The transcriptional coactivator PGC-1α is dispensable for chronic overload-induced skeletal muscle hypertrophy and metabolic remodeling

Pérez-Schindler, Joaquín; Summermatter, Serge; Santos, Gesa; Zorzato, Francesco; Handschin, Christoph

doi:10.1073/pnas.1312039110

Cited by 45 publications

(50 citation statements)

References 43 publications

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“…In the same study, we demonstrated that PGC-1α4 is sufficient to induce skeletal muscle hypertrophy. A different group has reported that mice lacking expression of all (known) PGC-1α proteins in skeletal muscle still undergo hypertrophy induced by the synergistic ablation model [63]. We cannot rule out either the existence of additional isoforms that might account for those particular effects or compensatory mechanisms due to the disruption of the Pgc-1α gene since the embryonic state.…”

Section: Challenges and Perspectivesmentioning

confidence: 85%

The hitchhiker’s guide to PGC-1α isoform structure and biological functions

2015

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Proteins of the peroxisome proliferator-activated receptor γ (PPARγ) coactivator 1 (PGC-1) family of transcriptional coactivators coordinate physiological adaptations in many tissues, usually in response to demands for higher nutrient and energy supply. Of the founding members of the family, PGC-1α (also known as PPARGC1A) is the most highly regulated gene, using multiple promoters and alternative splicing to produce a growing number of coactivator variants. PGC-1α promoters are selectively active in distinct tissues in response to specific stimuli. To date, more than ten novel PGC-1α isoforms have been reported to be expressed from a novel promoter (PGC-1α-b, PGC-1α-c), to undergo alternative splicing (NT-PGC-1α) or both (PGC-1α2, PGC-1α3, PGC-1α4). The resulting proteins display differential regulation and tissue distribution and, most importantly, exert specific biological functions. In this review we discuss the structural and functional characteristics of the novel PGC-1α isoforms, aiming to provide an integrative view of this constantly expanding system of transcriptional coactivators.

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Section: Challenges and Perspectivesmentioning

confidence: 85%

The hitchhiker’s guide to PGC-1α isoform structure and biological functions

2015

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“…Total protein was recovered from quadriceps muscles as described in Perez‐Schindler, Summermatter, Santos, Zorzato, and Handschin (2013). Equal amounts of protein were migrated on mini‐TGX 4‐20% stain free precast gel (Bio‐Rad, 4568096) and labeled with the in‐gel trihalo compounds under UV for 1 min.…”

Section: Methodsmentioning

confidence: 99%

PGC‐1α affects aging‐related changes in muscle and motor function by modulating specific exercise‐mediated changes in old mice

et al. 2017

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SummaryThe age‐related impairment in muscle function results in a drastic decline in motor coordination and mobility in elderly individuals. Regular physical activity is the only efficient intervention to prevent and treat this age‐associated degeneration. However, the mechanisms that underlie the therapeutic effect of exercise in this context remain unclear. We assessed whether endurance exercise training in old age is sufficient to affect muscle and motor function. Moreover, as muscle peroxisome proliferator‐activated receptor γ coactivator 1α (PGC‐1α) is a key regulatory hub in endurance exercise adaptation with decreased expression in old muscle, we studied the involvement of PGC‐1α in the therapeutic effect of exercise in aging. Intriguingly, PGC‐1α muscle‐specific knockout and overexpression, respectively, precipitated and alleviated specific aspects of aging‐related deterioration of muscle function in old mice, while other muscle dysfunctions remained unchanged upon PGC‐1α modulation. Surprisingly, we discovered that muscle PGC‐1α was not only involved in improving muscle endurance and mitochondrial remodeling, but also phenocopied endurance exercise training in advanced age by contributing to maintaining balance and motor coordination in old animals. Our data therefore suggest that the benefits of exercise, even when performed at old age, extend beyond skeletal muscle and are at least in part mediated by PGC‐1α.

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“…The binding peak regions were aligned with orthologous regions from 6 other mammalian species-human (hg18), rhesus macaque (rheMac2), dog (canFam2), horse (equCab1), cow (bosTau3), and opossum (monDom4)-using TCoffee (18). A collection of 190 mammalian regulatory motifs (position weight matrices [WMs]) representing the binding specificities of approximate 350 mouse TFs (in many cases, sequence specificities of multiple closely related TFs were represented with the same WM) were downloaded from the SwissRegulon website (19). TFBSs for all known motifs were predicted using the MotEvo algorithm (20) on the alignments of all 7,512 peak sequences.…”

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confidence: 99%

“…Subsequently, probes were classified as expressed or nonexpressed by using the "Mclust" R package (22), and after removal of nonexpressed probes, the intensity values were quantile normalized across all samples. Using mapping of the probes to the UCSC collection of mouse mRNAs, probes were then associated with a comprehensive collection of mouse promoters available from the SwissRegulon database (19). The log 2 expression level of a given promoter was calculated as the weighted average of the expression levels of all probes associated with it.…”

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confidence: 99%

Transcriptional Network Analysis in Muscle Reveals AP-1 as a Partner of PGC-1α in the Regulation of the Hypoxic Gene Program

Barešić

Salatino

Kupr

et al. 2014

Molecular and Cellular Biology

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Skeletal muscle tissue shows an extraordinary cellular plasticity, but the underlying molecular mechanisms are still poorly understood. Here, we use a combination of experimental and computational approaches to unravel the complex transcriptional network of muscle cell plasticity centered on the peroxisome proliferator-activated receptor ␥ coactivator 1␣ (PGC-1␣), a regulatory nexus in endurance training adaptation. By integrating data on genome-wide binding of PGC-1␣ and gene expression upon PGC-1␣ overexpression with comprehensive computational prediction of transcription factor binding sites (TFBSs), we uncover a hitherto-underestimated number of transcription factor partners involved in mediating PGC-1␣ action. In particular, principal component analysis of TFBSs at PGC-1␣ binding regions predicts that, besides the well-known role of the estrogenrelated receptor ␣ (ERR␣), the activator protein 1 complex (AP-1) plays a major role in regulating the PGC-1␣-controlled gene program of the hypoxia response. Our findings thus reveal the complex transcriptional network of muscle cell plasticity controlled by PGC-1␣.

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The transcriptional coactivator PGC-1α is dispensable for chronic overload-induced skeletal muscle hypertrophy and metabolic remodeling

Cited by 45 publications

References 43 publications

The hitchhiker’s guide to PGC-1α isoform structure and biological functions

The hitchhiker’s guide to PGC-1α isoform structure and biological functions

PGC‐1α affects aging‐related changes in muscle and motor function by modulating specific exercise‐mediated changes in old mice

Transcriptional Network Analysis in Muscle Reveals AP-1 as a Partner of PGC-1α in the Regulation of the Hypoxic Gene Program

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