyocyte adhesion and/or communication between adjacent cells and is responsible for arrhythmia and slow pacing and eventually heart block. Whether this is due to a general failure in cardiac conduction or to a more specific effect at the level of the heart pacemaker cannot be established with the present knowledge of the disease. On the other hand, in favor of our general model is the notion that emerin, with myotonic dystrophy kinase (15 ), is the second protein localized to the intercalated discs and responsible for a genetic disorder presenting a severe heart conduction defect.

Our results suggest that emerin may associate directly with membranes through its hydrophobic tail and we expect that it may do the same at the intercalated discs. Its cytoplasmic hydrophilic portion should interact with protein(s) of the adhesive junctions. In the emerin sequence a serine-rich stretch of 12 amino acids (PVSASR-SSL-DLS), 42 amino acids from the transmembrane domain, presented striking similarity to the consensus sequence (PV/ICFSRXSSLSS/DLS) of the 20 amino acid repeats of the adenomatous polyposis coli (APC) tumor suppressor gene (16 ), involved in binding [beta]-catenin. It also showed significant though lower similarity to the minimal [beta]-catenin binding region of the cadherins (17 ). Thus emerin in heart may also bind [beta]-catenin or a novel protein presenting similar sequence. It is noteworthy that this part of the protein is deleted in patient LB1520, who still retains some emerin capable of correct localization.

We have no evidence yet of a specific emerin localization in skeletal muscle that may account for the muscular dystrophy of EDMD patients. The finding of emerin in cytoplasmic membranes suggests a general and novel role for emerin in membrane attachment to the cytoskeleton and this could actually represent the most relevant function of this protein in both skeletal muscle and heart.

MATERIALS AND METHODS

Cell and tissue fractionation

Cells were fractionated essentially as described by Manilal et al. (4 ) in the presence of protease inhibitors. After low speed centrifugation purified nuclei were digested with nucleases (18 ) and extracted with 1 M NaCl to obtain nucleoplasm. The pellet was washed with 1% Triton X-100 to separate detergent wash and insoluble lamina-associated proteins. The cytoplasmic fraction was centrifuged at 100 000 g to obtain soluble and insoluble fractions. The pellet was solubilized with 1 M NaCl and a 1% Triton X-100 wash to obtain extractable and non-extractable fractions.

Heart tissue was processed as described by Kuehl et al. (19 ) with minor modifications. A crude homogenate of 500 mg human heart in 25 mM Tris-HCl, pH 7.1, 2.5 mM MgCl2, 0.25 M sucrose, 0.6% (w/v) Triton X-100 and protease inhibitors was centrifuged at low speed. The cellular pellet was resuspended in 25 mM Tris-HCl, pH 7.1, 2.5 mM MgCl2, 2.3 M sucrose and protease inhibitors and centrifuged for 75 min at 82 000 g through a 2.3 M sucrose cushion to separate the soluble cytoplasmic fraction, an insoluble fraction which accumulated at the interface and a pellet containing purified nuclei. These were treated as above to obtain the nuclear lamina-associated fraction.

Production of antisera

The anti-human emerin antisera have been described previously (5 ). Rabbit polyclonal antisera were raised against a bacterial fusion protein expressing a fragment of mouse recombinant emerin corresponding to amino acids 1-168. The mouse sequence was deduced from a mouse cDNA obtained in the laboratory (Cartegni et al., in preparation) and the PCR amplification product was cloned in vector pGEX 2T and controlled by sequencing as described for the human cDNA. Specific antibodies were isolated from the sera by affinity purification using antigen immobilized on nitrocellulose filters (20 ).

Immunocytochemistry and Western blots

Indirect immunofluorescence and Western blots were performed as described previously (5 ), with the anti-emerin antibodies used at 1:100 or 1:1000 dilutions respectively. The 12CA5 mouse anti-HA mAb (Boehringer), the anti-vimentin, anti-vinculin and anti-cadherin (CH-19) mAb (Sigma, St Louis, MO) and the mouse anti-lamin A/C mAb (Ylem, Avezzano, Italy) were used as indicated by the suppliers.

Electron microscopy analysis was performed as described previously (21 ) on normal skeletal muscle samples obtained from a non-dystrophic patient during surgical treatment of osteosarcoma or heart samples taken from routine control biopsies on a heart transplant patient. The tissue fragments were fixed with 0.001% glutaraldehyde, 2% paraformaldehyde in 0.1 M NaPO4 buffer, pH 7.2, for 1 h at 4°C, cryoprotected in 2.3 M sucrose overnight at 4°C, frozen in liquid nitrogen and sectioned with a Reichert FC4 cryosectioning unit at -95°C (21 ). The anti-emerin antibodies were used diluted 1:50. Cryosectioning was the only method among several tested that allowed emerin immunostaining.

