Gabrielle Åhlberg

Intragenic deletion of TRIM32 in compound heterozygotes with sarcotubular myopathy/LGMD2H

In 2005 the commonality of sarcotubular myopathy (STM) and limb girdle muscular dystrophy type 2H (LGMD2H) was demonstrated, as both are caused by the p D487N missense mutation in TRIM32 originally found in the Manitoba Hutterite population. Recently, three novel homozygous TRIM32 mutations have been described in LGMD patients. Here we describe a three generation Swedish family clinically presenting with limb girdle muscular weakness and histological features of a microvacuolar myopathy. The two index patients were compound heterozygotes for a frameshift mutation in TRIM32 (c.1560delC ) and a 30 kb intragenic deletion, encompassing parts of intron 1 and the entire exon 2 of TRIM32. In these patients, no full‐length or truncated TRIM32 could be detected. Interestingly, heterozygous family members carrying only one mutation showed mild clinical symptoms and vacuolar changes in muscle. In our family, the phenotype encompasses additionally a mild demyelinating polyneuropathic syndrome. Thus STM and LGMD2H are the result of loss of function mutations that can be either deletions or missense mutations.

Welander distal myopathy – an overview

Welander distal myopathy has an autosomal dominant inheritance and a late onset. The onset of symptoms is in the hands and gradually distal muscles of the lower extremities are involved. The most-affected muscles are the long extensors of the hands and feet. CK-values are normal or slightly elevated. There is never any cardiac involvement in Welander distal myopathy. Neurophysiological findings are of both myopathic and neuropathic character. Histopathological findings in muscle biopsies are mainly of myopathic type and include rimmed vacuoles which correspond to autophagic vacuoles on the ultrastructural level. Tubulo-filamentous inclusions with a diameter of 16-21 nm, i.e. of the same type as found in patients with Inclusion Body Myositis, are found in the sarcoplasm and in myofibre nuclei. A neurogenic component in Welander distal myopathy has been suggested, on the grounds of a sensory dysfunction, neuropathic findings on neurophysiology and muscle biopsy and a decrease of A-delta nerve fibres on sural nerve biopsy. Genetic analysis has excluded linkage to other defined distal myopathies and hereditary Inclusion Body Myopathy loci.

Distribution of muscle degeneration in Welander distal myopathy—A magnetic resonance imaging and muscle biopsy study

Seven patients with Welander distal myopathy were subjected to magnetic resonance imaging (MRI) of the lower extremity, and muscle biopsies of the tibialis anterior, soleus and vastus lateralis muscles. MRI revealed abnormalities in both the anterior and posterior compartments of the lower leg in three of the patients, and in only the posterior compartment in the rest of the patients. No MRI abnormalities were found in either the proximal muscles of the leg or in the peroneal or posterior tibial muscle groups. Affected muscles had T1- and T2-values indicating a replacement of muscle fibres with fat tissue. Muscle biopsies showed pathological changes varying from slight to severe in tibialis anterior and soleus muscles in all patients. No muscle fibre abnormalities were seen in the vastus lateralis muscle in any of the patients. In accordance with earlier reports from patients with Welander distal myopathy, there was muscle degeneration of tibialis anterior muscles corresponding to the weakness of dorsal extension of the feet, but also degeneration in the muscles of the posterior compartment. The patients did not, however, show any clinical signs of weakness related to posterior muscle groups. There is no evidence of involvement of proximal muscles of the leg clinically, with MRI or in muscle biopsies.

Welander distal myopathy is not linked to other defined distal myopathy gene loci

Welander distal myopathy is an autosomal dominant disorder with late onset that affects extensor muscles of the hands and the feet. The disorder is considered as the most prevalent of the distal myopathies and is almost only seen in Sweden and in some parts of Finland. On clinical, morphological and genetical grounds the disorder is clearly separated from other distal myopathies. We have performed linkage analysis with the MLINK program in a total of six families with microsatellite markers dispersed throughout the genome and report exclusion for the localisation of the gene of 64% of the human genome. These studies have clearly separated Welander distal myopathy from previously mapped forms of distal myopathy such as the Miyoshi myopathy by excluding linkage to chromosome 2. The region on 14q that has been suggested to house the gene of the distal myopathy described by Laing et al. (Am J Hum Genet 1995;56:422-7), has as well been excluded by several markers.

