Sarcolemma resilience and skeletal muscle health require O-mannosylation of dystroglycan.

IF 5.3 2区医学 Q2 CELL BIOLOGY Skeletal Muscle Pub Date : 2025-01-09 DOI:10.1186/s13395-024-00370-2

Jeffrey M Hord, Sarah Burns, Tobias Willer, Matthew M Goddeeris, David Venzke, Kevin P Campbell

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Abstract

Background: Maintaining the connection between skeletal muscle fibers and the surrounding basement membrane is essential for muscle function. Dystroglycan (DG) serves as a basement membrane extracellular matrix (ECM) receptor in many cells, and is also expressed in the outward-facing membrane, or sarcolemma, of skeletal muscle fibers. DG is a transmembrane protein comprised of two subunits: alpha-DG (α-DG), which resides in the peripheral membrane, and beta-DG (β-DG), which spans the membrane to intracellular regions. Extensive post-translational processing and O-mannosylation are required for α-DG to bind ECM proteins, which is mediated by a glycan structure known as matriglycan. O-mannose glycan biosynthesis is initiated by the protein O-mannosyltransferase 1 (POMT1) and POMT2 enzyme complex and leads to three subtypes of glycans called core M1, M2, and M3. The lengthy core M3 is capped with matriglycan. Genetic defects in post-translational O-mannosylation of DG interfere with its receptor function and result in muscular dystrophy with central nervous system and skeletal muscle pathophysiology.

Methods: To evaluate how the loss of O-mannosylated DG in skeletal muscle affects the development and progression of myopathology, we generated and characterized mice in which the Pomt1 gene was specifically deleted in skeletal muscle (Pomt1^skm) to interfere with POMT1/2 enzyme activity. To investigate whether matriglycan is the primary core M glycan structure that provides the stabilizing link between the sarcolemma and ECM, we generated mice that retained cores M1, M2, and M3, but lacked matriglycan (conditional deletion of like-acetylglucosaminyltransferase 1; Large1^skm). Next, we restored Pomt1 using gene transfer via AAV2/9-MCK-mPOMT1 and determined the effect on Pomt1^skm pathophysiology.

Results: Our data showed that in Pomt1^skm mice O-mannosylated DG is required for sarcolemma resilience, remodeling of muscle fibers and muscle tissue, and neuromuscular function. Notably, we observed similar body size limitations, sarcolemma weakness, and neuromuscular weakness in Large1^skm mice that only lacked matriglycan. Furthermore, our data indicate that genetic rescue of Pomt1 in Pomt1^skm mice limits contraction-induced sarcolemma damage and skeletal muscle pathology.

Conclusions: Collectively, our data indicate that DG modification by Pomt1/2 results in core M3 capped with matriglycan, and that this is required to reinforce the sarcolemma and enable skeletal muscle health and neuromuscular strength.

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肌膜弹性和骨骼肌健康需要o -甘露糖醛基化。

背景：维持骨骼肌纤维与周围基底膜之间的连接对肌肉功能至关重要。歧合聚糖（DG）在许多细胞中作为基底膜细胞外基质（ECM）受体，也在骨骼肌纤维的外膜或肌膜中表达。DG是一种跨膜蛋白，由两个亚基组成：α-DG (α-DG)，位于外周膜上，β-DG （β-DG）横跨膜到细胞内区域。α-DG结合ECM蛋白需要广泛的翻译后加工和o -甘露糖基化，这是由一种被称为基质聚糖的聚糖结构介导的。o -甘露糖聚糖的生物合成由蛋白质o -甘露糖基转移酶1 （POMT1）和POMT2酶复合物启动，并导致三种亚型的聚糖，称为核心M1， M2和M3。长芯M3用矩阵can覆盖。DG翻译后o -甘露糖基化的遗传缺陷干扰其受体功能，导致中枢神经系统和骨骼肌病理生理的肌肉萎缩。方法：为了评估骨骼肌中o -甘露糖基化DG的缺失如何影响肌病的发生和进展，我们生成了骨骼肌中Pomt1基因（Pomt1skm）被特异性删除以干扰Pomt1 /2酶活性的小鼠并对其进行了表征。为了研究基质多糖是否是在肌膜和ECM之间提供稳定联系的主要核心M聚糖结构，我们产生了保留核心M1、M2和M3的小鼠，但缺乏基质多糖(条件缺失样乙酰氨基葡萄糖转移酶1；Large1skm)。接下来，我们通过AAV2/9-MCK-mPOMT1基因转移恢复Pomt1，并确定对Pomt1skm病理生理的影响。结果：我们的数据显示，Pomt1skm小鼠的肌膜弹性、肌肉纤维和肌肉组织的重塑以及神经肌肉功能都需要o -甘露糖基化DG。值得注意的是，我们在只缺乏基质蛋白的大体型小鼠中观察到类似的体型限制、肌膜无力和神经肌肉无力。此外，我们的数据表明，Pomt1在Pomt1skm小鼠中的遗传拯救限制了收缩诱导的肌膜损伤和骨骼肌病理。结论：总的来说，我们的数据表明，Pomt1/2修饰DG导致核心M3被基质覆盖，这是增强肌膜、保持骨骼肌健康和神经肌肉力量所必需的。

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来源期刊

Skeletal Muscle CELL BIOLOGY-

CiteScore

9.10

自引率

0.00%

发文量

审稿时长

12 weeks

期刊介绍： The only open access journal in its field, Skeletal Muscle publishes novel, cutting-edge research and technological advancements that investigate the molecular mechanisms underlying the biology of skeletal muscle. Reflecting the breadth of research in this area, the journal welcomes manuscripts about the development, metabolism, the regulation of mass and function, aging, degeneration, dystrophy and regeneration of skeletal muscle, with an emphasis on understanding adult skeletal muscle, its maintenance, and its interactions with non-muscle cell types and regulatory modulators. Main areas of interest include: -differentiation of skeletal muscle- atrophy and hypertrophy of skeletal muscle- aging of skeletal muscle- regeneration and degeneration of skeletal muscle- biology of satellite and satellite-like cells- dystrophic degeneration of skeletal muscle- energy and glucose homeostasis in skeletal muscle- non-dystrophic genetic diseases of skeletal muscle, such as Spinal Muscular Atrophy and myopathies- maintenance of neuromuscular junctions- roles of ryanodine receptors and calcium signaling in skeletal muscle- roles of nuclear receptors in skeletal muscle- roles of GPCRs and GPCR signaling in skeletal muscle- other relevant aspects of skeletal muscle biology. In addition, articles on translational clinical studies that address molecular and cellular mechanisms of skeletal muscle will be published. Case reports are also encouraged for submission. Skeletal Muscle reflects the breadth of research on skeletal muscle and bridges gaps between diverse areas of science for example cardiac cell biology and neurobiology, which share common features with respect to cell differentiation, excitatory membranes, cell-cell communication, and maintenance. Suitable articles are model and mechanism-driven, and apply statistical principles where appropriate; purely descriptive studies are of lesser interest.