Irena Hausmanowa-Petrusewicz

Charcot-Marie-Tooth type 4B is caused by mutations in the gene encoding myotubularin-related protein-2.

A gene mutated in Charcot-Marie-Tooth disease type 4B (CMT4B), an autosomal recessive demyelinating neuropathy with myelin outfoldings, has been mapped on chromosome 11q22. Using a positional-cloning strategy, we identified in unrelated CMT4B patients mutations occurring in the gene MTMR2, encoding myotubularin-related protein-2, a dual specificity phosphatase (DSP).

Mutations in the sarcoglycan genes in patients with myopathy.

BACKGROUND Some patients with autosomal recessive limb-girdle muscular dystrophy have mutations in the genes coding for the sarcoglycan proteins (alpha-, beta-, gamma-, and delta-sarcoglycan). To determine the frequency of sarcoglycan-gene mutations and the relation between the clinical features and genotype, we studied several hundred patients with myopathy. METHODS Antibody against alpha-sarcoglycan was used to stain muscle-biopsy specimens from 556 patients with myopathy and normal dystrophin genes (the gene frequently deleted in X-linked muscular dystrophy). Patients whose biopsy specimens showed a deficiency of alpha-sarcoglycan on immunostaining were studied for mutations of the alpha-, beta-, and gamma-sarcoglycan genes with reverse transcription of muscle RNA, analysis involving single-strand conformation polymorphisms, and sequencing. RESULTS Levels of alpha-sarcoglycan were found to be decreased on immunostaining of muscle-biopsy specimens from 54 of the 556 patients (10 percent); in 25 of these patients no alpha-sarcoglycan was detected. Screening for sarcoglycan-gene mutations in 50 of the 54 patients revealed mutations in 29 patients (58 percent): 17 (34 percent) had mutations in the alpha-sarcoglycan gene, 8 (16 percent) in the beta-sarcoglycan gene, and 4 (8 percent) in the gamma-sarcoglycan gene. No mutations were found in 21 patients (42 percent). The prevalence of sarcoglycan-gene mutations was highest among patients with severe (Duchenne-like) muscular dystrophy that began in childhood (18 of 83 patients, or 22 percent); the prevalence among patients with proximal (limb-girdle) muscular dystrophy with a later onset was 6 percent (11 of 180 patients). CONCLUSIONS Defects in the genes coding for the sarcoglycan proteins are limited to patients with Duchenne-like and limb-girdle muscular dystrophy with normal dystrophin and occur in 11 percent of such patients.

The inner nuclear membrane protein Emerin regulates β‐catenin activity by restricting its accumulation in the nucleus

Emerin is a type II inner nuclear membrane (INM) protein of unknown function. Emerin function is likely to be important because, when it is mutated, emerin promotes both skeletal muscle and heart defects. Here we show that one function of Emerin is to regulate the flux of β‐catenin, an important transcription coactivator, into the nucleus. Emerin interacts with β‐catenin through a conserved adenomatous polyposis coli (APC)‐like domain. When GFP‐emerin is expressed in HEK293 cells, β‐catenin is restricted to the cytoplasm and β‐catenin activity is inhibited. In contrast, expression of an emerin mutant, lacking its APC‐like domain (GFP‐emerinΔ), dominantly stimulates β‐catenin activity and increases nuclear accumulation of β‐catenin. Human fibroblasts that are null for emerin have an autostimulatory growth phenotype. This unusual growth phenotype arises through enhanced nuclear accumulation and activity of β‐catenin and can be replicated in wild‐type fibroblasts by transfection with constitutively active β‐catenin. Our results support recent findings that suggest that INM proteins can influence signalling pathways by restricting access of transcription coactivators to the nucleus.

