肌强直性营养不良疾病严重程度的剪接生物标志物。

Splicing biomarkers of disease severity in myotonic dystrophy.

机构信息

Department of Neurology, University of Rochester Medical Center, Rochester, NY; Center for Neural Development and Disease, University of Rochester Medical Center, Rochester, NY.

出版信息

Ann Neurol. 2013 Dec;74(6):862-72. doi: 10.1002/ana.23992.

DOI:10.1002/ana.23992

PMID:23929620

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4099006/

Abstract

OBJECTIVE

To develop RNA splicing biomarkers of disease severity and therapeutic response in myotonic dystrophy type 1 (DM1) and type 2 (DM2).

METHODS

In a discovery cohort, we used microarrays to perform global analysis of alternative splicing in DM1 and DM2. The newly identified splicing changes were combined with previous data to create a panel of 50 putative splicing defects. In a validation cohort of 50 DM1 subjects, we measured the strength of ankle dorsiflexion (ADF) and then obtained a needle biopsy of tibialis anterior (TA) to analyze splice events in muscle RNA. The specificity of DM-associated splicing defects was assessed in disease controls. The CTG expansion size in muscle tissue was determined by Southern blot. The reversibility of splicing defects was assessed in transgenic mice by using antisense oligonucleotides to reduce levels of toxic RNA.

RESULTS

Forty-two splicing defects were confirmed in TA muscle in the validation cohort. Among these, 20 events showed graded changes that correlated with ADF weakness. Five other splice events were strongly affected in DM1 subjects with normal ADF strength. Comparison to disease controls and mouse models indicated that splicing changes were DM-specific, mainly attributable to MBNL1 sequestration, and reversible in mice by targeted knockdown of toxic RNA. Splicing defects and weakness were not correlated with CTG expansion size in muscle tissue.

INTERPRETATION

Alternative splicing changes in skeletal muscle may serve as biomarkers of disease severity and therapeutic response in myotonic dystrophy.

摘要

目的

在肌强直性营养不良 1 型（DM1）和 2 型（DM2）中开发 RNA 剪接生物标志物，以预测疾病严重程度和治疗反应。

方法

在一个发现队列中，我们使用微阵列对 DM1 和 DM2 的剪接进行了全局分析。将新鉴定的剪接变化与之前的数据相结合，创建了一个由 50 个潜在剪接缺陷组成的面板。在 50 名 DM1 受试者的验证队列中，我们测量了踝关节背屈（ADF）的强度，然后对胫骨前肌（TA）进行了针吸活检，以分析肌肉 RNA 中的剪接事件。在疾病对照中评估 DM 相关剪接缺陷的特异性。通过 Southern blot 确定肌肉组织中的 CTG 扩展大小。通过使用反义寡核苷酸降低毒性 RNA 的水平，在转基因小鼠中评估剪接缺陷的可逆性。

结果

在验证队列中，TA 肌肉中证实了 42 个剪接缺陷。其中，20 个事件显示出与 ADF 无力相关的分级变化。DM1 受试者中，5 个其他剪接事件在 ADF 强度正常的情况下受到强烈影响。与疾病对照和小鼠模型的比较表明，剪接变化是 DM 特异性的，主要归因于 MBNL1 隔离，并且在小鼠中通过靶向敲低毒性 RNA 是可逆的。剪接缺陷和无力与肌肉组织中的 CTG 扩展大小无关。

结论

骨骼肌中的可变剪接变化可能作为肌强直性营养不良疾病严重程度和治疗反应的生物标志物。

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