Project description:Physical exercise is beneficial to keep physical and mental health. The molecular mechanisms underlying exercise are still worth exploring.The healthy adult mice after six weeks of moderate-intensity exercise (experimental group) and sedentary mice (control group) were used to perform transcriptomic, proteomic, lactylation modification, and metabolomics analysis. In addition, gene sets related to hypoxia, glycolysis, and fatty acid metabolism were used to aid in the screening of hub genes. The mMCP-counter was employed to evaluate infiltration of immune cells in murine liver tissues.

Project description:To explore the effects of moderate intensity exercise on protein of lactylation in mouse muscle tissue metabolism. The healthy adult mice running for 6 weeks as exercise model and sedentary mice as control were used to perform transcriptomic, proteomic, lactylation-proteomics, and metabolomics analysis. In addition, correlation analysis between transcriptome and proteome, and proteome and metabolome was conducted as well. In this study, 159 lactate sites of 78 proteins were identified to be differentically regulated by moderate intensity exercise. Enrichment analysis showed that lactated proteins Mtatp8, Atp5mg and Atp5po exhibited ATP hydrolysis activity. They are involved in biological processes such as mitochondrial transmembrane transport, and Mtatp8, Atp5mg and Atp5po participate in Oxidative phosphorylation and Thermogenesis pathways. The lactation levels of Mtatp8, Atp5mg and Atp5po proteins in exercise group were significantly decreased, while their protein levels were significantly increased. The combined analysis of proteomics and metabolomics showed that the Oxocarboxylic acid metabolism pathway and Sphingolipid signaling pathway had significant changes under the influence of moderate intensity exercise. Our results showed that moderate intensity exercise has a certain effect on the lactylation level of mice, possibly by reducing lactylation levels of Mtatp8, Atp5mg and Atp5po and increasing the expression of their protein levels, thereby regulating the Oxidative phosphorylation pathway and participating in energy metabolism. 2-Oxocarboxylic acid metabolism pathway and Sphingolipid signaling pathway need to be further explored.

Project description:Epigenetic alterations are among the prominent drivers of cellular senescence and/or aging, intricately orchestrating gene expression programs during these processes. Many studies have investigated the histone modification mechanisms that regulate cellular senescence and aging. In this study, we show that histone lactylation, an identified histone modification that integrates metabolic processes, epigenetic regulation of gene expression and cellular activities in response to internal and external cues, plays a pivotal role in counteracting senescence and mitigating dysfunctions of skeletal muscle in aged mice. Mechanistically, histone lactylation 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. Running exercise increases the levels of glycolysis and histone lactylation, which in turn upregulate key genes in the DNA repair and proteostasis pathways, thereby helping to preserve the proper function of skeletal muscle. Our study highlights the significant roles of histone lactylation in modulating cellular senescence as well as aging-related tissue function, suggesting that this modification may serve as an innovative biomarker for senescence and provides a promising avenue for antiaging intervention via metabolic manipulation.

Project description:Epigenetic alterations are among the prominent drivers of cellular senescence and/or aging, intricately orchestrating gene expression programs during these processes. Many studies have investigated the histone modification mechanisms that regulate cellular senescence and aging. In this study, we show that histone lactylation, an identified histone modification that integrates metabolic processes, epigenetic regulation of gene expression and cellular activities in response to internal and external cues, plays a pivotal role in counteracting senescence and mitigating dysfunctions of skeletal muscle in aged mice. Mechanistically, histone lactylation 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. Running exercise increases the levels of glycolysis and histone lactylation, which in turn upregulate key genes in the DNA repair and proteostasis pathways, thereby helping to preserve the proper function of skeletal muscle. Our study highlights the significant roles of histone lactylation in modulating cellular senescence as well as aging-related tissue function, suggesting that this modification may serve as an innovative biomarker for senescence and provides a promising avenue for antiaging intervention via metabolic manipulation.

Project description:Epigenetic alterations are among the prominent drivers of cellular senescence and/or aging, intricately orchestrating gene expression programs during these processes. Many studies have investigated the histone modification mechanisms that regulate cellular senescence and aging. In this study, we show that histone lactylation, an identified histone modification that integrates metabolic processes, epigenetic regulation of gene expression and cellular activities in response to internal and external cues, plays a pivotal role in counteracting senescence and mitigating dysfunctions of skeletal muscle in aged mice. Mechanistically, histone lactylation 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. Running exercise increases the levels of glycolysis and histone lactylation, which in turn upregulate key genes in the DNA repair and proteostasis pathways, thereby helping to preserve the proper function of skeletal muscle. Our study highlights the significant roles of histone lactylation in modulating cellular senescence as well as aging-related tissue function, suggesting that this modification may serve as an innovative biomarker for senescence and provides a promising avenue for antiaging intervention via metabolic manipulation.

