Altered TDP-43-dependent splicing in HSPB8-related distal hereditary motor neuropathy and myofibrillar myopathy.

BACKGROUND AND PURPOSE: Mutations in the small heat-shock protein 22 gene (HSPB8) have been associated with Charcot-Marie-Tooth disease type 2L, distal hereditary motor neuropathy (dHMN) type IIa and, more recently, distal myopathy/myofibrillar myopathy (MFM) with protein aggregates and TDP-43 inclusions. The aim was to report a novel family with HSPB8K141E -related dHMN/MFM and to investigate, in a patient muscle biopsy, whether the presence of protein aggregates was paralleled by altered TDP-43 function. METHODS: We reviewed clinical and genetic data. We assessed TDP-43 expression by qPCR and alternative splicing of four previously validated direct TDP-43 target exons in four genes by reverse transcriptase-polymerase chain reaction. RESULTS: The triplets and their mother presented in the second to third decade of life with progressive weakness affecting distal and proximal lower limb and truncal muscles. Nerve conduction study showed a motor axonal neuropathy. The clinical features, moderately raised creatin kinase levels, selective pattern of muscle involvement on magnetic resonance imaging and pathological changes on muscle biopsy, including the presence of protein aggregates, supported the diagnosis of a contemporary primary muscle involvement. In affected muscle tissue we observed a consistent alteration of TDP-43-dependent splicing in three out of four TDP-43-target transcripts (POLDIP3, FNIP1 and BRD8), as well as a significant decrease of TDP-43 mRNA levels. CONCLUSIONS: Our study confirmed the role of mutated HSPB8 as a cause of a combined neuromuscular disorder encompassing dHMN and MFM with protein aggregates. We identified impaired RNA metabolism, secondary to TDP-43 loss of function, as a possible pathological mechanism of HSPB8K141E toxicity, leading to muscle and nerve degeneration.

Emerin deficiency at the nuclear membrane in patients with Emery-Dreifuss muscular dystrophy.

Mutations in the STA gene at the Xq28 locus have been found in patients with X-linked Emery-Dreifuss muscular dystrophy (EDMD). This gene encodes a hitherto unknown protein named 'emerin'. To elucidate the subcellular localization of emerin, we raised two antisera against synthetic peptide fragments predicted from emerin cDNA. Using both antisera, we found positive nuclear membrane staining in skeletal, cardiac and smooth muscles in the normal controls and in patients with neuromuscular diseases other than EDMD. In contrast, a deficiency in immunofluorescent staining of skeletal and cardiac muscle from EDMD patients was observed. A 34 kD protein is immunoreactive with the antisera--the protein is equivalent to that predicted for emerin. Together, our findings suggest the specific deficiency of emerin in the nuclear membrane of muscle cells in patients with EDMD.

Mutations in the integrin alpha7 gene cause congenital myopathy.

The basal lamina of muscle fibers plays a crucial role in the development and function of skeletal muscle. An important laminin receptor in muscle is integrin alpha7beta1D. Integrin beta1 is expressed throughout the body, while integrin alpha7 is more muscle-specific. To address the role of integrin alpha7 in human muscle disease, we determined alpha7 protein expression in muscle biopsies from 117 patients with unclassified congenital myopathy and congenital muscular dystrophy by immunocytochemistry. We found three unrelated patients with integrin alpha7 deficiency and normal laminin alpha2 chain expression. To determine if any of these three patients had mutations of the integrin alpha7 gene, ITGA7, we cloned and sequenced the full-length human ITGA7 cDNA, and screened the patients for mutations. One patient had splice mutations on both alleles; one causing a 21-bp insertion in the conserved cysteine-rich region, and the other causing a 98-bp deletion. A second patient was a compound heterozygote for the same 98-bp deletion, and had a 1-bp frame-shift deletion on the other allele. A third showed marked deficiency of ITGA7 mRNA. Clinically, these patients showed congenital myopathy with delayed motor milestones. Our results demonstrate that mutations in ITGA7 are involved in a form of congenital myopathy.

Characterization of the Asian myopathy patients with VCP mutations.

