Easured using realtime PCR. B. Electron transport system abnormalities are more abundant in rats treated with the AMP buy AN 3199 kinase activator b-guanidinopropionic acid. Each Vastus lateralis skeletal muscle was stained for cytochrome C oxidase and succinate dehydrogenase every 60 microns for one millimeter. Regions of skeletal muscle fibers lacking COX activity 25033180 and hyper-reactive for SDH (the ETS abnormal phenotype) were counted. doi:10.1371/journal.pone.0059006.gDiscussionDespite the identification of the relationship between mitochondrial DNA deletion mutation accumulation and metabolic dysfunction, the specific mechanism(s) that originate and allow clonal accumulation of mtDNA deletion mutations with aging are enigmatic. The loss of electron transport activity in muscle fiber segments harboring intracellular clonal expansions of mtDNA deletion mutations suggests that many metabolic pathways, both anabolic and catabolic, would be affected by the inability to dispose of reducing equivalents generated by K162 cost respiration. Since many of the enzymes in the citric acid cycle are susceptible to product (NADH) inhibition, the electron flux would decrease, and the central hub of metabolism would be compromised. This would have a direct effect on mitochondrial ATP synthesis, and result in the requirement for the use of inefficient compensatory biochemtransport and oxidative phosphorylation. To test the hypothesis, we stained for activated AMP kinase and overexpression of the peroxisome proliferator activated receptor alpha (ppara) using immunohistochemistry with antibodies specific to these factors, their cofactors and their target genes. AMP kinase was phosphorylated on threonine-172, an indication of its activation, in ETS abnormal fibers. Moreover, a primary downstream target of activated AMP kinase, acetyl-coA carboxylase, was phosphorylated on serine 79, inhibiting fatty acid synthesis, an energy intensive process, consistent with an increase in AMP concentration (Figure 2). Immunohistochemical analysis of ppara, pgc-1a (peroxisome proliferator activated receptor gamma coactivator 1 alpha) andMitobiogenesis Drives mtDNA Deletion MutationsFigure 4. Model of positive feedback loop in ETS abnormal fibers. Signal transduction pathways detect mitochondrial dysfunction and drive transcriptional activation leading to up-regulation of mitochondrial DNA replication and subsequent deletion mutation accumulation. Genes in green were up-regulated in ETS abnormal fibers. Proteins in blue were found to be up-regulated by immunohistochemistry in ETS abnormal fibers. Proteins in purple were detected by both assays. wt: wild-type mitochondrial genomes, D deletion mutation containing mitochondrial genomes. doi:10.1371/journal.pone.0059006.gical pathways, depleting cellular ATP concentration. We tested whether the response to electron transport dysfunction induced by the expansion of mtDNA deletion mutations was non-adaptive and consistent with the proposed role for mitochondrial deletion mutations in sarcopenia. To better understand the molecular basis of sarcopenia, we profiled (Tables S1 and S2) muscle fibers containing intracellular expansions of deletion-mutation containing mitochondrial DNA. The profile obtained suggested that AMP kinase, the ubiquitous energy sensing molecule, was activated as was nuclear hormone signaling, a response indicating a program of mitochondrial biogenesis was activated, consistent with the observed mitochondrial dysfunction in deletio.Easured using realtime PCR. B. Electron transport system abnormalities are more abundant in rats treated with the AMP kinase activator b-guanidinopropionic acid. Each Vastus lateralis skeletal muscle was stained for cytochrome C oxidase and succinate dehydrogenase every 60 microns for one millimeter. Regions of skeletal muscle fibers lacking COX activity 25033180 and hyper-reactive for SDH (the ETS abnormal phenotype) were counted. doi:10.1371/journal.pone.0059006.gDiscussionDespite the identification of the relationship between mitochondrial DNA deletion mutation accumulation and metabolic dysfunction, the specific mechanism(s) that originate and allow clonal accumulation of mtDNA deletion mutations with aging are enigmatic. The loss of electron transport activity in muscle fiber segments harboring intracellular clonal expansions of mtDNA deletion mutations suggests that many metabolic pathways, both anabolic and catabolic, would be affected by the inability to dispose of reducing equivalents generated by respiration. Since many of the enzymes in the citric acid cycle are susceptible to product (NADH) inhibition, the electron flux would decrease, and the central hub of metabolism would be compromised. This would have a direct effect on mitochondrial ATP synthesis, and result in the requirement for the use of inefficient compensatory biochemtransport and oxidative phosphorylation. To test the hypothesis, we stained for activated AMP kinase and overexpression of the peroxisome proliferator activated receptor alpha (ppara) using immunohistochemistry with antibodies specific to these factors, their cofactors and their target genes. AMP kinase was phosphorylated on threonine-172, an indication of its activation, in ETS abnormal fibers. Moreover, a primary downstream target of activated AMP kinase, acetyl-coA carboxylase, was phosphorylated on serine 79, inhibiting fatty acid synthesis, an energy intensive process, consistent with an increase in AMP concentration (Figure 2). Immunohistochemical analysis of ppara, pgc-1a (peroxisome proliferator activated receptor gamma coactivator 1 alpha) andMitobiogenesis Drives mtDNA Deletion MutationsFigure 4. Model of positive feedback loop in ETS abnormal fibers. Signal transduction pathways detect mitochondrial dysfunction and drive transcriptional activation leading to up-regulation of mitochondrial DNA replication and subsequent deletion mutation accumulation. Genes in green were up-regulated in ETS abnormal fibers. Proteins in blue were found to be up-regulated by immunohistochemistry in ETS abnormal fibers. Proteins in purple were detected by both assays. wt: wild-type mitochondrial genomes, D deletion mutation containing mitochondrial genomes. doi:10.1371/journal.pone.0059006.gical pathways, depleting cellular ATP concentration. We tested whether the response to electron transport dysfunction induced by the expansion of mtDNA deletion mutations was non-adaptive and consistent with the proposed role for mitochondrial deletion mutations in sarcopenia. To better understand the molecular basis of sarcopenia, we profiled (Tables S1 and S2) muscle fibers containing intracellular expansions of deletion-mutation containing mitochondrial DNA. The profile obtained suggested that AMP kinase, the ubiquitous energy sensing molecule, was activated as was nuclear hormone signaling, a response indicating a program of mitochondrial biogenesis was activated, consistent with the observed mitochondrial dysfunction in deletio.