Project description:Hypoxia inducible factors (HIF), specifically, HIF1A, is continuously synthesized and degraded rapidly in normoxia. During hypoxia, HIF1A stabilization limits oxygen utilization and inhibits protein synthesis, but there are limited data on HIF1A function(s) in normoxia. Given the high energy needs of contraction and maintenance of the large protein mass in skeletal muscle, we determined HIF1A function in normoxia in differentiated murine myotubes with loss/gain of function and skeletal muscle from mice with Hif1afl/f or post-natal muscle-specific deletion (Hif1amsd). Integration of transcriptomics and proteomics in myotubes and muscle from mice with Hif1amsd showed enrichment of mitochondrial/metabolic regulatory molecules including TCA cycle and electron transport chain components. Mitochondrial oxidative functions and ATP content were higher with less free radical generation with Hif1a deletion. Untargeted metabolomics showed enrichment in TCA cycle components and senescence regulation. Targeted metabolomics showed higher concentrations of most TCA cycle intermediates and expression of sirtuin 3, with less abundance of markers of post-mitotic senescence. Under normoxia, regulation of mitochondrial oxidation and post-mitotic senescence in skeletal muscle by the transient expression of HIF1A may have relevance in other tissues also.

Project description:Background. Skeletal muscle is a major target organ for ethanol induced perturbations with resultant sarcopenia in alcohol-related liver disease (ALD). Targeted studies show that in skeletal muscle, ethanol causes mitochondrial oxidative dysfunction and impaired mTORC1 signaling with consequent decreased protein synthesis and increased autophagy. However, complex interactions and pathway intersections involved in cellular adaptive and maladaptive responses are not well understood. Unlike hypotheses driven focused experiments, an integrated multiomics-experimental validation approach helps identify the global landscape of complex, interacting perturbations in the skeletal muscle. Methods. We used an integrated multiomics approach in a comprehensive array of models, including murine and human induced pluripotent stem cell-derived myotubes (hiPSCm), skeletal muscle from a mouse model of ALD (mALD), and human patients with alcohol-related cirrhosis (CIR) and controls (CON), to identify novel regulatory mechanisms of sarcopenia in ALD. We generated 13 untargeted datasets, including chromosomal conformation, RNA sequencing, proteomics, phosphoproteomics, acetylomics, and metabolomics and conducted a comprehensive analysis using upset plots and feature extraction-based approaches. The most altered molecular interactions were experimentally validated in different models using immunoblots, redox measurements, imaging methods, and measures of senescence associated molecular phenotype (SAMP). Redox ratio was reversed using mitochondrial targeted Lactobacillus brevis NADH oxidase (MitoLbNOX). Results. Enrichments in mitochondrial oxidative function, protein synthesis, and senescence pathways were identified. Multiomics analyses were consistent with the known effects of hypoxia inducible factor 1 (HIF1) that inhibits mitochondrial oxidative dysfunction and promotes skeletal muscle senescence. Pertubrations in genes in the nicotinamide dinucleotide-related pathways including sirtuin signaling, known regulators of senescence, was also noted with ethanol treatment. Experimentally, HIF1 protein was stabilized in myotubes and muscle tissue without cellular hypoxia. Mitochondrial electron transport chain protein expression was less in murine myotubes and hiPSCm with lower redox ratio, less expression of sirtuins, and increased acetylation of mitochondrial proteins. SAMP noted in multiple models in response to ethanol exposure and reversing redox ratio with MitoLbNOX prevented HIF1a stabilization and SAMP in murine myotubes. Conclusions. Our integrated multiomics analyses combined with complementary experimental validation, identify HIF1a stabilization with accelerated skeletal muscle post-mitotic senescence as novel mechanisms of sarcopenia in ALD, highlighting the complex interactions that result in mitochondrial dysfunction with persistent and progressive sarcopenia in ALD.

