Dysferlin protein analysis in limb-girdle muscular dystrophies

Dysferlin is the protein product of the DYSF gene mapped at 2p31, which mutations cause limb-girdle muscular dystrophy type 2B (LGMD2B) and Miyoshi myopathy. To date, nine autosomal recessive forms (AR-LGMD) have been identified: four genes, which code for the sarcoglycan glycoproteins, are associated with both mild and severe forms, the sarcoglycanopathies (LGMD2C, 2D, 2E and 2F). The other five forms, usually causing a milder phenotype are LGMD2A (calpain 3), LGMD2B (dysferlin), LGMD2G (telethonin), LGMD2H (9q31-11), and LGMD21 (19q13.3). We studied dysferlin expression in a total of 176 patients, from 166 LGMD families: 12 LGMD2B patients, 70 with other known forms of muscular dystrophies (LGMD2A, sarcoglycanopathies, LGMD2G), in an attempt to assess the effect of the primary gene-product deficiency on dysferlin. In addition, 94 still unclassified LGMD families were screened for dysferlin deficiency. In eight LGMD2B patients from five families, no dysferlin was observed in muscle biopsies, both through immunofluorescence (IF) and Western blot methodologies, while in two families, a very faint band was detected. Both patterns, negative or very faint bands, were concordant in patients belonging to the same families, suggesting that dysferlin deficiency is specific to LGMD2B. Myoferlin, the newly identified homologue of dysferlin was studied for the first time in LGMD2B patients. Since no difference was observed between patients mildly and severely affected, this protein do not seem to modify the phenotype in the present dysferlin-deficient patients. Dystrophin, sarcoglycans, and telethonin were normal in all LGMD2B patients, while patients with sarcoglycanopathies (2C, 2D, and 2E), LGMD2A, LGMD2G, and DMD showed the presence of a normal dysferlin band by Western blot and a positive pattern on IF. These data suggest that there is no interaction between dysferlin and these proteins. However, calpain analysis showed a weaker band in four patients from two families with intra-familial concordance. Therefore, this secondary deficiency of calpain in LGMD2B families, may indicate an interaction between dysferlin and calpain in muscle. Dysferlin was also present in cultured myotubes, in chorionic villus, and in the skin. Dysferlin deficiency was found in 24 out of a total of 166 Brazilian AR-LGMD families screened for muscle proteins (approximately 14%), thus representing the second most frequent known LGMD form, after calpainopathy, in our population.     

Genomic organization of the dysferlin gene and novel mutations in Miyoshi myopathy

OBJECTIVE: Mutations in the skeletal muscle gene dysferlin cause two autosomal recessive forms of muscular dystrophy: Miyoshi myopathy (MM) and limb girdle muscular dystrophy type 2B (LGMD2B). The purpose of this study was to define the genomic organization of the dysferlin gene and conduct mutational screening and a survey of clinical features in 21 patients with defined molecular defects in the dysferlin gene. METHODS: Genomic organization of the gene was determined by comparing the dysferlin cDNA and genomic sequence in P1-derived artificial chromosomes (PACs) containing the gene. Mutational screening entailed conformational analysis and sequencing of genomic DNA and cDNA. Clinical records of patients with defined dysferlin gene defects were reviewed retrospectively. RESULTS: The dysferlin gene encompasses 55 exons spanning over 150 kb of genomic DNA. Mutational screening revealed nine novel mutations associated with MM. The range of onset in this patient group was narrow with a mean of 19.0 +/- 3.9 years. CONCLUSION: This study confirms that the dysferlin gene is mutated in MM and LGMD2B and extends understanding of the timing of onset of the disease. Knowledge of the genomic organization of the gene will facilitate mutation detection and investigations of the molecular biologic properties of the dysferlin gene.     