Constructs and transfections

Emerin deletion mutants were prepared by PCR, inserted in-frame in a vector containing the HA epitope, sequenced and cloned in pMT2 (22 ). Alternatively, PCR-amplified fragments of emerin were cloned in vector pEGFP-C1 (Clontech). COS cells were transiently transfected by the standard CaPO4 method and analyzed 24 h after transfection.

ACKNOWLEDGEMENTS

We thank R.Sitia and P.C.Marchisio for many suggestions and discussions, S.Schiaffino and S.Ausoni for help with the cardiomyocyte cultures, G.Camerino, S.Bione, P.D'Adamo and C.Manzini for advice and critical reading of the manuscript and M.Gatti for technical assistance. This work was supported by grants from Telethon Italy to D.T. and F.C.

REFERENCES

1 Emery,A.E.H. (1989) Emery-Dreifuss syndrome. J. Med. Genet., 26, 637-641.

2 Bione,S., Maestrini,E., Rivella,S., Mancini,M., Regis,S., Romeo,G. and Toniolo,D. (1994) Identification of a novel X-linked gene responsible for Emery-Dreifuss muscular dystrophy. Nature Genet., 8, 323-327. MEDLINE Abstract

3 Nagano,A., Koga,R., Ogawa,M., Kurano,Y., Kawada,J., Okada,R., Hayashi,Y.K., Tsukahara,T. and Arahata,K. (1996) Emerin deficiency at the nuclear membrane in patients with Emery-Dreifuss muscular dystrophy. Nature Genet., 12, 254-259. MEDLINE Abstract

4 Manilal,S., Nguyen thi Man, Sewry,C.A. and Morris,G.E. (1996) The Emery-Dreifuss muscular dystrophy protein, emerin, is a nuclear membrane protein. Hum. Mol. Genet., 6, 801-808.

5 Mora,M., Cartegni,L., Di Blasi,C., Barresi,R., Bione,S., Raffaele di Barletta,M., Morandi,L., Merlini,L., Nigro,V., Politano,L., Donati,M.A., Cornelio,F., Cobianchi,F. and Toniolo,D. (1997) X-linked Emery Dreifuss muscular dystrophy can be diagnosed from skin biopsy or blood sample. Annls Neurol., 42, 249-253.

6 Furukawa,K., Panté,N., Aebi,U. and Gerace,L. (1995) Cloning of a cDNA for lamina-associated polypeptide 2 (LAP2) and identification of regions that specify targeting to the nuclear envelope. EMBO J., 14, 1626-1636. MEDLINE Abstract

7 Hardie,D.G., Haystead,T.A.J. and Sim,A.T.R. (1991) Use of okadaic acid to inhibit protein phosphatases in intact cells. Methods Enzymol., 201, 469-476. MEDLINE Abstract

8 Pelham,H.R.B. and Munro,S. (1993) Sorting of membrane protein in the secretory pathway. Cell, 75, 603-605. MEDLINE Abstract

9 Ausoni,S., Campione,M., Picard,A., Moretti,P., Vitadello,M., De Nardi,C. and Schiaffino,S. (1994) Structure and regulation of mouse cardiac troponin I gene. J. Biol. Chem., 269, 339-346. MEDLINE Abstract

10 Gumbiner,B.M. (1996) Cell adhesion: the molecular basis of tissue architecture and morphogenesis. Cell, 84, 345-357. MEDLINE Abstract

11 Adams,J.C. (1997) Cell adhesion-spreading frontiers, intricate insights. Trends Cell Biol., 7, 107-110.

12 Marshall,I.C.B. and Wilson,K.L. (1997) Nuclear envelope assembly after mitosis. Trends Cell Biol., 7, 69-74.

13 Foisner,R. and Gerace,L. (1993) Integral membrane proteins of the nuclear envelope interact with lamins and chromosomes and binding is modulated by mitotic phosphorylation. Cell, 73, 1267-1279. MEDLINE Abstract

14 Ruiz,P., Brinkmann,V., Ledermann,B., Behrend,M., Grund,C., Thalhammer,C., Vogel,F., Birchmeier,C., Gunthert,U., Franke,W.W. and Birchmeier,W. (1996) Targeted mutation of plakoglobin in mice reveals essential functions of desmosomes in the embryonic heart. J. Cell Biol., 135, 215-225. MEDLINE Abstract

15 Maeda,M., Taft,C.S., Bush,E.W., Holder,E., Bailey,W., Neville,H., Perryman,M.B. and Bies,R.D. (1995) Identification, tissue-specific expression and subcellular localization of the 80- and 71-kDa forms of myotonic dystrophy kinase protein. J. Biol. Chem., 270, 20246-20249. MEDLINE Abstract

