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Translating Muscle RNAseq Into the Clinic for the Diagnosis of Muscle Diseases
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Translating Muscle RNAseq Into the Clinic for the Diagnosis of Muscle Diseases
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Journal Article
Translating Muscle RNAseq Into the Clinic for the Diagnosis of Muscle Diseases
2025
Overview
ABSTRACT
Objective
Approximately half of patients with hereditary myopathies remain without a definitive genetic diagnosis after DNA next‐generation sequencing (NGS). Here, we implemented transcriptome analysis of muscle biopsies as a complementary diagnostic tool for patients with muscle disease but no definitive genetic diagnosis after exome sequencing.
Methods
In total, 70 undiagnosed cases with suspected genetic muscular dystrophies or congenital myopathies were included in the study. Muscle RNAseq comprised the analysis of aberrant splicing, aberrant expression, and monoallelic expression. In addition, existing NGS data or variant calling from RNAseq were reanalyzed, and genome sequencing was performed in selected cases. Four aberrant splicing open‐source tools were compared and assessed.
Results
RNAseq established a diagnosis in 10/70 patients (14.3%) by identifying aberrant transcripts produced by single nucleotide variants (7/10) or copy number variants (3/10). Reanalysis of NGS data allowed the diagnosis in 9/70 individuals (12.9%). Based on this cohort, FRASER was the tool that reported more splicing outlier events per sample while showing the highest accuracy (81.26%).
Conclusions
We demonstrate the utility of RNAseq in identifying causative variants in muscle diseases. Evaluation of four aberrant splicing tools allowed efficient identification of most pathogenic splicing events, obtaining a manageable number of candidate events for manual inspection, demonstrating feasibility for translation into a clinical setting. We also show how the integration of omic technologies reduces the turnaround time to identify causative variants.
Publisher
John Wiley & Sons, Inc,John Wiley and Sons Inc,Wiley
Subject
/ Adult
/ Biopsy
/ Child
/ Disease
/ Female
/ Genomes
/ Genomics
/ High-Throughput Nucleotide Sequencing
/ Humans
/ Kinases
/ Male
/ Muscle, Skeletal - metabolism
/ Muscle, Skeletal - pathology
/ Muscular Diseases - diagnosis
/ Muscular Diseases - genetics
/ Muscular Dystrophies - diagnosis
/ Muscular Dystrophies - genetics
/ Proteins