应用免疫印迹法诊断肢带型肌营养不良2A型

目的 应用免疫印迹法(Western blot)诊断肢带型肌营养不良2A型(LGMD2A)患者并与LGMD2B型相鉴别.方法 收集我院诊治的4例LGMD2型患者的临床、病理及生化检验资料.取肌肉活体组织行组织化学和免疫组织化学染色,用Western blot分析dysferlin蛋白及calpain-3蛋白的表达.结果 LGMD2A与2B型患者的临床症状相似;免疫组织化学染色显示所有患者均出现不同程度的dysferlin缺失.但Western blot揭示:LGMD2A型患者calpain-3蛋白完全缺失,dysferlin蛋白部分缺失;而2B型患者则相反.结论 用Western blot检测calpain-3蛋白可在dysfedin蛋白表达缺失的LGMD患者中鉴别出2A型患者,该方法对临床辅助诊断LGMD2A有很好的价值.     

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.     

Calpain-3 and dysferlin protein screening in patients with limb-girdle dystrophy and myopathy

BACKGROUND: Mutations in the genes encoding for calpain-3 and dysferlin are responsible for limb-girdle muscular dystrophy (LGMD) type 2A and 2B, the most common forms of autosomal recessive LGMD. OBJECTIVE: To identify calpain-3 or dysferlin deficiency in a large cohort of patients with as yet unclassified LGMD and myopathy through candidate protein analysis. METHODS: The authors' muscle biopsy database search identified 407 candidate muscle biopsies with normal dystrophin and sarcoglycan. Calpain-3 and dysferlin were studied by Western blotting and immunohistochemistry. RESULTS: Combined calpain-3 and dysferlin Western blot analysis identified calpain-3 deficiency in 66 (16%) muscle biopsies. In 31 cases (47%), the protein was absent, and in 35 (53%), it was severely reduced in amount (3 to 50% of control). Dysferlin deficiency was found in 26 (6.5%) muscle biopsies. In 9, the protein was absent (35%), and in 17 (65%), it was severely reduced in amount (traces to 20% of control). Twenty-eight percent (53/191) of patients with LGMD phenotype had calpain-3 deficiency. Sixty percent (21/35) of patients with distal myopathy had dysferlin deficiency. Dysferlin immunohistochemistry showed, in the completely dysferlin-deficient patients, absent reaction at the sarcolemma but positive nuclear membrane labeling and, in the partially dysferlin-deficient patients, scattered granular positive cytoplasmic areas and diffuse reaction in regenerating fibers. CONCLUSION: About 25% of previously unclassified dystrophy/myopathy cases are due to calpain-3 or dysferlin protein deficiency. These results suggest that immunoblot analysis may be used to define patients for calpain-3 and dysferlin gene mutation studies.     

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.     

Dysferlinopathy in the Jews of the Caucasus: a frequent mutation in the dysferlin gene

Dysferlin encoding gene (DYS) is mutated in the autosomal recessive disorders Miyoshi myopathy, Limb Girdle Muscular Dystrophy type 2B (LGMD2B) and distal anterior compartment myopathy, causing dysferlin deficiency in muscle biopsy. Three ethnic clusters have previously been described in Dysferlinopathy: the Libyan Jewish population originating in the area of Tripoli, Italian and Spanish populations. We report another cluster of this muscular dystrophy in Israel among Jews of the Caucasus region. A genomic analysis of the dysferlin coding sequence performed in patients from this ethnic group, who demonstrated an absence of dysferlin expression in muscle biopsy, revealed a homozygous frameshift mutation of G deletion at codon 927 (2779delG) predicting a truncated protein and a complete loss of functional protein. The possible existence of a founder effect is strengthened by our finding of a 4% carrier frequency in this community. These findings are important for genetic counseling and also enable a molecular diagnosis of LGMD2B in Jews of the Caucasus region.     