BACKGROUND AND PURPOSE: Mutations in the valosin-containing protein (VCP) gene are known to cause inclusion body myopathy with Paget's disease of bone and frontotemporal dementia (IBMPFD) and familial amyotrophic lateral sclerosis (ALS). Despite an increasing number of clinical reports, only one Asian family with IBMPFD has been described. METHODS: To characterize patients with VCP mutations, we screened a total of 152 unrelated Asian families who were suspected to have rimmed vacuolar myopathy. RESULTS: We identified VCP mutations in seven patients from six unrelated Asian families. Five different missense mutations were found, including a novel p.Ala439Pro substitution. All patients had adult-onset progressive muscle wasting with variable involvement of axial, proximal, and distal muscles. Two of seven patients were suggested to have mild brain involvement including cerebellar ataxia, and only one showed radiological findings indicating a change in bone. Findings from skeletal muscle indicated mixed neurogenic and myogenic changes, fibers with rimmed vacuoles, and the presence of cytoplasmic and nuclear inclusions. These inclusions were immunopositive for VCP, ubiquitin, transactivation response DNA-binding protein 43, and also histone deacetylase 6 (HDAC6), of which function is regulated by VCP. Evidence of early nuclear and mitochondrial damage was also characteristic. CONCLUSIONS: Valosin-containing protein mutations are not rare in Asian patients, and gene analysis should be considered for patients with adult-onset rimmed vacuolar myopathy with neurogenic changes. A wide variety of central and peripheral nervous system symptoms coupled with rare bone abnormalities may complicate diagnosis.

Emerinopathy and laminopathy clinical, pathological and molecular features of muscular dystrophy with nuclear envelopathy in Japan.

Mutations in the genes for nuclear envelope proteins of emerin (EMD) and lamin A/C (LMNA) are known to cause Emery-Dreifuss muscular dystrophy (EDMD) and limb girdle muscular dystrophy (LGMD). We compared clinical features of the muscular dystrophy patients associated with mutations in EMD (emerinopathy) and LMNA (laminopathy) in our series. The incidence of laminopathy was slightly higher than that of emerinopathy. The age at onset of the disease in emerinopathy was variable and significantly older than in laminopathy. The initial symptom of emerinopathy was also variable, whereas nearly all laminopathy patients presented initially with muscle weakness. Calf hypertrophy was often seen in laminopathy, underscoring the importance of mutation screening for LMNA in childhood muscular dystrophy with calf hypertrophy. The clinical spectrum of emerinopathy is actually wider than previously known including EDMD, LGMD, conduction defects with minimal muscle/joint involvement, and their intermittent forms. Pathologically, no marked difference was observed between emerinopathy and laminopathy. Increased number and variation in size of myonuclei were detected. More precise observations using electron microscopy is warranted to characterize the detailed nuclear changes in nuclear envelopathy.

X-linked form of Emery-Dreifuss muscular dystrophy.

Emery-Dreifuss muscular dystrophy (EDMD) is an inherited muscular disorder clinically characterized by slowly progressive weakness affecting humero-peroneal muscles, early joint contractures and cardiomyopathy with conduction defects. Autosomal dominant and recessive forms are caused by mutations in lamin A/C gene. Lamin A/C is a major component of nuclear lamina, and its gene mutations cause several human disorders including muscular dystrophy, cardiomyopathy, lipodystrophy, neuropathy, and progeria syndrome. X-linked recessive form of EDMD is caused by mutation in EMD (or STA) gene encoding an integral protein of the inner nuclear membrane. Emerin expresses ubiquitously, but its deficiency affects only limited tissues of skeletal and cardiac muscles and joints. In this paper, I will focus on clinical and pathological aspects of X-EDMD and possible functions of emerin.

Molecular pathomechanism of distal myopathy with rimmed vacuoles.

Distal myopathy with rimmed vacuoles (DMRV) and hereditary inclusion body myopathy (HIBM) are now known to be the same disease and are caused by mutations in tile GNE gene that encodes a bifunctional protein with two enzymatic activities: UDP-GlcNAc2-epimerase (GNE) and ManNAc kinase (MNK). GNE catalyzes the rate-limiting step in the sialic acid biosynthesis and MNK catalyzes the next step. So far, we have found homozygous or compound heterozygous mutations in 55 unrelated Japanese DMRV patients. Among them, c.1714G>C (p.V572L) mutation is the most common, accounting for 57% of the mutant alleles. The same mutation was recently identified also in Korean DMRV patients, raising the possibility of the presence of a common founder. We have also found that cardiac involvement is not very rare and is found in 18% of patients, albeit degree of severity widely varies; in some patients, it can result in sudden death. The length of time when patients become non ambulatory is diverse. The severity of clinical symptoms also varies widely, as evidenced by the presence of an asymptomatic homozygote harboring of p.D176V, the second most common mutation among Japanese patients. Patients' fibroblasts and myotubes are hyposialylated and this hyposialylation can be recovered by adding GNE metabolite, ManNAc, or sialic acid per se, NeuAc. Accordingly, the sialylation status in the skeletal muscle tissue is also greatly altered especially in fibers with rimmed vacuoles, suggesting the tight association between hyposialylation and the formation of rimmed vacuoles. However, we still do not know why hyposialylation leads to the formation of rimmed vacuoles. To further elucidate the pathomechanism and to develop a therapy of DMRV, we need to produce mouse model mouse for this disease.

