Nikolay Oskolkov, Malgorzata Santel, Hemang M Parikh, Ola Ekström, Gray J Camp, Eri Miyamoto-Mikami, Kristoffer Ström, Bilal Ahmad Mir, Dmytro Kryvokhyzha, Mikko Lehtovirta, Hiroyuki Kobayashi, Ryo Kakigi, Hisashi Naito, Karl-Fredrik Eriksson, Björn Nystedt, Noriyuki Fuku, Barbara Treutlein, Svante Pääbo, Ola Hansson
{"title":"基于RNA测序数据的高通量肌纤维分型。","authors":"Nikolay Oskolkov, Malgorzata Santel, Hemang M Parikh, Ola Ekström, Gray J Camp, Eri Miyamoto-Mikami, Kristoffer Ström, Bilal Ahmad Mir, Dmytro Kryvokhyzha, Mikko Lehtovirta, Hiroyuki Kobayashi, Ryo Kakigi, Hisashi Naito, Karl-Fredrik Eriksson, Björn Nystedt, Noriyuki Fuku, Barbara Treutlein, Svante Pääbo, Ola Hansson","doi":"10.1186/s13395-022-00299-4","DOIUrl":null,"url":null,"abstract":"<p><strong>Background: </strong>Skeletal muscle fiber type distribution has implications for human health, muscle function, and performance. This knowledge has been gathered using labor-intensive and costly methodology that limited these studies. Here, we present a method based on muscle tissue RNA sequencing data (totRNAseq) to estimate the distribution of skeletal muscle fiber types from frozen human samples, allowing for a larger number of individuals to be tested.</p><p><strong>Methods: </strong>By using single-nuclei RNA sequencing (snRNAseq) data as a reference, cluster expression signatures were produced by averaging gene expression of cluster gene markers and then applying these to totRNAseq data and inferring muscle fiber nuclei type via linear matrix decomposition. This estimate was then compared with fiber type distribution measured by ATPase staining or myosin heavy chain protein isoform distribution of 62 muscle samples in two independent cohorts (n = 39 and 22).</p><p><strong>Results: </strong>The correlation between the sequencing-based method and the other two were r<sub>ATPas</sub> = 0.44 [0.13-0.67], [95% CI], and r<sub>myosin</sub> = 0.83 [0.61-0.93], with p = 5.70 × 10<sup>-3</sup> and 2.00 × 10<sup>-6</sup>, respectively. The deconvolution inference of fiber type composition was accurate even for very low totRNAseq sequencing depths, i.e., down to an average of ~ 10,000 paired-end reads.</p><p><strong>Conclusions: </strong>This new method ( https://github.com/OlaHanssonLab/PredictFiberType ) consequently allows for measurement of fiber type distribution of a larger number of samples using totRNAseq in a cost and labor-efficient way. It is now feasible to study the association between fiber type distribution and e.g. health outcomes in large well-powered studies.</p>","PeriodicalId":21747,"journal":{"name":"Skeletal Muscle","volume":null,"pages":null},"PeriodicalIF":5.3000,"publicationDate":"2022-07-02","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9250227/pdf/","citationCount":"5","resultStr":"{\"title\":\"High-throughput muscle fiber typing from RNA sequencing data.\",\"authors\":\"Nikolay Oskolkov, Malgorzata Santel, Hemang M Parikh, Ola Ekström, Gray J Camp, Eri Miyamoto-Mikami, Kristoffer Ström, Bilal Ahmad Mir, Dmytro Kryvokhyzha, Mikko Lehtovirta, Hiroyuki Kobayashi, Ryo Kakigi, Hisashi Naito, Karl-Fredrik Eriksson, Björn Nystedt, Noriyuki Fuku, Barbara Treutlein, Svante Pääbo, Ola Hansson\",\"doi\":\"10.1186/s13395-022-00299-4\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>Background: </strong>Skeletal muscle fiber type distribution has implications for human health, muscle function, and performance. This knowledge has been gathered using labor-intensive and costly methodology that limited these studies. Here, we present a method based on muscle tissue RNA sequencing data (totRNAseq) to estimate the distribution of skeletal muscle fiber types from frozen human samples, allowing for a larger number of individuals to be tested.</p><p><strong>Methods: </strong>By using single-nuclei RNA sequencing (snRNAseq) data as a reference, cluster expression signatures were produced by averaging gene expression of cluster gene markers and then applying these to totRNAseq data and inferring muscle fiber nuclei type via linear matrix decomposition. This estimate was then compared with fiber type distribution measured by ATPase staining or myosin heavy chain protein isoform distribution of 62 muscle samples in two independent cohorts (n = 39 and 22).</p><p><strong>Results: </strong>The correlation between the sequencing-based method and the other two were r<sub>ATPas</sub> = 0.44 [0.13-0.67], [95% CI], and r<sub>myosin</sub> = 0.83 [0.61-0.93], with p = 5.70 × 10<sup>-3</sup> and 2.00 × 10<sup>-6</sup>, respectively. The deconvolution inference of fiber type composition was accurate even for very low totRNAseq sequencing depths, i.e., down to an average of ~ 10,000 paired-end reads.</p><p><strong>Conclusions: </strong>This new method ( https://github.com/OlaHanssonLab/PredictFiberType ) consequently allows for measurement of fiber type distribution of a larger number of samples using totRNAseq in a cost and labor-efficient way. 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High-throughput muscle fiber typing from RNA sequencing data.
Background: Skeletal muscle fiber type distribution has implications for human health, muscle function, and performance. This knowledge has been gathered using labor-intensive and costly methodology that limited these studies. Here, we present a method based on muscle tissue RNA sequencing data (totRNAseq) to estimate the distribution of skeletal muscle fiber types from frozen human samples, allowing for a larger number of individuals to be tested.
Methods: By using single-nuclei RNA sequencing (snRNAseq) data as a reference, cluster expression signatures were produced by averaging gene expression of cluster gene markers and then applying these to totRNAseq data and inferring muscle fiber nuclei type via linear matrix decomposition. This estimate was then compared with fiber type distribution measured by ATPase staining or myosin heavy chain protein isoform distribution of 62 muscle samples in two independent cohorts (n = 39 and 22).
Results: The correlation between the sequencing-based method and the other two were rATPas = 0.44 [0.13-0.67], [95% CI], and rmyosin = 0.83 [0.61-0.93], with p = 5.70 × 10-3 and 2.00 × 10-6, respectively. The deconvolution inference of fiber type composition was accurate even for very low totRNAseq sequencing depths, i.e., down to an average of ~ 10,000 paired-end reads.
Conclusions: This new method ( https://github.com/OlaHanssonLab/PredictFiberType ) consequently allows for measurement of fiber type distribution of a larger number of samples using totRNAseq in a cost and labor-efficient way. It is now feasible to study the association between fiber type distribution and e.g. health outcomes in large well-powered studies.
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.
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