Intracellular accumulation and reduced sarcolemmal expression of dysferlin in limb--girdle muscular dystrophies

Dysferlin has recently been identified as a novel gene involved in limb-girdle muscular dystrophy type 2B (LGMD2B) and its allelic disease, Miyoshi myopathy. The predicted structure of dysferlin suggests that it is a transmembrane protein possibly involved in membrane fusion. Thus, unlike previously identified structural proteins in muscular dystrophy, dysferlin is likely involved in a novel pathogenic mechanism for this disease. In this study, we have analyzed the expression of dysferlin in skeletal muscle of patients with disruptions in the dystrophin-glycoprotein complex and patients with a clinical diagnosis of LGMD2B or Miyoshi myopathy. We show expression of dysferlin at the sarcolemma in normal muscle and reduced sarcolemmal expression along with accumulation of intracellular staining in dystrophic muscle. Electron microscopy in Miyoshi myopathy biopsies suggests that the cytoplasmic staining could be a result of the abundance of intracellular vesicles. Our results indicate that dysferlin expression is perturbed in LGMD and that both mutations in the dysferlin gene and disruption of the dystrophin-glycoprotein complex can lead to the accumulation of dysferlin within the cytoplasm.     

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.     

Protein and gene analyses of dysferlinopathy in a large group of Japanese muscular dystrophy patients

Mutations in the dysferlin gene cause muscular dystrophies called dysferlinopathy, which include limb-girdle muscular dystrophy type 2B (LGMD2B) and Miyoshi myopathy (MM). To clarify the frequency, clinicopathological and genetic features of dysferlinopathy in Japan, we performed protein and gene analyses of dysferlin. We examined a total of 107 unrelated Japanese patients, including 53 unclassified LGMD, 28 MM and 26 other neuromuscular disorders (ONMD). Expression of dysferlin protein was observed using immunohistochemistry (IHC) and mini-multiplex Western blotting (MMW), and mutation analysis was performed. We found a deficiency of dysferlin protein by both IHC and MMW in 19% of LGMD and 75% of MM patients, and mutations in the dysferlin gene were identified in this group alone. 19% of dysferlin-deficient patients had 3370G-->T missense mutation and 16% had 1939C-->G nonsense mutation. The patients with homozygous 3370G-->T mutation showed milder clinical phenotypes. Twenty-five percent of MM muscles had normal dysferlin protein contents that suggested the genetic heterogeneity of this disease. Altered immunolocalization of dysferlin was observed in not only primary dysferlinopathy, but also in the several diseased muscles with normal protein contents. This result implies the necessity of other protein(s) for proper membrane localization of dysferlin, or some roles of dysferlin in the cytoplasmic region.     

A novel mutation in the DYSF gene in a patient with a presumed inflammatory myopathy

Dysferlinopathy, a progressive muscular dystrophy, results from mutations in the Dysferlin gene (DYSF, MIM*603009). Traditional diagnosis relies on the reduction or absence of dysferlin. However, altered dysferlin has been observed in other myopathies, leading to a precise diagnosis through molecular genetics. In this study, we report a patient who was previously misdiagnosed as inflammatory myopathy based on routine clinicopathological examinations alone. However, muscle biopsy specimens were analyzed further by immunohistochemistry of muscular dystrophy‐related proteins, and gene‐targeted next generation sequencing (NGS) was used to correctly identify muscular dystrophy. DNA was sequenced with NGS and the detected mutation was verified by Sanger sequencing. Our targeted NGS found a novel missense mutation (c.5392G > A) in the DYSF gene, allowing correct diagnosis of LGMD2B in our patient. We discovered of a novel missense mutation in the DYSF gene and have broadened the DYSF mutation spectrum, which may be correlated in patients with presumed dysferlinopathy, especially when lymphocytic infiltration is observed.     

微量标本Western blot在诊断肢带型肌营养不良2A型中的应用

目的 探讨微量标本Western blot在诊断肢带型肌营养不良2A型中的应用.方法 对73例以肢体近端肌肉受累为首要临床表现的进行性肌营养不良患者行开放式骨骼肌活体组织检查,标本行组织化学染色以及抗dystrophin-N、C、R,α、β、γ、δ-sarcoglycan,dysferlin,caveolin-3单克隆抗体免疫组织化学染色.对其中已经除外dystrophin、sarcoglycans、dysferlin、caveolin-3蛋白异常的29例患者再行骨骼肌Western blot抗calpain-3、caveolin-3单克隆抗体免疫反应.结果 共有10例患者被确诊为肢带型肌营养不良2A型,其临床特点均为肢体近端肌无力起病,血清肌酸激酶不同程度升高,肌电图呈肌源性改变.组织化学染色见肌纤维大小不一,可见不同程度肌纤维变性、坏死和再生,结缔组织增生,6例见分叶状肌纤维;免疫组织化学染色见肌纤维中dystrophin、sarcoglycan、dysferlin、caveolin-3蛋白均正常表达.Western blot发现该10例患者相对分子质量94 000条带(calpain-3)与Duchenne/Becker型肌营养不良对照相比,呈完全(8例)或部分(2例)缺失;30 000区域附加条带均呈弱表达,22 000区域条带(caveolin-3)均正常表达.结论 骨骼肌微量标本Western blot是诊断LGMD2A的有效方法,适用于临床LGMD的分型诊断.     

