A diagnostic fluorescent marker kit for six limb girdle muscular dystrophies

The autosomal progressive muscular dystrophies which are grouped together under the term limb girdle muscular dystrophies (LGMD) are diseases characterized by a progressive impairment of the proximal limb muscles and myopathic changes on electromyogram and muscle biopsy. Eight independent purely recessive genetic entities have been recognized in this group of diseases by genetic localization or causative gene identification. We have developed fluorescent genetic markers bracketing six of these loci (LGMD2A–LGMD2F). The marker loci were genotyped in 96 LGMD2 families leading to genetic definition of 25 of them either with a high likelihood or with a suggested localization (7 LGMD2A, 5 LGMD2B, 4 LGMD2C, 4 LGMD2D, 2 LGMD2E and 3 LGMD2F). In addition, 18 families were excluded for all six tested loci; for 45 of the 53 remaining families at least one exclusion could be demonstrated. This kit, which makes the rapid genetic testing of LGMD2 families possible, may be useful in a diagnostic process.     

Diagnostic value of muscle MRI in differentiating LGMD2I from other LGMDs

Mutations in the fukutin–related protein (FKRP) have recently been demonstrated to cause limb girdle muscular dystrophy type 2I (LGMD2I), one of the most common forms of the autosomal recessive LGMDs in Europe. We performed a systematic clinical and muscle MRI assessment in 6 LGMD2I patients and compared these findings with those of 14 patients with genetically confirmed diagnosis of other forms of autosomal recessive LGMDs or dystrophinopathies. All LGMD2I patients had a characteristic clinical phenotype with predominant weakness of hip flexion and adduction, knee flexion and ankle dorsiflexion. These findings were also mirrored on MRI of the lower extremities which demonstrated marked signal changes in the adductor muscles, the posterior thigh and posterior calf muscles. This characteristic clinical and MRI phenotype was also seen in LGMD2A. However, in LGMD2A there was a selective involvement of the medial gastrocnemius and soleus muscle in the lower legs which was not seen in LGMD2I. The pattern in LGMD2A and LGMD2I were clearly different from the one seen in alpha–sarcoglycanopathy and dystrophinopathy type Becker which showed marked signal abnormalities in the anterior thigh muscles. Our results indicate that muscular MRI is a powerful tool for differentiating LGMD2I from other forms of autosomal recessive LGMDs and dystrophinopathies.     

The italian limb girdle muscular dystrophy registry: Relative frequency,clinical features,and differential diagnosis

Introduction: Limb girdle muscular dystrophies (LGMDs) are characterized by high molecular heterogeneity, clinical overlap, and a paucity of specific biomarkers. Their molecular definition is fundamental for prognostic and therapeutic purposes. Methods: We created an Italian LGMD registry that included 370 molecularly defined patients. We reviewed detailed retrospective and prospective data and compared each LGMD subtype for differential diagnosis purposes. Results: LGMD types 2A and 2B are the most frequent forms in Italy. The ages at disease onset, clinical progression, and cardiac and respiratory involvement can vary greatly between each LGMD subtype. In a set of extensively studied patients, targeted next‐generation sequencing (NGS) identified mutations in 36.5% of cases. Conclusion: Detailed clinical characterization combined with muscle tissue analysis is fundamental to guide differential diagnosis and to address molecular tests. NGS is useful for diagnosing forms without specific biomarkers, although, at least in our study cohort, several LGMD disease mechanisms remain to be identified. Muscle Nerve 55 : 55–68, 2017     

Entire CAPN3 gene deletion in a patient with limb‐girdle muscular dystrophy type 2A

Limb‐girdle muscular dystrophy type 2A (LGMD2A) due to mutations in the CAPN3 gene is one of the most common of autosomal recessive limb‐girdle muscular dystrophies. We describe a patient who had a typical LGMD2A phenotype and posterior compartment involvement on MRI. Different genetic analyses were performed, including microarray analysis. There was an apparently homozygous mutation in exon 24, c.2465G>T, p.(*822Leuext62*), and a lack of correlation in the disease segregation analyses. This suggested the presence of a genomic rearrangement. In fact, a heterozygous deletion of the entire CAPN3 gene was found. This novel deletion comprised the terminal region of the GANC gene and the entire CAPN3 gene. This finding points out the need to reconsider and adapt our current strategy of molecular diagnosis in order to detect these types of genomic rearrangements that escape standard mutation screening procedures. Muscle Nerve 50 : 448–453, 2014     