Project description:Background. Skeletal muscle is a major target organ for ethanol induced perturbations with resultant sarcopenia in alcohol-related liver disease (ALD). Targeted studies show that in skeletal muscle, ethanol causes mitochondrial oxidative dysfunction and impaired mTORC1 signaling with consequent decreased protein synthesis and increased autophagy. However, complex interactions and pathway intersections involved in cellular adaptive and maladaptive responses are not well understood. Unlike hypotheses driven focused experiments, an integrated multiomics-experimental validation approach helps identify the global landscape of complex, interacting perturbations in the skeletal muscle. Methods. We used an integrated multiomics approach in a comprehensive array of models, including murine and human induced pluripotent stem cell-derived myotubes (hiPSCm), skeletal muscle from a mouse model of ALD (mALD), and human patients with alcohol-related cirrhosis (CIR) and controls (CON), to identify novel regulatory mechanisms of sarcopenia in ALD. We generated 13 untargeted datasets, including chromosomal conformation, RNA sequencing, proteomics, phosphoproteomics, acetylomics, and metabolomics and conducted a comprehensive analysis using upset plots and feature extraction-based approaches. The most altered molecular interactions were experimentally validated in different models using immunoblots, redox measurements, imaging methods, and measures of senescence associated molecular phenotype (SAMP). Redox ratio was reversed using mitochondrial targeted Lactobacillus brevis NADH oxidase (MitoLbNOX). Results. Enrichments in mitochondrial oxidative function, protein synthesis, and senescence pathways were identified. Multiomics analyses were consistent with the known effects of hypoxia inducible factor 1 (HIF1) that inhibits mitochondrial oxidative dysfunction and promotes skeletal muscle senescence. Pertubrations in genes in the nicotinamide dinucleotide-related pathways including sirtuin signaling, known regulators of senescence, was also noted with ethanol treatment. Experimentally, HIF1 protein was stabilized in myotubes and muscle tissue without cellular hypoxia. Mitochondrial electron transport chain protein expression was less in murine myotubes and hiPSCm with lower redox ratio, less expression of sirtuins, and increased acetylation of mitochondrial proteins. SAMP noted in multiple models in response to ethanol exposure and reversing redox ratio with MitoLbNOX prevented HIF1a stabilization and SAMP in murine myotubes. Conclusions. Our integrated multiomics analyses combined with complementary experimental validation, identify HIF1a stabilization with accelerated skeletal muscle post-mitotic senescence as novel mechanisms of sarcopenia in ALD, highlighting the complex interactions that result in mitochondrial dysfunction with persistent and progressive sarcopenia in ALD.

Project description:Background. Skeletal muscle is a major target organ for ethanol induced perturbations with resultant sarcopenia in alcohol-related liver disease (ALD). Targeted studies show that in skeletal muscle, ethanol causes mitochondrial oxidative dysfunction and impaired mTORC1 signaling with consequent decreased protein synthesis and increased autophagy. However, complex interactions and pathway intersections involved in cellular adaptive and maladaptive responses are not well understood. Unlike hypotheses driven focused experiments, an integrated multiomics-experimental validation approach helps identify the global landscape of complex, interacting perturbations in the skeletal muscle. Methods. We used an integrated multiomics approach in a comprehensive array of models, including murine and human induced pluripotent stem cell-derived myotubes (hiPSCm), skeletal muscle from a mouse model of ALD (mALD), and human patients with alcohol-related cirrhosis (CIR) and controls (CON), to identify novel regulatory mechanisms of sarcopenia in ALD. We generated 13 untargeted datasets, including chromosomal conformation, RNA sequencing, proteomics, phosphoproteomics, acetylomics, and metabolomics and conducted a comprehensive analysis using upset plots and feature extraction-based approaches. The most altered molecular interactions were experimentally validated in different models using immunoblots, redox measurements, imaging methods, and measures of senescence associated molecular phenotype (SAMP). Redox ratio was reversed using mitochondrial targeted Lactobacillus brevis NADH oxidase (MitoLbNOX). Results. Enrichments in mitochondrial oxidative function, protein synthesis, and senescence pathways were identified. Multiomics analyses were consistent with the known effects of hypoxia inducible factor 1 (HIF1) that inhibits mitochondrial oxidative dysfunction and promotes skeletal muscle senescence. Pertubrations in genes in the nicotinamide dinucleotide-related pathways including sirtuin signaling, known regulators of senescence, was also noted with ethanol treatment. Experimentally, HIF1 protein was stabilized in myotubes and muscle tissue without cellular hypoxia. Mitochondrial electron transport chain protein expression was less in murine myotubes and hiPSCm with lower redox ratio, less expression of sirtuins, and increased acetylation of mitochondrial proteins. SAMP noted in multiple models in response to ethanol exposure and reversing redox ratio with MitoLbNOX prevented HIF1a stabilization and SAMP in murine myotubes. Conclusions. Our integrated multiomics analyses combined with complementary experimental validation, identify HIF1a stabilization with accelerated skeletal muscle post-mitotic senescence as novel mechanisms of sarcopenia in ALD, highlighting the complex interactions that result in mitochondrial dysfunction with persistent and progressive sarcopenia in ALD.