Dysferlin interacts with affixin (beta-parvin) at the sarcolemma

The dysferlin gene is defective in Miyoshi myopathy (MM) and limb girdle muscular dystrophy type 2B (LGMD2B). Dysferlin is a sarcolemmal protein that is implicated in calcium-dependent membrane repair. Affixin (beta-parvin) is a novel, integrin-linked kinase-binding protein that is involved in the linkage between integrin and the cytoskeleton. Here we show that affixin is a dysferlin binding protein that colocalizes with dysferlin at the sarcolemma of normal human skeletal muscle. The immunoreactivity of affixin was reduced in sarcolemma of MM and LGMD2B muscles, although the total amount of the affixin protein was normal. Altered immunoreactivity of affixin was also observed in other muscle diseases including LGMD1C, where both affixin and dysferlin showed quite similar changes with a reduction of sarcolemmal staining with or without cytoplasmic accumulations. Colocalization of dysferlin and affixin was confirmed by immunofluorescence analysis using dysferlin-expressing C2 myoblasts. Wild-type and mutant dysferlin colocalized with endogenous affixin. The interaction of dysferlin and affixin was confirmed by immunoprecipitation study using normal human and mouse skeletal muscles. Using immunoprecipitation with deletion mutants of dysferlin, we have identified that C-terminal region of dysferlin is an apparent binding site for affixin. We also found N-terminal calponin homology domain of affixin as a binding site for dysferlin. Our results suggest that affixin may participate in membrane repair with dysferlin.     

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.     

High prevalence and phenotype-genotype correlations of limb girdle muscular dystrophy type 2I in Denmark

OBJECTIVES: The prevalence of limb girdle muscular dystrophy type 2I (LGMD2I) in northern Europe is unknown. We investigated this and the genotype-phenotype relation in LGMD2I. METHODS: Prospective clinical and molecular screening of 118 Danish patients registered with LGMD was performed to divide patients into LGMD subtypes. RESULTS: One hundred three patients fulfilled the clinical criteria for LGMD2. Thirty-eight had LGMD2I (27 homozygous, 11 compound heterozygous for 826C>A), 23 had sarcoglycanopathy, 2 dysferlinopathy, 12 calpainopathy, and 4 Becker muscular dystrophy. The 24 patients with no molecular diagnosis did not harbor fukutin-related protein gene (FKRP) mutations. A clear clinical delineation was found between patients homozygous and compound heterozygous for the 826C>A mutation. Homozygous patients had later debut, milder clinical progression, and less muscle weakness compared with compound heterozygous patients, who were all wheelchair bound by their mid-20s. Impaired cardiac pump function was found in both groups. INTERPRETATION: This study reports a different distribution of LGMD subtypes in Denmark than seen in other geographic regions, with a threefold to fourfold higher prevalence of LGMD2I than elsewhere. The findings support a clear clinical delineation between patients homozygous and compound heterozygous for the 826C>A mutation in FKRP. The findings suggest that, in the studied region, screening for the 826C>A mutation will identify all persons with LGMD2I.     