EFNS guideline on diagnosis and management of limb girdle muscular dystrophies

The limb girdle muscular dystrophies (LGMD) are termed as such as they share the characteristic feature of muscle weakness predominantly affecting the shoulder and pelvic girdles; their classification has been completely revised in recent years because of elucidation of many of the underlying genetic and protein alterations in the various subtypes. An array of diagnostic measures is possible but with varying ease of use and availability. Several aspects of muscle cell function appear to be involved in the causation of muscle pathology. These cellular variations may confer some specific clinical features thus permitting recognition of the LGMD subtype and hence directing appropriate levels of monitoring and intervention. Despite an extensive literature on the individual limb girdle dystrophies, these publications may be impenetrable for the general neurologist in this increasingly complex field. The proposed guidelines suggest an approach to the diagnosis and monitoring of the limb girdle dystrophies in a manner accessible to general neurologists.     

Dysferlin aggregation in limb‐girdle muscular dystrophy type 2B/myoshi myopathy necessitates mutational screen for diagnosis

Introduction: Diagnosis of the limb‐girdle muscular dystrophies (LGMDs) has been facilitated by the use of immunofluorescence microscopy, Western blot analysis, and rapid genetic testing. Methods: We identified 7 patients with LGMD2B or Miyoshi myopathy (MM) phenotypes and performed detailed history, physical examination, and mutation analyses of genomic DNA. Results: Ten disease‐causing variants of the dysferlin gene (DYSF) were detected, 4 of which were novel and predicted to be pathogenic (IVS33+9G>T, c.1343T>C, c.4747T>G, and c.5066dupC). Two of these mutations (c.1343T>C and IVS33+9G>T) were associated with a reduction in sarcolemmal dysferlin expression, despite increased total mRNA and protein in mixed muscle homogenates, due to a pathological retention of the mutated polypeptide in the cytoplasm. Conclusions: Considering that protein‐based assays may yield false negative test results and that dysferlin aggregation may be present in other LGMDs, mutational screening is necessary for specific diagnosis in primary dysferlinopathy patients exhibiting this phenotype. Muscle Nerve 47: 740–747, 2013     

Limb-girdle muscular dystrophy

The limb-girdle muscular dystrophies (LGMDs) are a group of muscular dystrophies that share a similar clinical phenotype. Despite this clinical homogeneity, at least 15 different genetic forms of LGMD are now known. Some of these share pathogenetic mechanisms with other forms of muscular dystrophy, such as the sarcoglycanopathies (LGMD 2C-F) and the dystrophinopathies (Duchenne and Becker muscular dystrophy). Some are allelic with other forms of muscular dystrophy; LGMD 1B is allelic with autosomal dominant Emery-Dreifuss muscular dystrophy. Still others introduce totally unique pathogenetic mechanisms to the study of muscular dystrophy. For example, LGMD 2H appears to be due to mutations affecting the ubiquitin-proteasome pathway. A diagnostic approach is outlined based on clinical features, genetics, and commercially available testing.     

LAMA2‐related myopathy: Frequency among congenital and limb‐girdle muscular dystrophies

Introduction: Muscular dystrophy caused by LAMA2‐gene mutations is an autosomal recessive disease typically presenting as a severe, early‐onset congenital muscular dystrophy (CMD). However, milder cases with a limb‐girdle type muscular dystrophy (LGMD) have been described. Methods: In this study, we assessed the frequency and phenotypic spectrum of LAMA2‐related muscular dystrophy in CMD (n = 18) and LGMD2 (n = 128) cohorts identified in the last 15 years in eastern Denmark. The medical history, brain‐MRI, muscle pathology, muscle laminin‐α2 expression, and genetic analyses were assessed. Results: Molecular genetics revealed 2 pathogenic LAMA2 mutations in 5 of 18 CMD and 3 of 128 LGMD patients, corresponding to a LAMA2‐mutation frequency of 28% in the CMD and 2.3% in the LGMD cohorts, respectively. Conclusions: This study demonstrates a wide clinical spectrum of LAMA2‐related muscular dystrophy and its prevalence in an LGMD2 cohort, which indicates that LAMA2 muscular dystrophy should be included in the LGMD2 nomenclature. Muscle Nerve 52: 547–553, 2015     

A novel form of recessive limb girdle muscular dystrophy with mental retardation and abnormal expression of alpha-dystroglycan