16 Groden,J., Thliveris,A., Samowitz,W., Carlson,M., Gelbert,L., Albertsen,H., Joslyn,G., Stevens,J., Spirio,L., Robertson,M., Sargeant,L., Krapcho,K., Wollf,E., Burt,R., Hughes,J.P., Warrington,J., McPherson,J., Wasmuth,J., LePaslier,D., Abderrahim,H., Cohen,D., Leppert,M. and White,R. (1991) Identification and characterization of the familial adenomatous polyposis coli gene. Cell, 66, 589-600. MEDLINE Abstract

17 Pai,L.M., Kirkpatrick,C., Blanton,J., Oda,H., Takeichi,M. and Peifer,M. (1996) Drosophila a-catenin and E-cadherin bind to distinct regions of Drosophila armadillo. J. Biol. Chem., 271, 32411-32420. MEDLINE Abstract

18 Cobianchi,F., Calvio,C., Stoppini,M., Buvoli,M. and Riva,S. (1993) Phosphorylation of human hnRNP protein A1 abrogates in vitro strand annealing activity. Nucleic Acids Res., 21, 949-955. MEDLINE Abstract

19 Kuehl,L. (1977) Isolation of skeletal muscle nuclei. Methods Cell. Biol., 15, 79-88. MEDLINE Abstract

20 Sambrook,J., Fritsch,E.F. and Maniatis,T. (1989) Molecular Cloning: A Laboratory Manual, 2nd Edn. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY.

21 Squarzoni,S., Sabatelli,P., Maltarello,M.C., Cataldi,A., Di Primio,R. and Maraldi,N.M. (1992) Localization of dystrophin COOH-terminal domain by the fracture label technique. J. Cell Biol., 118, 1401-1409. MEDLINE Abstract

22 Kaufman,R.J., Wasley,L.C., Spiliotes,A.J., Gossels,S.D., Latt,S.A., Larsen,G.R. and Kay,R.M. (1985) Co-amplification and co-expression of human tissue-type plasminogen activator and murine dihydrofolate reductase sequences in Chinese hamster ovary cells. Mol. Cell. Biol., 5, 1750-1759. MEDLINE Abstract

23 Kite,J. and Doolittle,R.F. (1982) A simple method for displaying the hydropathic character of a protein. J. Mol. Biol., 157, 105-132.

*To whom correspondence should be addressed. Tel: +39 382 546340; Fax: +39 382 422286; Email: toniolo@ipvgbe.igbe.pv.cnr.it

This page is maintained by OUP admin. Last updated Sat Oct 18 13:29:50 BST 1997. Part of the OUP Journals World Wide Web service.
Copyright Oxford University Press, 1997


Add to CiteULike CiteULike   Add to Connotea Connotea   Add to Del.icio.us Del.icio.us    What's this?


This article has been cited by other articles:


Home page
 Hum Mol GenetHome page
A. Muchir, P. Pavlidis, G. Bonne, Y. K. Hayashi, and H. J. Worman
Activation of MAPK in hearts of EMD null mice: similarities between mouse models of X-linked and autosomal dominant Emery Dreifuss muscular dystrophy
Hum. Mol. Genet., August 1, 2007; 16(15): 1884 - 1895.
[Abstract] [Full Text] [PDF]

Home page
 CirculationHome page
K. Sakata, M. Shimizu, H. Ino, M. Yamaguchi, H. Terai, N. Fujino, K. Hayashi, T. Kaneda, M. Inoue, Y. Oda, et al.
High Incidence of Sudden Cardiac Death With Conduction Disturbances and Atrial Cardiomyopathy Caused by a Nonsense Mutation in the STA Gene
Circulation, June 28, 2005; 111(25): 3352 - 3358.
[Abstract] [Full Text] [PDF]

Home page
 J. Cell Sci.Home page
Q. Zhang, J. N. Skepper, F. Yang, J. D. Davies, L. Hegyi, R. G. Roberts, P. L. Weissberg, J. A. Ellis, and C. M. Shanahan
Nesprins: a novel family of spectrin-repeat-containing proteins that localize to the nuclear membrane in multiple tissues
J. Cell Sci., March 14, 2002; 114(24): 4485 - 4498.
[Abstract] [Full Text] [PDF]

Home page
 J. Cell Sci.Home page
O. A. Vaughan, M. Alvarez-Reyes, J. M. Bridger, J. L. V. Broers, F. C. S. Ramaekers, M. Wehnert, G. E. Morris, W. G. F. Whitfield, and C. J. Hutchison
Both emerin and lamin C depend on lamin A for localization at the nuclear envelope
J. Cell Sci., March 9, 2002; 114(14): 2577 - 2590.
[Abstract] [Full Text] [PDF]