Challenges for the genetic screening in dysferlin deficiency--report of an instructive case and review of the literature

The homozygous or compound heterozygous mutation of the alleles of DYSF gene causes dysferlinopathy resulting in limb girdle muscular dystrophy Type 2B (LGMD 2B) or Miyoshi myopathy. However, patients with only 1 (heterozygous) mutation on 1 allele are increasingly recognized. Based on the Leiden database (www.dmd.nl) among 257 different mutations resulting in dysferlin-deficient muscular dystrophy, pathogenic mutations were detected only on 1 allele in 45 cases, while the exons of the other allele did not show any pathological alterations. The relatively high number of these so-called heterozygous cases raises the question if present routine molecular techniques are sufficient alone for confirming the diagnosis of dysferlin deficiency. In fact, the heterogenous genetic background of the disease makes it impossible to make the correct diagnosis without Western blot of the muscle dysferlin. This paper presents the clinical, myopathological and molecular genetic results of a 30-year-old male with dysferlinopathy as an instructive case. The cDNA sequencing of the dysferlin gene revealed a single C5302T heterozygous mutation resulting in Arg1768Trp exchange. The paper highlights the importance of the protein analysis in the diagnosis of dysferlin deficiency, discusses the difficulties of the complete genomic analysis of the dysferlin gene alterations and the possible etiopathogenetic role of the noncoding DNA sequence of the dysferlin gene in dysferlin deficiencies.     

分子病理确诊的肢带型肌营养不良2A型患者五例临床及病理特点

目的 通过总结5例肢带型肌营养不良2A型(LGMD2A)患者的病例资料,探讨其临床和病理特点.方法 对病理诊断排除LGMD2B(7例)之后的30例分型未明的LGMD患者的肌肉标本进行免疫组织化学染色和钙激活蛋白酶-3(calpain-3)蛋白免疫印迹分析.结果 30例患者肌肉标本中有5例calpain-3蛋白条带缺失或遗留痕迹,从而被确诊为钙蛋白酶肌病,即LGMD2A.该5例患者起病年龄10～45岁,病程2～10年.其中2例的同胞兄妹有相似的临床表现,而父母无异常,提示本病的常染色体隐性遗传方式.5例均以下肢近端肌无力起病,肌萎缩明显;血清肌酸激酶639～8237 U/L,平均2502 U/L,肌电图均为肌源性损害.5例肌肉活体组织检查病理符合典型肌营养不良的病理特点,表现为肌纤维大小明显不等,可见坏死伴吞噬及再生,内核纤维增多,还原型辅酶Ⅰ四氮唑还原酶染色2例见分叶状纤维.5例LGMD2A患者dystrophin、caveolin-3和α-、β-、γ-、δ-sarcoglycan免疫组织化学染色均正常,2例dysferlin染色减低,余3例正常.结论 LGMD2A的临床表现和肌活体组织检查病理均缺乏特异性,免疫印迹分析有助于此病的诊断和鉴别诊断.     

Homozygous mutations in caveolin-3 cause a severe form of rippling muscle disease

Heterozygous missense mutations in the caveolin-3 gene (CAV3) cause different muscle disorders. Most patients with CAV3 alterations present with rippling muscle disease (RMD) characterized by signs of increased muscle irritability without muscle weakness. In some patients, CAV3 mutations underlie the progressive limb-girdle muscular dystrophy type 1C (LGMD1C). Here, we report two unrelated patients with novel homozygous mutations (L86P and A92T) in CAV3. Both presented with a more severe clinical phenotype than usually seen in RMD. Immunohistochemical and immunoblot analyses of muscle biopsies showed a strong reduction of caveolin-3 in both homozygous RMD patients similar to the findings in heterozygous RMD. Electron microscopy studies showed a nearly complete absence of caveolae in the sarcolemma in all RMD patients analyzed. Additional plasma membrane irregularities (small plasmalemmal discontinuities, subsarcolemmal vacuoles, abnormal papillary projections) were more pronounced in homozygous than in heterozygous RMD patients. A stronger activation of nitric oxide synthase was observed in both homozygous patients compared with heterozygous RMD. Like in LGMD1C, dysferlin immunoreactivity is reduced in RMD but more pronounced in homozygous as compared with heterozygous RMD. Thus, we further extend the phenotypic variability of muscle caveolinopathies by identification of a severe form of RMD associated with homozygous CAV3 mutations.