A collaborative study on the natural history of childhood and juvenile onset proximal spinal muscular atrophy (type II and III SMA): 569 patients

We analyzed clinical data of 569 patients in two combined series with childhood and juvenile proximal SMA. This cohort included only patients who had achieved the ability to sit unaided (type II and III SMA). The survival rate among 240 type II patients (who sat but never walked) was 98.5% at 5 years and 68.5% at 25 years. SMA III (n = 329) (those who walked and had symptoms before age 30 years) was subdivided into those with an onset before and after age 3 years (type IIIa, n = 195; SMA IIIb, n = 134). In patients with SMA III, life expectancy is not significantly less than a normal population. The probabilities of being able to walk at 10 years after onset was 70.3%, and at 40 years, 22.0% in SMA IIa. For SMA IIIb, 96.7% were walking 10 years after onset and 58.7% at 40 years. The subdivision of type III SMA was justified by the probability of being ambulatory depending on age at onset; the prognosis differed for those with onset before or after age 3 years. The data provide a reliable basis of the natural history of proximal SMA and support a classification system that is based primarily on age at onset and the achievement of motor milestones.

Dystrophinopathy in isolated cases of myopathy in females

X-linked dystrophinopathy is the most common cause of isolated cases of myopathy in males. To investigate dystrophin abnormalities as a cause of myopathy in girls and women, we used dystrophin immunocytochemistry to study muscle biopsies from 505 girls and women with neuromuscular disease. Forty-six muscle biopsies showed a combination of fibers containing or lacking dystrophin; this mosaic immunostaining pattern denoted a carrier status. Twenty-one of 46 (45.6%) had a family history of Duchenne muscular dystrophy in males. Twenty-five of 46 (54.3%) were isolated cases, with no previous family history of neuromuscular disorder. The laboratory findings of the isolated cases were consistent with the familial cases; all showed myopathic histopathology and abnormal elevations of serum CK. The clinical presentations of the isolated cases varied but were consistent with the familial cases: 40% (10/25) of isolated cases showed proximal limb weakness before age 10, 24% (6/25) presented with myalgias or cramps, 24% (6/25) presented with incidental findings of grossly elevated CK levels, 8% (2/25) noted easy fatigue, and 4% (1/25) had slowly progressive proximal limb weakness beginning at age 45. From our data, the clinical criteria for consideration of an underlying dystrophinopathy in isolated female cases of myopathy are CK levels greater than 1,000 IU/1 and myopathic histopathology. About 10% of the isolated cases of hyperCKemic myopathy (25/210) were proven by dystrophin analysis to have a dystrophinopathy as the cause of their disease (manifesting carriers of Duchenne dystrophy). However, we feel that this may be an underestimate. The correct diagnosis in these patients is imperative for appropriate genetic counseling to the patients and their families.

Clinical, serologic, and immunogenetic features in polish patients with idiopathic inflammatory myopathies

OBJECTIVE To determine the clinical, serologic, and immunogenetic correlations in patients with idiopathic inflammatory myopathies (IIM), and to evaluate the useful grouping of some diseases for practical clinical purposes. METHODS Patients with IIM were categorized according to clinical presentation as compared with autoantibody specificity. Serum samples from 84 patients were screened for myositis-specific autoantibodies (MSAs) by indirect immunofluorescence and double immunodiffusion. All sera were also studied by protein A-assisted immunoprecipitation. Genomic DNA was isolated from peripheral blood mononuclear cells, and HLA-DQA1 and DRB1 alleles were determined. The patients were seen and followed up for many years in the same center. RESULTS MSAs were present in 19% of patients. The most common MSAs were antisynthetases in 13% of patients (Jo-1 10.7%, PL-12 1.2%, and EJ 1.2%), associated with the antisynthetase syndrome. Anti-SRP was found in 1.2% of patients, associated with polymyositis, and anti-Mi-2 in 4.9%, found exclusively in patients with dermatomyositis. The most frequent MSA was PM-Scl in 23.8% of patients, associated with scleromyositis, and Ku was present in 9.6% of patients with overlap syndromes. The alleles that were found at a significantly increased frequency were HLA-DRB1*0301 (59.4%) and DQA1*0501 (71.6%), which are in linkage disequilibrium. DQA1*0501 was present in 85.7% of patients with antisynthetases, and in 100% of patients with PM-Scl and Ku. CONCLUSION The HLA-DRB1*0301; DQA1*0501 haplotype was found to be significantly increased in this population overall and in those myositis patients with antisynthetase, anti-PM-Scl, and anti-Ku antibodies. The results of this study confirm that IIM are heterogeneous syndromes, but can be divided into more useful groups on the basis of clinical, serologic, and immunogenetic features.