The limb girdle muscular dystrophies are a heterogeneous group of conditions characterized by proximal muscle weakness and disease onset ranging from infancy to adulthood. We report here eight patients from seven unrelated families affected by a novel and relatively mild form of autosomal recessive limb girdle muscular dystrophy (LGMD2) with onset in the first decade of life and characterized by severe mental retardation but normal brain imaging. Immunocytochemical studies revealed a significant selective reduction of alpha-dystroglycan expression in the muscle biopsies. Linkage analysis excluded known loci for both limb girdle muscular dystrophy and congenital muscular dystrophies in the consanguineous families. We consider that this represents a novel form of muscular dystrophy with associated brain involvement. The biochemical studies suggest that it may belong to the growing number of muscular dystrophies with abnormal expression of alpha-dystroglycan.     

Pattern of skeletal muscle involvement in primary dysferlinopathies: a whole‐body 3.0‐T magnetic resonance imaging study

Objectives and methods – Mutations in the gene encoding dysferlin cause limb girdle muscular dystrophy type 2B (LGMD2B), distal Miyoshi myopathy (MM), and a rare form of distal anterior compartment myopathy. To study the correlations between clinical manifestations and muscle imaging changes we conducted a 3.0‐T magnetic resonance imaging (MRI) study in six German patients with primary dysferlinopathies defined by absence of dysferlin expression in muscle (MM, n = 3; LGMD2B, n = 2; hyperCKemia without clinical symptoms, n = 1). Results – Patients with manifest myopathy had widespread muscular pathology. In analogy to previous imaging studies, we confirmed an involvement of the anterior and posterior thigh compartments and a predominant involvement of posterior lower legs. However, our whole‐body MRI study further provided evidence of signal alterations in the glutei, erector spinae and shoulder girdle muscles. Correlation of clinical findings with imaging demonstrated the potential of MRI to detect subclinical muscle pathology. Conclusions – Whole‐body 3.0‐T MRI is a non‐invasive method to demonstrate various degrees of skeletal muscle alterations and disease progression in muscular dystrophies. Furthermore, whole‐body high‐field MRI may serve as a helpful diagnostic tool in differentiating primary dysferlinopathies from other forms of LGMD and distal myopathies.     

Variable reduction of caveolin-3 in patients with LGMD2B/MM

Abstract. Mutations in the human dysferlin gene (DYSF) cause autosomal recessive muscular dystrophies characterized by degeneration and weakness of proximal and/or distal muscles: limb girdle muscular dystrophy type 2B (LGMD2B) and Miyoshi myopathy (MM). Recently, an interaction between caveolin-3 and dysferlin in normal and dystrophic muscle (primary caveolin-3 deficiency; LGMD1C) was shown. In this study, clinical,morphological and genetic analysis was carried out in four independent LGMD2B/MM patients. All patients presented with an adult-onset, slowly progressive muscular dystrophy with variable involvement of proximal and distal muscles. We found complete lack of dysferlin in the four LGMD2B/MM patients. Secondary reduction of caveolin-3 was detected in three out of the four patients. Regular caveolae were detected along the basal lamina in two patients by electron microscopy. We provide further evidence that dysferlin and caveolin-3 interact in human skeletal muscle. It remains to be elucidated whether the loss of this interaction contributes to pathogenic events in muscular dystrophy.M. C. Walter and C. Braun contributed equally.     

Calpain-3 gene defect causing limb gird muscular dystrophy in a Hungarian family

Limb gird muscular dystrophies (LGMD2) are a clinically and genetically heterogeneous group of hereditary diseases with autosomal recessive trait, characterized by progressive atrophy and weakness predominantly in the proximal limb muscles. The authors present clinical, histological, immunohistochemical and immunoblot results of two sisters suffering from so far unclassified autosomal recessive limb girdle muscular dystrophy. Haplotype analysis for genes possibly involved in autosomal recessive limb girdle muscular dystrophies was performed in the genetically informative family. All of the results pointed to a molecular genetic defect of the calpain-3 (CAPN3) gene. Direct sequencing of the CAPN3 gene revealed compound heterozygous state for two mutations previously described in association with limb girdle muscular dystrophy, proving pathogenicity. The authors would like to emphasize the importance of the above described combined strategy in diagnosing limb girdle muscular dystrophies.     

