Fukutin-related Protein Associates with the Sarcolemmal Dystrophin-Glycoprotein Complex

Beedle, Aaron M.; Nienaber, Patricia M.; Campbell, Kevin P.

doi:10.1074/jbc.c700061200

Cited by 36 publications

(32 citation statements)

References 30 publications

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“…3E). This is in contrast to other muscular dystrophies involving the DGC, where one primary genetic defect leads to disruption of the entire DGC, as assessed by using the same assay (27,28). This finding indicates that it is not the loss of the entire DGC, but rather the disrupted linkage between the sarcolemma and the basal lamina (due to disrupted glycosylation of ␣-DG) (Fig.…”

Section: Large Myd Muscle Maintains An Intact Dgc But Is Highly Suscementioning

confidence: 39%

Basal lamina strengthens cell membrane integrity via the laminin G domain-binding motif of α-dystroglycan

Han

Kanagawa

Yoshida‐Moriguchi

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

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129

133

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Skeletal muscle basal lamina is linked to the sarcolemma through transmembrane receptors, including integrins and dystroglycan. The function of dystroglycan relies critically on posttranslational glycosylation, a common target shared by a genetically heterogeneous group of muscular dystrophies characterized by ␣-dystroglycan hypoglycosylation. Here we show that both dystroglycan and integrin ␣7 contribute to force-production of muscles, but that only disruption of dystroglycan causes detachment of the basal lamina from the sarcolemma and renders muscle prone to contraction-induced injury. These phenotypes of dystroglycan-null muscles are recapitulated by Large myd muscles, which have an intact dystrophin-glycoprotein complex and lack only the laminin globular domain-binding motif on ␣-dystroglycan. Compromised sarcolemmal integrity is directly shown in Large myd muscles and similarly in normal muscles when arenaviruses compete with matrix proteins for binding ␣-dystroglycan. These data provide direct mechanistic insight into how the dystroglycan-linked basal lamina contributes to the maintenance of sarcolemmal integrity and protects muscles from damage. dystroglycanopathy ͉ glycosylation ͉ integrin ͉ membrane damage ͉ muscular dystrophy

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Section: Large Myd Muscle Maintains An Intact Dgc But Is Highly Suscementioning

confidence: 39%

Basal lamina strengthens cell membrane integrity via the laminin G domain-binding motif of α-dystroglycan

Han

Kanagawa

Yoshida‐Moriguchi

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

129

133

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“…For secondary immunofluorescence, tissues were blocked with 5% donkey serum in PBS, incubated in primary antibody overnight, washed, incubated in Cy3 (Jackson ImmunoResearch Laboratories Inc.) or Alexa Fluor 488-conjugated (Molecular Probes, Invitrogen) secondary antibodies, washed, and coverslipped. With the exception of αDG glycosylation staining, tissue cryosections were processed for immunofluorescence as described previously (81). For αDG glyco-antibody IIH6, tissues were fixed in 2% PFA, washed, and denatured by incubations with 100 mM glycine at room temperature and 0.05% SDS at 50°C for 10 and 30 minutes, respectively (82).…”

Section: Methodsmentioning

confidence: 99%

“…PHOS-bead voids were buffer exchanged (same as desalting step) and concentrated, diluted 1:1 with phosphate buffer, and mixed with 5×LSB for SDS-PAGE. All protein samples were separated by 3%-15% SDS-PAGE and transferred to PVDF for Western blotting using standard protocols (81). Laminin overlays have been described previously (37).…”

Section: Methodsmentioning

confidence: 99%

Mouse fukutin deletion impairs dystroglycan processing and recapitulates muscular dystrophy

Beedle¹,

Turner²,

Saito³

et al. 2012

J. Clin. Invest.

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Dystroglycan is a transmembrane glycoprotein that links the extracellular basement membrane to cytoplasmic dystrophin. Disruption of the extensive carbohydrate structure normally present on α-dystroglycan causes an array of congenital and limb girdle muscular dystrophies known as dystroglycanopathies. The essential role of dystroglycan in development has hampered elucidation of the mechanisms underlying dystroglycanopathies. Here, we developed a dystroglycanopathy mouse model using inducible or muscle-specific promoters to conditionally disrupt fukutin (Fktn), a gene required for dystroglycan processing. In conditional Fktn-KO mice, we observed a near absence of functionally glycosylated dystroglycan within 18 days of gene deletion. Twentyweek-old KO mice showed clear dystrophic histopathology and a defect in glycosylation near the dystroglycan O-mannose phosphate, whether onset of Fktn excision driven by muscle-specific promoters occurred at E8 or E17. However, the earlier gene deletion resulted in more severe phenotypes, with a faster onset of damage and weakness, reduced weight and viability, and regenerating fibers of smaller size. The dependence of phenotype severity on the developmental timing of muscle Fktn deletion supports a role for dystroglycan in muscle development or differentiation. Moreover, given that this conditional Fktn-KO mouse allows the generation of tissue-and timingspecific defects in dystroglycan glycosylation, avoids embryonic lethality, and produces a phenotype resembling patient pathology, it is a promising new model for the study of secondary dystroglycanopathy.