Dysferlin is a surface membrane-associated protein that is absent in Miyoshi myopathy.

Recently we reported that mutations in a muscle protein "dysferlin" are present in limb girdle muscular dystrophy-2B and a related, adult-onset, distal dystrophy known as Miyoshi myopathy (MM). We report that antibodies to dysferlin identify a protein of approximately 230 kDa and show that dysferlin is located in the muscle membrane. This protein is absent in MM and LGMD-2B muscle. By contrast, dystrophin and other dystrophin-associated proteins are normal in these patients. Thus, dysferlin is a membrane-associated protein that is not likely to be an integral component of the dystrophin complex. Although it is not essential for initial myogenesis, it appears to be critical for sustained normal function in mature muscle.

Selective deficiency of alpha-dystroglycan in Fukuyama-type congenital muscular dystrophy.

BACKGROUND: Fukuyama-type congenital muscular dystrophy (FCMD) is an autosomal recessive disorder characterized by severe dystrophic muscle wasting from birth or early infancy with structural brain abnormalities. The gene for FCMD is located on chromosome 9q31, and encodes a novel protein named fukutin. The function of fukutin is not known yet, but is suggested to be an enzyme that modifies the cell-surface glycoprotein or glycolipids. OBJECTIVE: To elucidate the roles of fukutin gene mutation in skeletal and cardiac muscles and brain. METHODS: Immunohistochemical and immunoblot analyses were performed in skeletal and cardiac muscles and brain tissue samples from patients with FCMD and control subjects. RESULTS: The authors found a selective deficiency of highly glycosylated alpha-dystroglycan, but not beta-dystroglycan, on the surface membrane of skeletal and cardiac muscle fibers in patients with FCMD. Immunoblot analyses also showed no immunoreactive band for alpha-dystroglycan, but were positive for beta-dystroglycan in FCMD in skeletal and cardiac muscles. CONCLUSION: The current findings suggest a critical role for fukutin gene mutation in the loss or modification of glycosylation of the extracellular peripheral membrane protein, alpha-dystroglycan, which may cause a crucial disruption of the transmembranous molecular linkage of muscle fibers in patients with FCMD.

The frequency of patients with 50-kd dystrophin-associated glycoprotein (50DAG or adhalin) deficiency in a muscular dystrophy patient population in Japan: immunocytochemical analysis of 50DAG, 43DAG, dystrophin, and utrophin.

The 50-kd dystrophin-associated glycoprotein (50DAG or adhalin) in the skeletal muscle has been shown to be deficient in patients with severe childhood autosomal recessive muscular dystrophy prevalent in North Africa. To elucidate the frequency of patients having the 50DAG deficiency in a muscular dystrophy population in Japan, we immunocytochemically examined 50DAG, 43DAG, dystrophin, and utrophin. A total of 243 patients with muscular dystrophy, among 1,035 diagnostic muscle biopsies during the past 2.5 years, were analyzed. We identified five unrelated patients (three females and two males who have no family history) with 50DAG deficiency in the sarcolemma. Thus, 2.1% (5/243) of our muscular dystrophy patient population had 50DAG deficiency.

Tongue atrophy in facioscapulohumeral muscular dystrophy.

Involvement of the lingual muscle is considered one of the exclusion criteria of facioscapulohumeral muscular dystrophy (FSHD). In a series of 151 Japanese patients with 4q35-FSHD, seven patients (4.6%) had tongue atrophy with abnormal MRI findings and typical myogenic patterns of electromyography. All seven patients belong to a group of early-onset FSHD with large gene deletions on chromosome 4q35. Our result suggests that the patients with 4q35-FSHD could have myopathic tongue atrophy.

Mutation in the caveolin-3 gene causes a peculiar form of distal myopathy.