Muscle pathology in 31 patients with calpain 3 gene mutations

Background and purposeAt present, more than 20 different forms of limb-girdle muscular dystrophies (LGMDs) are known (at least 7 autosomal dominant and 14 autosomal recessive). Although these different forms show some typical phenotypic characteristics, the existing clinical overlap makes their differential diagnosis difficult. Limb-girdle muscular dystrophy type 2 (LGMD2A) is the most prevalent LGMD in many European as well as Brazilian communities and is caused by mutations in the gene CAPN3. Laboratory testing, such as calpain immunohistochemistry and Western-blot analysis, is not totally reliable, since up to 20% of molecularly confirmed LGMD2A show normal content of calpain 3 and a third of LGMD2A biopsies have normal calpain 3 proteolytic activity in the muscle. Thus, genetic testing is considered as the only reliable diagnostic criterion in LGMD2A.Material and methodsIn an attempt to find a correlation between genotype and muscle pathology in limb-girdle muscular dystrophy 2A we performed histopathological investigation of a group of 31 patients subdivided according to the type of pathologic CAPN3 gene mutation.ResultsIn all biopsies typical features of muscular dystrophy such as fiber necrosis and regeneration, variation in fiber size and fibrosis were noted. Lobulated fibers were often encountered in the muscle biopsies of LGMD2A patients. Such fibers were more frequent in patients with 550delA mutation.ConclusionsThese findings may be helpful in establishing diagnostic strategies in LGMD.     

Klinik und Genetik der Gliedergürteldystrophien

Limb girdle muscular dystrophies (LGMDs) are a genetically heterogeneous group of primary myopathies involving progressive weakness and wasting of the muscles in the hip and shoulder girdles, with distal spread to the bulbar or respiratory musculature in rare cases. Depending on the mode of genetic transmission, six autosomal dominant forms (LGMD1A-F, 10-25%) and ten autosomal recessive forms (LGMD2A-J, 75-90%) are currently known. The prevalence of LGMDs is 0.8/100,000. These conditions are caused by mutations in genes encoding for myotilin (5q31, LGMD1A), lamin A/C (1q11-q21.2, LGMD1B), caveolin-3 (3p25, LGMD1C), unknown proteins (7q, LGMD1D, 6q23, LGMD1E, 7q32.1-32.2., LGMD1F), calpain-3 (15q15.1-21.1, LGMD2A), dysferlin (2p13.3-13.1, LGMD2B), gamma-sarcoglycan (13q12, LGMD2C), alpha-sarcoglycan, also known as adhalin (17q12-q21.3, LGMD2D), beta-sarcoglycan (4q12, LGMD2E), delta-sarcoglycan (5q33-q34, LGMD2F), telethonin (17q11-q12, LGMD2G), E3-ubiquitin ligase (9q31-q34.1, LGMD2H), fukutin-related protein (19q13.3, LGMD2I), and titin (2q31, LGMD2J). Cardiac involvement has been described for LGMD1B-E, LGMD2C-G, and LGMD2I. The time of onset varies between early childhood and middle age. There is no male or female preponderance. Disease progression and life expectancy vary widely, even among different members of the same family. The diagnosis is based primarily on DNA analysis. The history, clinical neurological examinations, blood chemistry investigations, electromyography, and muscle biopsy also provide information that is helpful for the diagnosis. No causal therapy is currently available.     

Limb-girdle muscular dystrophy; update]

Sixteen different forms of limb-girdle muscular dystrophies (LGMDs) have emerged from recent molecular genetic studies, six forms with a dominant trait and ten forms with a recessive trait. Among 1,420 Japanese patients with muscular dystrophy analyzed at NCNP, LGMD is the secondly largest category (19%) following dystrophinopathy (56%). Within LGMDs, the occurrence of LGMD2A (calpainopathy), LGMD2B (dysferlinopathy), and LGMD2C-F (sarcoglycanopathy) is 26%, 18%, and 6.6%, respectively, however, causative genes have not been specified in about 50% of the LGMD patients. LGMD2A patients show atrophy prominent in shoulder and pelvic girdle muscles without calf muscle hypertrophy, and abundant lobulated fibers in muscle biopsy. Four major mutations unique to the Japanese population, have been identified. Pathogenesis attributes to a loss of proteolytic activity of mutant calpain-3. Dysferlin, the defective protein in LGMD2B, is a ferlin family molecule possessing six C2 domains probably mediating the resealing mechanism of the damaged sarcolemma. Mutations in the dysferlin gene result in Miyoshi distal myopathy and distal anterior compartment myopathy other than LGMD2B. Among four sarcoglyconopathies, LGMD2D is the most common form, whereas LGMD2F has not yet been reported. In sarcoglycan-deficient skeletal muscle, matrix metalloproteinases may be involved in the beta-dystroglycan processing which underlies the pathogenesis of sarcoglycanopathy.     

