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Caloric Restriction Combined with Immobilization as Translational Model for Sarcopenia Expressing Key-Pathways of Human Pathology
The prevalence of sarcopenia is increasing while it is often challenging, expensive and time-consuming to test the effectiveness of interventions against sarcopenia. Translational mouse models that adequately mimic underlying physiological pathways could accelerate research but are scarce. Here, we...
| Autores principales: | , , , , , , , , , , , , |
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| Formato: | Online Artículo Texto |
| Lenguaje: | English |
| Publicado: |
JKL International LLC
2023
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| Materias: | |
| Acceso en línea: | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10187708/ https://www.ncbi.nlm.nih.gov/pubmed/37191430 http://dx.doi.org/10.14336/AD.2022.1201 |
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| author | de Jong, Jelle C.B.C Caspers, Martien P.M Keijzer, Nanda Worms, Nicole Attema, Joline de Ruiter, Christa Lek, Serene Nieuwenhuizen, Arie G Keijer, Jaap Menke, Aswin L Kleemann, Robert Verschuren, Lars van den Hoek, Anita M |
| author_facet | de Jong, Jelle C.B.C Caspers, Martien P.M Keijzer, Nanda Worms, Nicole Attema, Joline de Ruiter, Christa Lek, Serene Nieuwenhuizen, Arie G Keijer, Jaap Menke, Aswin L Kleemann, Robert Verschuren, Lars van den Hoek, Anita M |
| author_sort | de Jong, Jelle C.B.C |
| collection | PubMed |
| description | The prevalence of sarcopenia is increasing while it is often challenging, expensive and time-consuming to test the effectiveness of interventions against sarcopenia. Translational mouse models that adequately mimic underlying physiological pathways could accelerate research but are scarce. Here, we investigated the translational value of three potential mouse models for sarcopenia, namely partial immobilized (to mimic sedentary lifestyle), caloric restricted (CR; to mimic malnutrition) and a combination (immobilized & CR) model. C57BL/6J mice were calorically restricted (-40%) and/or one hindleg was immobilized for two weeks to induce loss of muscle mass and function. Muscle parameters were compared to those of young control (4 months) and old reference mice (21 months). Transcriptome analysis of quadriceps muscle was performed to identify underlying pathways and were compared with those being expressed in aged human vastus lateralis muscle-biopsies using a meta-analysis of five different human studies. Caloric restriction induced overall loss of lean body mass (-15%, p<0.001), whereas immobilization decreased muscle strength (-28%, p<0.001) and muscle mass of hindleg muscles specifically (on average -25%, p<0.001). The proportion of slow myofibers increased with aging in mice (+5%, p<0.05), and this was not recapitulated by the CR and/or immobilization models. The diameter of fast myofibers decreased with aging (-7%, p<0.05), and this was mimicked by all models. Transcriptome analysis revealed that the combination of CR and immobilization recapitulated more pathways characteristic for human muscle-aging (73%) than naturally aged (21 months old) mice (45%). In conclusion, the combination model exhibits loss of both muscle mass (due to CR) and function (due to immobilization) and has a remarkable similarity with pathways underlying human sarcopenia. These findings underline that external factors such as sedentary behavior and malnutrition are key elements of a translational mouse model and favor the combination model as a rapid model for testing the treatments against sarcopenia. |
| format | Online Article Text |
| id | pubmed-10187708 |
| institution | National Center for Biotechnology Information |
| language | English |
| publishDate | 2023 |
| publisher | JKL International LLC |
| record_format | MEDLINE/PubMed |
