{"title":"消融UCP-1+细胞影响肌肉再生中的FAP动力学。","authors":"Jacob C Parson, Gretchen A Meyer","doi":"10.1152/ajpcell.00249.2025","DOIUrl":null,"url":null,"abstract":"<p><p>Uncoupling protein-1 (UCP-1+) cells found in brown adipose tissue and subtypes of white (a.k.a. beige) adipose tissue have been a focus of intensive investigation for their role in energy metabolism and are emerging as potential endocrine regulators of physiology. More recently, UCP-1+ subpopulations have also been found in skeletal muscle fibro-adipogenic progenitors (FAPs), which play an important role in regeneration. Both UCP-1+ adipocytes and FAPs secrete promyogenic cytokines further supporting their potential for proregenerative signaling. To investigate whether signaling from UCP-1+ cells does indeed promote regeneration, we examined injury-induced muscle regeneration in a mouse model with constitutive UCP-1+ cell ablation (UCP1-DTA) at three time points: early [3 and 7 days post injury (dpi)], intermediate (14 dpi), and late (21 dpi). We hypothesized that without UCP-1+ cells, muscle regeneration would be impaired at all time points. At 3 and 7 dpi, we found significantly reduced numbers of FAPs in male UCP1-DTA mice, but with no accompanying changes in muscle-derived stem (satellite) cells or immune cells. However, at 14 dpi, we observed significantly higher numbers of FAP in male UCP1-DTA mice and evidence of ongoing early-phase regeneration, including significantly increased histological and gene expression of early regenerative markers and significantly smaller regenerating fibers. However, these changes were not associated with fibrosis and fatty infiltration typical of impaired regeneration, nor were differences in contractile force recovery observed between genotypes. These findings suggest that UCP-1+ cells (adipocytes or FAPs) may regulate FAP dynamics in early regeneration, but without major effects on the recovery of structure and function.<b>NEW & NOTEWORTHY</b> Accumulating evidence suggests that UCP-1+ brown and beige adipose tissue impact muscle metabolism and that UCP-1+ FAPs impact atrophy, fibrosis, and fatty infiltration in a chronic injury model. This is the first report to examine muscle regeneration in the absence of brown fat and to explore the loss (rather than the addition) of UCP-1+ FAPs. We find that loss of both UCP-1+ adipocytes and FAPs only mildly impacts muscle regeneration, without disturbance of structural or functional recovery.</p>","PeriodicalId":7585,"journal":{"name":"American journal of physiology. Cell physiology","volume":" ","pages":"C754-C767"},"PeriodicalIF":4.7000,"publicationDate":"2025-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC12359850/pdf/","citationCount":"0","resultStr":"{\"title\":\"Ablation of UCP-1+ cells impacts FAP dynamics in muscle regeneration.\",\"authors\":\"Jacob C Parson, Gretchen A Meyer\",\"doi\":\"10.1152/ajpcell.00249.2025\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Uncoupling protein-1 (UCP-1+) cells found in brown adipose tissue and subtypes of white (a.k.a. beige) adipose tissue have been a focus of intensive investigation for their role in energy metabolism and are emerging as potential endocrine regulators of physiology. More recently, UCP-1+ subpopulations have also been found in skeletal muscle fibro-adipogenic progenitors (FAPs), which play an important role in regeneration. Both UCP-1+ adipocytes and FAPs secrete promyogenic cytokines further supporting their potential for proregenerative signaling. To investigate whether signaling from UCP-1+ cells does indeed promote regeneration, we examined injury-induced muscle regeneration in a mouse model with constitutive UCP-1+ cell ablation (UCP1-DTA) at three time points: early [3 and 7 days post injury (dpi)], intermediate (14 dpi), and late (21 dpi). We hypothesized that without UCP-1+ cells, muscle regeneration would be impaired at all time points. At 3 and 7 dpi, we found significantly reduced numbers of FAPs in male UCP1-DTA mice, but with no accompanying changes in muscle-derived stem (satellite) cells or immune cells. However, at 14 dpi, we observed significantly higher numbers of FAP in male UCP1-DTA mice and evidence of ongoing early-phase regeneration, including significantly increased histological and gene expression of early regenerative markers and significantly smaller regenerating fibers. However, these changes were not associated with fibrosis and fatty infiltration typical of impaired regeneration, nor were differences in contractile force recovery observed between genotypes. These findings suggest that UCP-1+ cells (adipocytes or FAPs) may regulate FAP dynamics in early regeneration, but without major effects on the recovery of structure and function.