Limb girdle muscular dystrophy: Description of a phenotype

The phenotype is reported of 20 patients with autosomal recessive or sporadic, pelvifemoral limb girdle muscular dystrophy (LGMD). Selective wasting of muscles was observed at the moderately advanced stage of illness. The pattern of weakness was uniform. Attention to clinical detail allowed the identification of a phenotype different from a hypothetical scheme of LGMD based on previous literature, and other causes of limb girdle weakness. These patients may represent yet another nosologic entity within the autosomal recessive dystrophies; molecular genetic studies are awaited. A limited magnetic resonance imaging (MRI) study of muscle was of little consequence. Although additional detail was obtained, no pathognomonic distribution of the dystrophic process was observed; interindividual variation existed even among closely matched siblings. The severity of MRI signal change did not consistently correlate with the degree of weakness in an individual. When a diagnosis is uncertain, however, the added detail may be useful. © 1994 John Wiley & Sons, Inc.     

Episodes of exercise-induced dark urine and myalgia in LGMD 2I

Lindberg C, Sixt C, Oldfors A. Episodes of exercise‐induced dark urine and myalgia in LGMD 2I.
Acta Neurol Scand: 2012: 125: 285–287.
© 2011 John Wiley & Sons A/S. Background – Mutations in the fukutin‐related protein gene FKRP (MIM *606596) cause a form of congenital muscular dystrophy (MDC1C) and also limb girdle muscular dystrophy type 2I (LGMD2I). Exercise‐induced myoglobinuria, frequently occurring in metabolic myopathies, has been described in Becker muscular dystrophy and in a few cases of LGMD. Objectives – To describe that episodes with myoglobinuria, often associated with exercise‐induced myalgia, may be common and a presenting symptom in patients with LGMD2I. Methods – Data on episodes of suspected myoglobinuria and myalgia were collected from the patient records on 14 patients with a diagnosis of LGMDI. Results – Five LGMD2I patients reported recurrent episodes of dark urine and myalgia after exercise, and in three of them, this was the only symptom for several years. Conclusions – We conclude that episodes compatible with exercise‐induced myoglobinuria may be frequent in LGMD2I.     

Homozygous contiguous gene deletion of 13q12 causing LGMD2C and ARSACS in the same patient

We describe a 10‐year‐old girl with limb‐girdle muscular dystrophy type 2C (LGMD2C, gamma‐sarcoglycan deficiency) with additional features that include progressive lower limb spasticity, peripheral neuropathy, and ataxia. The gene for LGMD2C lies in close approximation to the gene for autosomal recessive spastic ataxia of Charlevoix–Saguenay (ARSACS) on chromosome 13q12. The clinical presentation was suspicious for a genomic rearrangement affecting the expression of both genes. Using chromosomal microarray analysis, a homozygous deletion that encompassed the genes for both disorders was identified. This is the first report of a patient with both neurological diseases, and this case illustrates the clinical utility of microarray technology in the investigation of patients with unusual presentations. Muscle Nerve 39: 396–400, 2009     

Protein and genetic diagnosis of limb girdle muscular dystrophy type 2A: The yield and the pitfalls

Limb girdle muscular dystrophy type 2A (LGMD2A) is the most frequent form of LGMD worldwide. Comprehensive clinical assessment and laboratory testing is essential for diagnosis of LGMD2A. Muscle immunoblot analysis of calpain‐3 is the most useful tool to direct genetic testing, as detection of calpain‐3 deficiency has high diagnostic value. However, calpain‐3 immunoblot testing lacks sensitivity in about 30% of cases due to gene mutations that inactivate the enzyme. The best diagnostic strategy should be determined on a case‐by‐case basis, depending on which tissues are available, and which molecular and/or genetic methods are adopted. In this work we survey the current knowledge, advantages, limitations, and pitfalls of protein testing and mutation detection in LGMD2A and provide an update of genetic epidemiology. Muscle Nerve 52 : 163–173, 2015