The authors describe a patient with sporadic distal myopathy associated with reduced caveolin-3 in muscle fibers in which the muscle atrophy was restricted to the small muscles of the hands and feet. Gene analysis disclosed a heterozygous 80 G-->A substitution in the caveolin-3 gene that was identical to that of reported cases of elevated serum creatine kinase. This patient further demonstrated possible clinical heterogeneity of myopathies with mutations in the caveolin-3 gene.

Electron microscopic examination of basal lamina in Fukuyama congenital muscular dystrophy.

By light microscopy we previously obtained immunocytochemical evidence for basal lamina (BL) abnormality of skeletal muscle in Fukuyama congenital muscular dystrophy (FCMD). To further elucidate the pathological involvement of the BL in FCMD, we examined by electron microscopy the skeletal muscle in 12 cases of FCMD, nine cases of age-matched neuromuscular diseases unrelated to FCMD, and a case of merosin-negative CMD (MCMD). We found that the BL of skeletal muscle fibres in all patients with FCMD and the MCMD patient had a thin, deranged and often disrupted appearance. These features were more prominent in large calibre (> 15 microns) fibres than in small calibre (approximately 8 microns) fibres. Replication of the BL was not observed in 11 of the 12 FCMD patients. Although the BL over the intact plasma membrane had occasional gaps, the plasma membrane under the disrupted BL was normal in some case. Our results indicate the presence of fragile BL which may precede plasma membrane damage in FCMD skeletal muscle.

Beyond LGMD1A: myotilin is a component of central core lesions and nemaline rods.

Myotilin is a Z-disc protein that binds alpha-actinin, gamma-filamin and F-actin. The essential role of myotilin in skeletal muscle is highlighted by the recent observation that autosomal dominant limb girdle muscular dystrophy type 1A is caused by mutations in the human myotilin gene. We studied the expression and subcellular distribution of myotilin in nemaline myopathy, central core disease, centronuclear myopathy, and myopathies with tubular aggregates. A prominent myotilin immunostaining of nemaline rods and core lesions was detected in all ten cases of nemaline myopathy and five cases of central core disease. This renders myotilin a sensitive, though non-specific marker for these structural lesions. Western blot analysis did not indicate an increased myotilin expression in nemaline myopathy muscle. However, the analysis indicated upregulation of a 75 kDa immunoreactive band, very weak in control muscle but previously detected in limb girdle muscular dystrophy 1A samples. Our findings indicate that myotilin is a core structural molecule in nemaline rods and central core lesions and suggest modification of myotilin in nemaline myopathy, and further support the notion that myotilin may have a key role in the dynamic molecular events mediating myofibril assembly in normal and diseased human skeletal muscle.

Massive muscle cell degeneration in the early stage of merosin-deficient congenital muscular dystrophy.

Primary merosin-deficient congenital muscular dystrophy (CMD) is a severe form of congenital muscular disorder which is caused by mutations in the laminin alpha2 chain gene (LAMA2). The disease is characterized by marked dystrophic changes in skeletal muscles during early infancy, while little is known about the pathological process of the muscle fiber degeneration. Here, we report the immunohistochemical analysis of skeletal muscle in ten patients with primary merosin-deficient CMD using a panel of molecular markers for skeletal muscle proteins, cellular necrosis, and apoptosis. In the youngest patient (a 52 day old baby), prominent massive muscle cell degeneration occurred in association with the deposition of the C5-9 complement membrane attack complex (MAC). Most of the MAC-positive muscle fibers showed a severely deranged immunoreaction to dystrophin, dystroglycans, and other sarcolemmal proteins. In addition, we found scattered positive signals for apoptosis. Similar but milder changes were also observed in six other patients younger than 1 year. In the patients older than 3 years, muscle fibers positive for MAC and apoptotic signals were barely detectable. These findings imply that massive muscle fiber degeneration occurs in the very early stage of merosin-deficient CMD and may contribute to the severe dystrophic changes in muscle from early infancy.

Abnormal localization of laminin subunits in muscular dystrophies.