Project description:Epigenetic alterations are among the prominent drivers of cellular senescence and/or aging, intricately orchestrating gene expression programs during these processes. Many studies have investigated the histone modification mechanisms that regulate cellular senescence and aging. In this study, we show that histone lactylation, an identified histone modification that integrates metabolic processes, epigenetic regulation of gene expression and cellular activities in response to internal and external cues, plays a pivotal role in counteracting senescence and mitigating dysfunctions of skeletal muscle in aged mice. Mechanistically, histone lactylation 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. Running exercise increases the levels of glycolysis and histone lactylation, which in turn upregulate key genes in the DNA repair and proteostasis pathways, thereby helping to preserve the proper function of skeletal muscle. Our study highlights the significant roles of histone lactylation in modulating cellular senescence as well as aging-related tissue function, suggesting that this modification may serve as an innovative biomarker for senescence and provides a promising avenue for antiaging intervention via metabolic manipulation.

Project description:Lysine lactylation (Kla) is a newly discovered posttranslational modification showing the addition of an L-lactate-derived lactyl group to the lysine residue. Histone lactylation has been found to regulate the downstream genes expression involved in the process of infection clearance, homeostasis retore, and tumorigenesis. Like other metabolite mediated PTMs, which the cellular levels of these metabolites affect the stoichiometry of the corresponding PTMs, the level of Kla also responds to the intracellular lactate concentration in a dose-dependent fashion associated with glycolysis metabolism. It has long been noted that manipulation of glycolysis metabolism could affect the tendon cell function, tendon homeostasis, and healing process of tendon.Nonetheless, the lactylation sites and regulations in tendinopathy remain unexplored.

Project description:Cancer cells often rely on aerobic glycolysis for metabolism, and lactylation, a newly discovered post-translational modification, significantly impacts molecular processes. This study comprehensively analyzes lactylation's role in oral squamous cell carcinoma (OSCC), providing initial insights into its impact on progression. Oral squamous cell carcinoma cell lines, before and after lactate treatment, underwent CUT&TAG, ATAC, and transcriptomic sequencing. ChIP-qPCR and RT-qPCR validated results in OSCC tissues. Integrated analysis identified 217 genes with increased expression driven by lactylation in OSCC. Lactylation broadly impacted pathways in cancer, notably regulating PI3K/AKT and MAPK signaling. This pioneering study analyzes lactylation in OSCC, providing a global map of its regulation in oral squamous cell carcinoma from the perspective of chromatin-driven gene expression.

Project description:Cancer cells often rely on aerobic glycolysis for metabolism, and lactylation, a newly discovered post-translational modification, significantly impacts molecular processes. This study comprehensively analyzes lactylation's role in oral squamous cell carcinoma (OSCC), providing initial insights into its impact on progression. Oral squamous cell carcinoma cell lines, before and after lactate treatment, underwent CUT&TAG, ATAC, and transcriptomic sequencing. ChIP-qPCR and RT-qPCR validated results in OSCC tissues. Integrated analysis identified 217 genes with increased expression driven by lactylation in OSCC. Lactylation broadly impacted pathways in cancer, notably regulating PI3K/AKT and MAPK signaling. This pioneering study analyzes lactylation in OSCC, providing a global map of its regulation in oral squamous cell carcinoma from the perspective of chromatin-driven gene expression.

Project description:Cancer cells often rely on aerobic glycolysis for metabolism, and lactylation, a newly discovered post-translational modification, significantly impacts molecular processes. This study comprehensively analyzes lactylation's role in oral squamous cell carcinoma (OSCC), providing initial insights into its impact on progression. Oral squamous cell carcinoma cell lines, before and after lactate treatment, underwent CUT&TAG, ATAC, and transcriptomic sequencing. ChIP-qPCR and RT-qPCR validated results in OSCC tissues. Integrated analysis identified 217 genes with increased expression driven by lactylation in OSCC. Lactylation broadly impacted pathways in cancer, notably regulating PI3K/AKT and MAPK signaling. This pioneering study analyzes lactylation in OSCC, providing a global map of its regulation in oral squamous cell carcinoma from the perspective of chromatin-driven gene expression.