Spatiotemporal analysis of dystrophin expression during muscle repair.

IF 4.4 2区医学 Q2 CELL BIOLOGY

Skeletal Muscle Pub Date : 2025-10-02 DOI:10.1186/s13395-025-00398-y

John C W Hildyard, Liberty E Roskrow, Dominic J Wells, Richard J Piercy

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引用次数: 0

Abstract

Background: Dystrophin mRNA is produced from a very large genetic locus and transcription of a single mRNA requires approximately 16 h. This prolonged interval between initiation and completion results in unusual transcriptional behaviour: in skeletal muscle, myonuclei express dystrophin continuously and robustly, yet degrade mature transcripts shortly after completion. Consequently, most dystrophin mRNA is nascent, not mature. This implies expression is principally controlled post-transcriptionally, a mechanism that circumvents transcriptional delay, allowing rapid responses to change in demand. Dystrophin protein is however highly stable, with slow turnover: in healthy muscle, despite constant production of dystrophin mRNA, demand is low and the need for responsive expression is minimal. We reasoned this system instead exists to control dystrophin expression during rare periods of elevated but changing demand, such as during muscle development or repair, when newly formed fibres must establish sarcolemmal dystrophin rapidly.

Methods: We assessed dystrophin mRNA (both nascent and mature) and dystrophin protein in regenerating skeletal muscle following injury, using a combination of qPCR, immunofluorescence and in-situ hybridisation to determine timing and location of expression during the repair process.

Results: We reveal a complex program that suggests control at multiple levels: nascent transcription is detectable even prior to overt myoblast fusion, suggesting cells 'pay in advance' to minimise subsequent delay. During myotube differentiation and maturation, when sarcolemmal demands are high, initiation increases only modestly while mature transcript stability increases markedly to generate high numbers of mature dystrophin transcripts, a state that persists until repair is complete, when oversupply and degradation resumes.

Conclusion: Our data demonstrate that dystrophin mRNA is indeed chiefly controlled by turnover, not initiation: degradation consequently represents a potential therapeutic target for maximising efficacy of even modest dystrophin restoration.

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肌肉修复过程中肌营养不良蛋白表达的时空分析。

背景：肌营养不良蛋白mRNA是由一个非常大的遗传位点产生的，单个mRNA的转录大约需要16小时。这种起始和完成之间的长时间间隔导致了不寻常的转录行为：在骨骼肌中，肌核持续而稳定地表达肌营养不良蛋白，但在完成后不久就降解成熟的转录物。因此，大多数肌营养不良蛋白mRNA是新生的，而不是成熟的。这意味着表达主要受转录后控制，这是一种规避转录延迟的机制，允许快速响应需求变化。然而，肌营养不良蛋白是高度稳定的，周转缓慢：在健康肌肉中，尽管不断产生肌营养不良蛋白mRNA，但需求量很低，对反应性表达的需求最小。我们推断，该系统的存在是为了在需求升高但不断变化的罕见时期控制肌营养不良蛋白的表达，例如在肌肉发育或修复期间，当新形成的纤维必须迅速建立肌上皮营养不良蛋白时。方法：采用qPCR、免疫荧光和原位杂交相结合的方法，评估损伤后再生骨骼肌中肌营养不良蛋白mRNA（包括新生肌营养不良蛋白和成熟肌营养不良蛋白）和肌营养不良蛋白的表达，以确定修复过程中的表达时间和位置。结果：我们揭示了一个复杂的程序，表明在多个水平上进行控制：新生转录甚至在明显的成肌细胞融合之前就可以检测到，这表明细胞“提前支付”以尽量减少随后的延迟。在肌管分化和成熟过程中，当肌层的需求很高时，起始量仅适度增加，而成熟转录物的稳定性显著增加，产生大量成熟的肌营养不良蛋白转录物，这种状态持续到修复完成，供过于求和降解恢复。结论：我们的数据表明，肌营养不良蛋白mRNA确实主要受周转控制，而不是起始控制：因此，降解代表了一个潜在的治疗靶点，即使是适度的肌营养不良蛋白恢复也能最大限度地提高疗效。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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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.