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“…According to yamamoto et al 25 , although the functions of fukutin continue unclear, it seems to interact with alpha-DG during glycosylation but binding to the core area of alpha-DG instead of its sugar chain. Also concerning FKrP, it has recently been supposed that in normal and mutant mice it is detected in the sarcollema and coexists with DG in the native dystrophin-glycoprotein complex, perhaps having its localization mediated by DG 26 . It has not yet been demonstrated that lArGe is a glycosyltransferase itself but the Kanagawa et al 27 found that alpha-DG interacts with lArGe at two different domains, one involved with the glycosilation process itself and the other at intracellular level (N-terminal domain of α-DG) for defining a recognition motif necessary to initiate functional glycosylation.…”

Section: Fig 1 Schematic Representation Of the Main Proteins Involvementioning

confidence: 99%

Congenital muscular dystrophy. Part II: a review of pathogenesis and therapeutic perspectives

Reed

2009

Arq. Neuro-Psiquiatr.

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-The congenital muscular dystrophies (CMDs) are a group of genetically and clinically heterogeneous hereditary myopathies with preferentially autosomal recessive inheritance, that are characterized by congenital hypotonia, delayed motor development and early onset of progressive muscle weakness associated with dystrophic pattern on muscle biopsy. The clinical course is broadly variable and can comprise the involvement of the brain and eyes. From 1994, a great development in the knowledge of the molecular basis has occurred and the classification of CMDs has to be continuously up dated. In the last number of this journal, we presented the main clinical and diagnostic data concerning the different subtypes of CMD. In this second part of the review, we analyse the main reports from the literature concerning the pathogenesis and the therapeutic perspectives of the most common subtypes of CMD: MDC1A with merosin deficiency, collagen VI related CMDs (Ullrich and Bethlem), CMDs with abnormal glycosylation of alpha-dystroglycan (Fukuyama CMD, Muscleeye-brain disease, Walker Warburg syndrome, MDC1C, MDC1D), and rigid spine syndrome, another much rare subtype of CMDs not related with the dystrophin/glycoproteins/extracellular matrix complex.Key WorDs: congenital muscular dystrophy, MDC1A, collagen VI related disorders, glycosylation of alphadystroglycan, Fukuyama DMC, muscle-eye-brain (MeB) disease, Walker-Warburg syndrome, rigid spine syndrome. distrofia muscular congênita. parte ii: revisão da patogênese e perspectivas terapêuticas resumo -As distrofias musculares congênitas (DMCs) são miopatias hereditárias geralmente, porém não exclusivamente, de herança autossômica recessiva, que apresentam grande heterogeneidade genética e clínica. são caracterizadas por hipotonia muscular congênita, atraso do desenvolvimento motor e fraqueza muscular de início precoce associada a padrão distrófico na biópsia muscular. o quadro clínico, de gravidade variável, pode também incluir anormalidades oculares e do sistema nervoso central. A partir de 1994, os conhecimentos sobre genética e biologia molecular das DMCs progrediram rapidamente, sendo a classificação continuamente atualizada. os aspectos clínicos e diagnósticos dos principais subtipos de DMC foram apresentados no número anterior deste periódico, como primeira parte desta revisão. Nesta segunda parte apresentaremos os principais mecanismos patogênicos e as perspectivas terapêuticas dos subtipos mais comuns de DMC: DMC tipo 1A com deficiência de merosina, DMCs relacionadas com alterações do colágeno VI (Ullrich e Bethlem), e DMCs com anormalidades de glicosilação da alfa-distroglicana (DMC Fukuyama, DMC "Muscle-eye-brain" ou MeB, síndrome de Walker Warburg, DMC tipo 1C, DMC tipo 1D). A DMC com espinha rígida, mais rara e não relacionada com alterações do complexo distrofina-glicoproteínas associadas-matriz extracelular também será abordada quanto aos mesmos aspectos patogênicos e terapêuticos.PAlAVrAs-ChAVes: distrofia muscular congênita, merosina, colágeno VI, glicosila...

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Fukutin-related Protein Associates with the Sarcolemmal Dystrophin-Glycoprotein Complex

Cited by 36 publications

References 30 publications

Basal lamina strengthens cell membrane integrity via the laminin G domain-binding motif of α-dystroglycan

Basal lamina strengthens cell membrane integrity via the laminin G domain-binding motif of α-dystroglycan

Mouse fukutin deletion impairs dystroglycan processing and recapitulates muscular dystrophy

Congenital muscular dystrophy. Part II: a review of pathogenesis and therapeutic perspectives

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