Project description:Background. Skeletal muscle is a major target organ for ethanol induced perturbations with resultant sarcopenia in alcohol-related liver disease (ALD). Targeted studies show that in skeletal muscle, ethanol causes mitochondrial oxidative dysfunction and impaired mTORC1 signaling with consequent decreased protein synthesis and increased autophagy. However, complex interactions and pathway intersections involved in cellular adaptive and maladaptive responses are not well understood. Unlike hypotheses driven focused experiments, an integrated multiomics-experimental validation approach helps identify the global landscape of complex, interacting perturbations in the skeletal muscle. Methods. We used an integrated multiomics approach in a comprehensive array of models, including murine and human induced pluripotent stem cell-derived myotubes (hiPSCm), skeletal muscle from a mouse model of ALD (mALD), and human patients with alcohol-related cirrhosis (CIR) and controls (CON), to identify novel regulatory mechanisms of sarcopenia in ALD. We generated 13 untargeted datasets, including chromosomal conformation, RNA sequencing, proteomics, phosphoproteomics, acetylomics, and metabolomics and conducted a comprehensive analysis using upset plots and feature extraction-based approaches. The most altered molecular interactions were experimentally validated in different models using immunoblots, redox measurements, imaging methods, and measures of senescence associated molecular phenotype (SAMP). Redox ratio was reversed using mitochondrial targeted Lactobacillus brevis NADH oxidase (MitoLbNOX). Results. Enrichments in mitochondrial oxidative function, protein synthesis, and senescence pathways were identified. Multiomics analyses were consistent with the known effects of hypoxia inducible factor 1 (HIF1) that inhibits mitochondrial oxidative dysfunction and promotes skeletal muscle senescence. Pertubrations in genes in the nicotinamide dinucleotide-related pathways including sirtuin signaling, known regulators of senescence, was also noted with ethanol treatment. Experimentally, HIF1 protein was stabilized in myotubes and muscle tissue without cellular hypoxia. Mitochondrial electron transport chain protein expression was less in murine myotubes and hiPSCm with lower redox ratio, less expression of sirtuins, and increased acetylation of mitochondrial proteins. SAMP noted in multiple models in response to ethanol exposure and reversing redox ratio with MitoLbNOX prevented HIF1a stabilization and SAMP in murine myotubes. Conclusions. Our integrated multiomics analyses combined with complementary experimental validation, identify HIF1a stabilization with accelerated skeletal muscle post-mitotic senescence as novel mechanisms of sarcopenia in ALD, highlighting the complex interactions that result in mitochondrial dysfunction with persistent and progressive sarcopenia in ALD.

Project description:Background. Skeletal muscle is a major target organ for ethanol induced perturbations with resultant sarcopenia in alcohol-related liver disease (ALD). Targeted studies show that in skeletal muscle, ethanol causes mitochondrial oxidative dysfunction and impaired mTORC1 signaling with consequent decreased protein synthesis and increased autophagy. However, complex interactions and pathway intersections involved in cellular adaptive and maladaptive responses are not well understood. Unlike hypotheses driven focused experiments, an integrated multiomics-experimental validation approach helps identify the global landscape of complex, interacting perturbations in the skeletal muscle. Methods. We used an integrated multiomics approach in a comprehensive array of models, including murine and human induced pluripotent stem cell-derived myotubes (hiPSCm), skeletal muscle from a mouse model of ALD (mALD), and human patients with alcohol-related cirrhosis (CIR) and controls (CON), to identify novel regulatory mechanisms of sarcopenia in ALD. We generated 13 untargeted datasets, including chromosomal conformation, RNA sequencing, proteomics, phosphoproteomics, acetylomics, and metabolomics and conducted a comprehensive analysis using upset plots and feature extraction-based approaches. The most altered molecular interactions were experimentally validated in different models using immunoblots, redox measurements, imaging methods, and measures of senescence associated molecular phenotype (SAMP). Redox ratio was reversed using mitochondrial targeted Lactobacillus brevis NADH oxidase (MitoLbNOX). Results. Enrichments in mitochondrial oxidative function, protein synthesis, and senescence pathways were identified. Multiomics analyses were consistent with the known effects of hypoxia inducible factor 1 (HIF1) that inhibits mitochondrial oxidative dysfunction and promotes skeletal muscle senescence. Pertubrations in genes in the nicotinamide dinucleotide-related pathways including sirtuin signaling, known regulators of senescence, was also noted with ethanol treatment. Experimentally, HIF1 protein was stabilized in myotubes and muscle tissue without cellular hypoxia. Mitochondrial electron transport chain protein expression was less in murine myotubes and hiPSCm with lower redox ratio, less expression of sirtuins, and increased acetylation of mitochondrial proteins. SAMP noted in multiple models in response to ethanol exposure and reversing redox ratio with MitoLbNOX prevented HIF1a stabilization and SAMP in murine myotubes. Conclusions. Our integrated multiomics analyses combined with complementary experimental validation, identify HIF1a stabilization with accelerated skeletal muscle post-mitotic senescence as novel mechanisms of sarcopenia in ALD, highlighting the complex interactions that result in mitochondrial dysfunction with persistent and progressive sarcopenia in ALD.