Welander distal myopathy outside the Swedish population: phenotype and genotype

Welander distal myopathy is a late onset disorder that is mainly seen in Sweden. It is linked to chromosome 2p13 and all Swedish patients show a common shared haplotype, indicating a founder mutation. Here we report the clinical manifestations, magnetic resonance imaging, pathophysiology and haplotype analysis of Welander patients in the Finnish population. The clinical examination of patients from 12 different families showed a distal myopathy with onset in the long extensor muscles of the hands and fingers, also seen in Swedish Welander patients. Muscle biopsies showed characteristic myopathic changes. Haplotype analysis with the five polymorphic markers that make up the common core haplotype, seen in the Swedish patients, revealed that this haplotype is also co-segregating in the Finnish patients and a common ancestry is therefore further supported for patients with Welander distal myopathy.

Welander hereditary distal myopathy, a molecular genetic comparison to hereditary myopathies with inclusion bodies

Welander distal myopathy (WDM) is an autosomal dominant disorder with late onset predominantly affecting distal extensor muscles of the hands and the feet. The disorder is considered as the most common of the distal myopathies but is almost only seen in Sweden and some parts of Finland. The finding of rimmed vacuoles in muscle biopsies from patients with moderate and severe symptoms constitutes one similarity with hereditary inclusion body myopathy (HIBM) sparing the quadriceps as described by Argov and Yarom [Argov Z, Yarom R. J Neurol Sci 1984;64:33-43]. The question has been raised whether some of the different forms of distal myopathy might be allelic. In previous reports the gene defects for HIBM and autosomal recessive hereditary distal myopathy with rimmed vacuoles (DMRV) have been mapped to chromosome 9pl-q1. The Finnish tibial muscular dystrophy (TMD) that displays similar histopathological findings has recently been linked to chromosome 2q. We have investigated the regions of interest with dispersed microsatellite markers in four well-described pedigrees, and this study now excludes the regions on chromosome 9pl-q1 and 2q from linkage to WDM both by haplotype analysis and linkage analysis with the MLINK program. WDM, showing morphological similarities with HIBM, is clearly separated from the disorders mapped to chromosomes 9 and 2 on clinical and genetical grounds.

Muscle fibre degeneration in distal myopathy (Welander)—Ultrastructure related to immunohistochemical observations on cytoskeletal proteins and Leu-19 antigen

In seven patients with long-standing and six patients with early symptoms of Welander distal myopathy (WDM), monoclonal antibodies directed against such cytoskeletal proteins as dystrophin, spectrin and desmin and against Leu-19, a myoblast and satellite cell related antigen, were applied to muscle biopsies from the anterior tibial and soleus muscles. In addition, ultrastructural studies were carried out on biopsies from the soleus muscle. In muscle fibres from patients with early symptoms there was normal immunostaining for dystrophin, spectrin, desmin and Leu-19. In the patients with long-standing symptoms, there was also a normal expression of dystrophin, and a normal staining for spectrin and desmin was found in normal sized muscle fibres. Occasionally normal sized muscle fibres showed staining for Leu-19. Increased staining for spectrin and desmin and a strong Leu-19 staining was seen in normal sized muscle fibres with rimmed vacuoles and in atrophic fibres. Increased staining for spectrin, desmin and Leu-19 has been described in denervated muscle fibres and, thus, the present findings may support earlier findings of a neurogenic component in Welander distal myopathy. In the soleus muscle, ultrastructural muscle fibre abnormalities conformed to those in the anterior tibial muscle. Many rimmed vacuoles were observed which corresponded, at the ultrastructural level, to autophagic vacuoles. Intranuclear and cytoplasmic filamentous inclusions of the same shape and diameter as in inclusion body myositis were observed.

C4342T-mutation in the SCN4A gene on chromosome 17q in a Swedish family with paramyotonia congenita (Eulenburg) – correlations with clinical, neurophysiological and muscle biopsy data

Genetic analysis of the adult muscle sodium channel alpha-subunit, SCN4A gene on chromosome 17q, was performed by means of PCR technique in a Swedish family with paramyotonia congenita (Eulenburg) (PMC). The mutation was found in four family members and consisted of a C to T transition affecting the fourth domain of the sodium channel protein. This mutation has earlier been described in other families with paramyotonia congenita. All family members carrying the mutation had cold-induced paradoxical myotonia, myotonic bursts on EMG, and a type IIB atrophy on muscle biopsy. Three of them had slight CK elevation and two had episodes of paralysis. On the basis of clinical findings in this family, persistent proximal muscle weakness, myopathic EMG abnormalities, a type IIB atrophy on muscle biopsy and no symptoms but other signs of muscle affection, were earlier suggested as clinical features of PMC. However, genetic analysis revealed that family members with these symptoms and findings did not have the mutation, indicating that these features are not due to PMC.