Ultrastructural abnormality of sarcolemmal nuclei in Emery-Dreifuss muscular dystrophy (EDMD).

We performed ultrastructural studies on nuclear abnormalities in biopsied muscles from seven patients with EDMD, of three non-related families, and two sporadic cases. The diagnosis was based on clinical data and molecular findings. We detected different degrees of abnormalities in the sarcolemmal nuclei ranging from marked condensation of chromatin to complete damage of nuclear components. Other nuclei in the same muscle cell very often appeared normal. The extrusion of nuclear chromatin into sarcoplasm as a consequence of nuclear membrane disintegration was observed in numerous nuclei. All these nuclear changes are considered to be cytological indicators of nuclear dysfunction evoked by emerin deficiency.

Architectural abnormalities in muscle nuclei. Ultrastructural differences between X-linked and autosomal dominant forms of EDMD

OBJECTIVES The aim of our study was to compare the ultrastructure of myonuclei in both forms of Emery-Dreifuss dystrophy (EDMD)-X-linked and dominantly autosomally transmitted. The muscle biopsies were taken from rectus femoris in four X-linked EDMD cases and three ADEDMD cases. METHODS The biopsies were evaluated using immunocytochemical staining to establish emerin or A/C lamins deficiency. The muscle ultrastructure, especially that of nuclei, was analysed to find out whether there are differences between the two forms of EDMD. RESULTS In both forms of EDMD, there was an aberrant nuclear architecture. In the X-linked form, the breakdown of fragile nuclear membrane and presence of nucleoplasm extrusion were a distinct feature. In the AD from, there was chromatin reorganization and loss of nucleoplasm volume.

Localization of the gene for X‐linked spinal muscular atrophy

We used probes for DNA polymorphisms on the X chromosome to study genetic linkage in seven families with X-linked adult-onset spinal muscular atrophy. We found significant linkage to the marker DXYS1 on the proximal X chromosome long arm and loose linkage or nonlinkage to markers elsewhere. Our analysis localizes the gene defect for this form of anterior horn cell disease.

108th ENMC International Workshop, 3rd Workshop of the MYO-CLUSTER project: EUROMEN, 7th International Emery-Dreifuss Muscular Dystrophy (EDMD) Workshop, 13-15 September 2002, Naarden, The Netherlands.

Inserm UR582 (ex 523), Institut de Myologie, Bâtiment Babinski, G.H. Pitie-Salpetriere, 47, boulevard de l’Hopital, 75 651 Paris Cedex 13, France Laboratoire de Genetique Moleculaire et Chromosomique, IURC, Montpellier, France Institute of Cardiology, University of Bologna, Bologna, Italy Department of Paediatrics and Neonatal Medicine, Imperial College School of Medicine, Hammersmith Campus, London, UK Department of Neurology, Academic Medical Centre, Amsterdam, The Netherlands Service de Cardiologie, GH Cochin, Paris, France Randall Center, Kings College, London, UK Neuromuscular Unit, M.R.C. Polish Academy of Sciences, Warsaw, Poland ITOI, Unit of Bologna, c/o IOR, Bologna, Italy Istituto Ortopedico Rizzoli, Neuromuscular Unit, Bologna, Italy MRIC, North East Wales Institute, Wrexham, UK Department of Internal Medicine and Cardiology Medical University of Warsaw, Warsaw, Poland Department of Cardiology, University Hospital Maastricht, Maastricht, The Netherlands Dipartimento di Biopatologia e Diagnostica per Immagini, Rome, Italy Istituto di Genetica Biochimica ed Evoluzionistica, CNR (IGBE-CNR), Pavia, Italy Division of Medical Genetics, University of Leicester, Leicester, UK Institute of Human Genetics, Greifswald, Germany