To address potential involvement of muscle basal lamina and membrane cytoskeleton proteins in the etiology of non-dystrophinopathy muscular dystrophies, we examined the immunostaining intensity and distribution of laminin subunits (A, B1, B2 and M), type IV collagen, dystrophin and spectrin in skeletal muscle biopsies from 64 myopathic patients (17 Fukuyama congenital muscular dystrophy: FCMD, 13 congenital muscular dystrophy unrelated to FCMD: other CMD, 16 Duchenne muscular dystrophy: DMD, and 18 other neuromuscular diseases. In FCMD muscle, we found a significant reduction of laminin M (merosin; a striated muscle specific basal lamina-associated protein) with approximately 26% of levels seen in controls by quantitative immunofluorescence. Other CMD and DMD muscles showed less dramatic reductions (78%, 80%, respectively). The localization of laminin M was also abnormal in FCMD muscle. Laminin B1 and B2 showed abnormalities similar to those observed with laminin M, but were less marked. Laminin A was only detected in rare regenerating fibers in control biopsies, whereas it was seen around most muscle fibers in FCMD patients, and in dystrophin deficient muscle fibers from DMD patients and its carrier. Staining intensity of type IV collagen in FCMD muscle was not significantly different from the other diseases. These findings may implicate a primary or central role for the basal lamina in FCMD muscle.

A carrier of Duchenne muscular dystrophy with dilated cardiomyopathy but no skeletal muscle symptom.

A 29-year-old female developed dilated cardiomyopathy at 20 years of age but with no muscle symptoms. Her 2-year-old son with Duchenne muscular dystrophy (DMD)_had no demonstrable deletion in the dystrophin gene, but all fibers except for 5% 'revertant' fibers in a muscle biopsy specimen had no dystrophin. Both skeletal and cardiac muscle biopsy specimens from the mother showed a mosaic distribution of dystrophin-positive and -negative fibers, and so she was diagnosed as being a manifesting carrier of DMD. We conclude that, when one encounters a female patient with idiopathic cardiomyopathy with a high serum creatine kinase level, the suspicion of her being a manifesting DMD carrier should be ruled out.

[Recent advances in limb-girdle muscular dystrophy research].

In our laboratory, limb-girdle muscular dystrophy (LGMD) accounted for 20% of all patients with muscular dystrophy. To determine the incidence of various forms of LGMD phenotypes, we looked for mutations in the calpain 3 gene and, for deficiencies in dysferlin and sarcoglycan by immunohistochemical studies with specific antibodies on muscle biopsies from patients with probable autosomal recessive inheritance (LGMD2), which were mostly sporadic cases of LGMD. Fourteen of 276 (5%) patients examined had sarcoglycan complex deficiency (sarcoglycanopathy) and 21 of 80 (26%) had mutations in the calpain 3 gene. Although we have not performed gene analysis in all patients, 10 of 64 (15%) patients examined had no apparent immunoreactivity against the dysferlin antibody. Thus, approximately 46% of LGMD2 patients had the above 3 distinct disorders, but in 54% the causative defects remain unknown.

[The frequency of patients with adhalin deficiency in a muscular dystrophy patient population].

Immunocytochemical deficiency of alpha-sarcoglycan (adhalin) in the skeletal muscle that is associated with normal dystrophin expression has been called adhalinopathy. However, recent molecular biological and genetic studies revealed that alpha-sarcoglycan is one of four subunits of sarcoglycans (alpha-delta) or sarcoglycan complex. Mutations of any one of the genes of these subunits cause loss of sarcoglycan complex, and therefore they are now called sarcoglycanopathy or limb-girdle muscular dystrophy (LGMD) 2C-2F. The frequency of sarcoglycanopathy is about 5-10% of dystrophin-normal muscular dystrophy. Mutation of alpha-sarcoglycan gene is most frequent (34%) among the four sarcoglycan genes as shown in the tables. However, 38% of the patients with sarcoglycanopathy have no mutation, implying the presence of yet unknown sarcoglycan(s) and/or interacting protein(s) with sarcoglycan complex.

Fatal hepatic hemorrhage by peliosis hepatis in X-linked myotubular myopathy: a case report.

We report a 5-year-old boy with X-linked myotubular myopathy complicated by peliosis hepatis. At birth, he was affected with marked generalized muscle hypotonia and weakness, which required permanent ventilatory support, and was bedridden for life. He died of acute fatal hepatic hemorrhage after using a mechanical in-exsufflator. Peliosis hepatis, defined as multiple, variable-sized, cystic blood-filled spaces through the liver parenchyma, was confirmed by autopsy. To avoid fatal hepatic hemorrhage by peliosis hepatis, routine hepatic function tests and abdominal imaging tests should be performed for patients with X-linked myotubular myopathy, especially at the time of using artificial respiration.