<b>NEW & NOTEWORTHY</b> Accumulating evidence suggests that UCP-1+ brown and beige adipose tissue impact muscle metabolism and that UCP-1+ FAPs impact atrophy, fibrosis, and fatty infiltration in a chronic injury model. This is the first report to examine muscle regeneration in the absence of brown fat and to explore the loss (rather than the addition) of UCP-1+ FAPs. We find that loss of both UCP-1+ adipocytes and FAPs only mildly impacts muscle regeneration, without disturbance of structural or functional recovery.</p>\",\"PeriodicalId\":7585,\"journal\":{\"name\":\"American journal of physiology. 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Cell physiology","FirstCategoryId":"99","ListUrlMain":"https://doi.org/10.1152/ajpcell.00249.2025","RegionNum":2,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"2025/7/28 0:00:00","PubModel":"Epub","JCR":"Q2","JCRName":"CELL BIOLOGY","Score":null,"Total":0}
Ablation of UCP-1+ cells impacts FAP dynamics in muscle regeneration.
Uncoupling protein-1 (UCP-1+) cells found in brown adipose tissue and subtypes of white (a.k.a. beige) adipose tissue have been a focus of intensive investigation for their role in energy metabolism and are emerging as potential endocrine regulators of physiology. More recently, UCP-1+ subpopulations have also been found in skeletal muscle fibro-adipogenic progenitors (FAPs), which play an important role in regeneration. Both UCP-1+ adipocytes and FAPs secrete promyogenic cytokines further supporting their potential for proregenerative signaling. To investigate whether signaling from UCP-1+ cells does indeed promote regeneration, we examined injury-induced muscle regeneration in a mouse model with constitutive UCP-1+ cell ablation (UCP1-DTA) at three time points: early [3 and 7 days post injury (dpi)], intermediate (14 dpi), and late (21 dpi). We hypothesized that without UCP-1+ cells, muscle regeneration would be impaired at all time points. At 3 and 7 dpi, we found significantly reduced numbers of FAPs in male UCP1-DTA mice, but with no accompanying changes in muscle-derived stem (satellite) cells or immune cells. However, at 14 dpi, we observed significantly higher numbers of FAP in male UCP1-DTA mice and evidence of ongoing early-phase regeneration, including significantly increased histological and gene expression of early regenerative markers and significantly smaller regenerating fibers. However, these changes were not associated with fibrosis and fatty infiltration typical of impaired regeneration, nor were differences in contractile force recovery observed between genotypes. These findings suggest that UCP-1+ cells (adipocytes or FAPs) may regulate FAP dynamics in early regeneration, but without major effects on the recovery of structure and function.NEW & NOTEWORTHY Accumulating evidence suggests that UCP-1+ brown and beige adipose tissue impact muscle metabolism and that UCP-1+ FAPs impact atrophy, fibrosis, and fatty infiltration in a chronic injury model. This is the first report to examine muscle regeneration in the absence of brown fat and to explore the loss (rather than the addition) of UCP-1+ FAPs. We find that loss of both UCP-1+ adipocytes and FAPs only mildly impacts muscle regeneration, without disturbance of structural or functional recovery.
期刊介绍:
The American Journal of Physiology-Cell Physiology is dedicated to innovative approaches to the study of cell and molecular physiology. Contributions that use cellular and molecular approaches to shed light on mechanisms of physiological control at higher levels of organization also appear regularly. Manuscripts dealing with the structure and function of cell membranes, contractile systems, cellular organelles, and membrane channels, transporters, and pumps are encouraged. Studies dealing with integrated regulation of cellular function, including mechanisms of signal transduction, development, gene expression, cell-to-cell interactions, and the cell physiology of pathophysiological states, are also eagerly sought. Interdisciplinary studies that apply the approaches of biochemistry, biophysics, molecular biology, morphology, and immunology to the determination of new principles in cell physiology are especially welcome.
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