Home page
 J. Cell Sci.Home page
E. A. L. Fairley, A. Riddell, J. A. Ellis, and J. Kendrick-Jones
The cell cycle dependent mislocalisation of emerin may contribute to the Emery-Dreifuss muscular dystrophy phenotype
J. Cell Sci., January 15, 2002; 115(2): 341 - 354.
[Abstract] [Full Text] [PDF]

Home page
 J. Cell Sci.Home page
W. Wu, F. Lin, and H. J. Worman
Intracellular trafficking of MAN1, an integral protein of the nuclear envelope inner membrane
J. Cell Sci., January 4, 2002; 115(7): 1361 - 1371.
[Abstract] [Full Text] [PDF]

Home page
 Eur Heart JHome page
A. Gavazzi, A. Repetto, L. Scelsi, C. Inserra, M.L. Laudisa, C. Campana, C. Specchia, B. Dal Bello, M. Diegoli, L. Tavazzi, et al.
Evidence-based diagnosis of familial non-X-linked dilated cardiomyopathy. Prevalence, inheritance and characteristics
Eur. Heart J., January 1, 2001; 22(1): 73 - 81.
[Abstract] [PDF]

Home page
 Eur Heart JHome page
E. Arbustini, P. Morbini, A. Pilotto, A. Gavazzi, and L. Tavazzi
Familial dilated cardiomyopathy: from clinical presentation to molecular genetics
Eur. Heart J., November 2, 2000; 21(22): 1825 - 1832.
[PDF]

Home page
 Hum Mol GenetHome page
D. B. Davis, A. J. Delmonte, C. T. Ly, and E. M. McNally
Myoferlin, a candidate gene and potential modifier of muscular dystrophy
Hum. Mol. Genet., January 22, 2000; 9(2): 217 - 226.
[Abstract] [Full Text] [PDF]

Home page
 HeartHome page
A E Buckley, J Dean, and I R Mahy
Cardiac involvement in Emery Dreifuss muscular dystrophy: a case series
Heart, July 1, 1999; 82(1): 105 - 108.
[Abstract] [Full Text] [PDF]

Home page
 J. Histochem. Cytochem.Home page
I. Mussini, D. Biral, O. Marin, S. Furlan, and S. Salvatori
Myotonic Dystrophy Protein Kinase Expressed in Rat Cardiac Muscle Is Associated with Sarcoplasmic Reticulum and Gap Junctions
J. Histochem. Cytochem., March 1, 1999; 47(3): 383 - 392.
[Abstract] [Full Text]

Home page
 J. Cell Sci.Home page
E. Fairley, J Kendrick-Jones, and J. Ellis
The Emery-Dreifuss muscular dystrophy phenotype arises from aberrant targeting and binding of emerin at the inner nuclear membrane
J. Cell Sci., January 8, 1999; 112(15): 2571 - 2582.
[Abstract] [PDF]

Home page
 J. Cell Sci.Home page
C Ostlund, J Ellenberg, E Hallberg, J Lippincott-Schwartz, and H. Worman
Intracellular trafficking of emerin, the Emery-Dreifuss muscular dystrophy protein
J. Cell Sci., January 6, 1999; 112(11): 1709 - 1719.
[Abstract] [PDF]

Home page
 BMJHome page
A. E H Emery
Fortnightly review: The muscular dystrophies
BMJ, October 10, 1998; 317(7164): 991 - 995.
[Full Text]

Home page
 J. Cell Sci.Home page
J. Ellis, M Craxton, J. Yates, and J Kendrick-Jones
Aberrant intracellular targeting and cell cycle-dependent phosphorylation of emerin contribute to the Emery-Dreifuss muscular dystrophy phenotype
J. Cell Sci., January 3, 1998; 111(6): 781 - 792.
[Abstract] [PDF]

This Article
Right arrow Abstract Freely available
Right arrow FREE Full Text (PDF) Freely available
Right arrow Alert me when this article is cited
Right arrow Alert me if a correction is posted
Services
Right arrow Email this article to a friend
Right arrow Similar articles in this journal
Right arrow Similar articles in ISI Web of Science
Right arrow Similar articles in PubMed
Right arrow Alert me to new issues of the journal
Right arrow Add to My Personal Archive
Right arrow Download to citation manager
Right arrow Search for citing articles in:
ISI Web of Science (75)
Right arrowRequest Permissions
Google Scholar
Right arrow Articles by Cartegni, L.
Right arrow Articles by Toniolo, D.
Right arrow Search for Related Content
PubMed
Right arrow PubMed Citation
Right arrow Articles by Cartegni, L.
Right arrow Articles by Toniolo, D.
Social Bookmarking
Add to CiteULike   Add to Connotea   Add to Del.icio.us  
What's this?