| spelling | pubmed-101877082023-06-01 Caloric Restriction Combined with Immobilization as Translational Model for Sarcopenia Expressing Key-Pathways of Human Pathology de Jong, Jelle C.B.C Caspers, Martien P.M Keijzer, Nanda Worms, Nicole Attema, Joline de Ruiter, Christa Lek, Serene Nieuwenhuizen, Arie G Keijer, Jaap Menke, Aswin L Kleemann, Robert Verschuren, Lars van den Hoek, Anita M Aging Dis Original Article The prevalence of sarcopenia is increasing while it is often challenging, expensive and time-consuming to test the effectiveness of interventions against sarcopenia. Translational mouse models that adequately mimic underlying physiological pathways could accelerate research but are scarce. Here, we investigated the translational value of three potential mouse models for sarcopenia, namely partial immobilized (to mimic sedentary lifestyle), caloric restricted (CR; to mimic malnutrition) and a combination (immobilized & CR) model. C57BL/6J mice were calorically restricted (-40%) and/or one hindleg was immobilized for two weeks to induce loss of muscle mass and function. Muscle parameters were compared to those of young control (4 months) and old reference mice (21 months). Transcriptome analysis of quadriceps muscle was performed to identify underlying pathways and were compared with those being expressed in aged human vastus lateralis muscle-biopsies using a meta-analysis of five different human studies. Caloric restriction induced overall loss of lean body mass (-15%, p<0.001), whereas immobilization decreased muscle strength (-28%, p<0.001) and muscle mass of hindleg muscles specifically (on average -25%, p<0.001). The proportion of slow myofibers increased with aging in mice (+5%, p<0.05), and this was not recapitulated by the CR and/or immobilization models. The diameter of fast myofibers decreased with aging (-7%, p<0.05), and this was mimicked by all models. Transcriptome analysis revealed that the combination of CR and immobilization recapitulated more pathways characteristic for human muscle-aging (73%) than naturally aged (21 months old) mice (45%). In conclusion, the combination model exhibits loss of both muscle mass (due to CR) and function (due to immobilization) and has a remarkable similarity with pathways underlying human sarcopenia. These findings underline that external factors such as sedentary behavior and malnutrition are key elements of a translational mouse model and favor the combination model as a rapid model for testing the treatments against sarcopenia. JKL International LLC 2023-06-01 /pmc/articles/PMC10187708/ /pubmed/37191430 http://dx.doi.org/10.14336/AD.2022.1201 Text en Copyright: © 2023 Jong et al. https://creativecommons.org/licenses/by/2.0/this is an open access article distributed under the terms of the creative commons attribution license, which permits unrestricted use, distribution and reproduction in any medium provided that the original work is properly attributed. |
| spellingShingle | Original Article de Jong, Jelle C.B.C Caspers, Martien P.M Keijzer, Nanda Worms, Nicole Attema, Joline de Ruiter, Christa Lek, Serene Nieuwenhuizen, Arie G Keijer, Jaap Menke, Aswin L Kleemann, Robert Verschuren, Lars van den Hoek, Anita M Caloric Restriction Combined with Immobilization as Translational Model for Sarcopenia Expressing Key-Pathways of Human Pathology |
| title | Caloric Restriction Combined with Immobilization as Translational Model for Sarcopenia Expressing Key-Pathways of Human Pathology |
| title_full | Caloric Restriction Combined with Immobilization as Translational Model for Sarcopenia Expressing Key-Pathways of Human Pathology |
| title_fullStr | Caloric Restriction Combined with Immobilization as Translational Model for Sarcopenia Expressing Key-Pathways of Human Pathology |
| title_full_unstemmed | Caloric Restriction Combined with Immobilization as Translational Model for Sarcopenia Expressing Key-Pathways of Human Pathology |
| title_short | Caloric Restriction Combined with Immobilization as Translational Model for Sarcopenia Expressing Key-Pathways of Human Pathology |
| title_sort | caloric restriction combined with immobilization as translational model for sarcopenia expressing key-pathways of human pathology |
| topic | Original Article |
| url | https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10187708/ https://www.ncbi.nlm.nih.gov/pubmed/37191430 http://dx.doi.org/10.14336/AD.2022.1201 |
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