Project description:Perturbed metabolism of ammonia, an endogenous cytotoxic molecule, causes mitochondrial dysfunction with decreased nicotinamide adenine dinucleotide (NAD+) in skeletal muscle. Consistent with our previous report of enrichment of NAD metabolism and sirtuin pathways during hyperammonemia, NAD+-dependent Sirtuin3 (Sirt3) expression and deacetylase activity weredecreased with increased muscle protein acetylation in murine and human skeletal muscle/myotubes. Acetylomics and cell fractions showed hyperammonemia-induced hyperacetylation of critical mitochondrial and signaling molecules. Overexpression of mitochondrial targeted Lactobacillus brevis NADH oxidase (MitoLbNOX) reversed ammonia-induced oxidative dysfunction, electron transport chain (ETC) supercomplex disassembly, lower ATP content, NAD+, and redox ratio (NAD+/NADH). Protein hyperacetylation, post-mitotic senescence and lower mitochondrial sirtuin (Sirt3) expressionduring hyperammonemia were also reversed by MitoLbNOX. Sirt3 overexpression alone did not reverse ammonia-induced redox or mitochondrial dysfunction but reversed hyperacetylation and senescence. These data show that targeting redox ratio, rather than Sirt3, more consistently restores mitochondrial homeostasis and protein acetylation during hyperammonemia.

Project description:Ammonia is a cytotoxic metabolite with pleotropic molecular and metabolic effects in non-hepatic tissue/cells targeting mitochondrial oxidative function that may contribute to post-mitotic senescence. Global molecular responses were determined by analysis of unbiased data followed by experimental validation of critical functional consequences in hyperammonemic differentiated myotubes and skeletal muscle from the portacaval anastomosis (PCA) rat. Integrating whole cell transcriptome with whole cell and mitochondrial proteome from hyperammonemic myotubes identified oxidative dysfunction and senescence pathways as being the most enriched with differentially expressed genes/proteins. Hyperammonemia and ammonia-lowering result in distinct clusters of molecular responses. Functional and metabolic studies in hyperammonemic myotubes showed that defects in electron transport chain (ETC) complexes I and III, loss of supercomplex assembly, decreased ATP synthesis, increased free radical generation with oxidative modification of proteins/lipids and increased expression of senescence associated molecular phenotype (SAMP) that were partially reversed by ammonia lowering. Studies in muscle from PCA rats established physiological relevance of our cellular studies. Dysregulated ammonia metabolism causes mitochondrial dysfunction by transcriptional and translational perturbations in multiple pathways with a distinct skeletal muscle SAMP.

Project description:EBF1 and HIF1a ChIPseq in MDA-MB-157 cells under normoxia and hypoxia

Project description:Epigenetic alterations are among the prominent drivers of cellular senescence and/or aging. In this study, we show that histone lactylation plays a pivotal role in counteracting senescence and mitigating dysfunctions of skeletal muscle in aged mice. Mechanistically, histone lactylation and lactyl-CoA levels markedly decrease during cellular senescence but are restored under hypoxic conditions primarily due to elevated glycolytic activity. The enrichment of histone lactylation at promoters is essential for sustaining the expression of genes involved in the cell cycle and DNA repair pathways, thereby inhibiting cellular senescence. Furthermore, the modulation of enzymes crucial for histone lactylation, including p300 and HDAC1, leads to reduced histone lactylation and accelerated cellular senescence. Consistently, the suppression of glycolysis and the depletion of histone lactylation are also observed during skeletal muscle aging. Modulating the enzymes also leads to the loss of histone lactylation in skeletal muscle, downregulating DNA repair and proteostasis pathways and accelerating muscle aging. Running exercise increases the levels of glycolysis and histone lactylation, thereby helping to preserve the proper function of skeletal muscle. Our study highlights the significant roles of histone lactylation in modulating cellular senescence and muscle aging, suggesting that this modification may serve as an innovative biomarker for senescence.