Elephant seals experience natural periods of prolonged food deprivation while breeding, molting, and undergoing postnatal development. Prolonged food deprivation in elephant seals increases circulating glucocorticoids without inducing muscle atrophy, but the cellular mechanisms that allow elephant seals to cope with such conditions remain elusive. We generated a cellular model and conducted transcriptomic, metabolic, and morphological analyses to study how seal cells adapt to sustained glucocorticoid exposure. Seal muscle progenitor cells differentiate into contractile myotubes with a distinctive morphology, gene expression profile, and metabolic phenotype. Exposure to dexamethasone at three ascending concentrations for 48h modulated the expression of 6 clusters of genes related to structural constituents of muscle and pathways associated with energy metabolism and cell survival. Knockdown of the glucocorticoid receptor (GR) and downstream expression analyses corroborated that GR mediates the observed effects. Dexamethasone also decreased cellular respiration, shifted the metabolic phenotype towards glycolysis, and induced mitochondrial fission and dissociation of mitochondria-ER interactions without decreasing cell viability. Knockdown of DDIT4, a GR target involved in the dissociation of mitochondria-ER membranes, recovered respiration and modulated antioxidant gene expression. These results show that adaptation to sustained glucocorticoid exposure in elephant seal myotubes involves a metabolic shift toward glycolysis, which is supported by alterations in mitochondrial morphology and a reduction in mitochondria-ER interactions, resulting in decreased respiration without compromising cell survival.
In this study, the developmental expression pattern of myostatin (mstn) in the spotted rose snapper Lutjanus guttatus under culture conditions is presented. The full coding sequence of mstn from L. guttatus was isolated from muscle tissue, obtaining 1134 nucleotides which encode a peptide of 377 amino acids. The phylogenetic analysis indicated that this sequence corresponds to mstn-1. mstn expression was detected in embryonic stages, and maintained at low levels until 28 days post-hatch, when it showed a significant increase, coinciding with the onset of metamorphosis. After that, expression was fluctuating, coinciding probably with periods of rapid and slow muscle growth or individual growth rates. mstn expression was also analysed by body mass with higher levels detected in smaller animals, irrespective of age. mstn was also expressed in other tissues from L. guttatus, presenting higher levels in brain, eye and gill. In brain for instance, two variants of mstn were isolated, both coding sequences were identical to muscle, except that one of them contained a 75 nucleotide deletion in exon 1, maintaining the reading frame but deleting two conserved cysteine residues. Phylogenetic analysis indicated that this brain variant was also mstn-1. The function of this variant is not clear and needs further investigation. These results indicate that mstn-1 participates in different physiological processes other than muscle growth in fishes.
Northern elephant seals (NES) are naturally exposed to extreme conditions, including prolonged food and water deprivation (fasting). NES pups initially nurse for a month before they are weaned and fast for two months. During this fasting period NES pups lose about 25% of their body mass, while maintaining biochemical homeostasis and supporting muscle development. The environment, especially stressful environmental conditions, can modify the methylation status of DNA, consequently regulating gene expression. We compared global DNA methylation between early (1–2 weeks) and late (7–8 weeks) fasting NES pups. DNA was extracted from white blood cells collected from fasting NES pups. Global DNA methylation was measured using a MethylFlash™ Global DNA Methylation (5‐mC) Kit. Prolonged fasting significantly increased global DNA methylation (p = 0.0463) in NES pups, suggesting a decrease in transcription activity. We are in the process of identifying changes in specific genes involved in growth, hypoxia tolerance, and metabolism between early and late fasting pups by analyzing the methylation status of CpG islands in putative promoter region sequences. Our initial results suggest that DNA methylation is an important regulator of gene expression during natural, prolonged food deprivation.
Elephant seals experience natural periods of prolonged food deprivation while breeding, molting, and undergoing postnatal development. Prolonged food deprivation in elephant seals increases circulating glucocorticoids without inducing muscle atrophy, but the cellular mechanisms that allow elephant seals to cope with such conditions remain elusive. We generated a cellular model and conducted transcriptomic, metabolic, and morphological analyses to study how seal cells adapt to sustained glucocorticoid exposure. Seal muscle progenitor cells differentiate into contractile myotubes with a distinctive morphology, gene expression profile, and metabolic phenotype. Exposure to dexamethasone at three ascending concentrations for 48h modulated the expression of 6 clusters of genes related to structural constituents of muscle and pathways associated with energy metabolism and cell survival. Knockdown of the glucocorticoid receptor (GR) and downstream expression analyses corroborated that GR mediates the observed effects. Dexamethasone also decreased cellular respiration, shifted the metabolic phenotype towards glycolysis, and induced mitochondrial fission and dissociation of mitochondria-ER interactions without decreasing cell viability. Knockdown of DDIT4, a GR target involved in the dissociation of mitochondria-ER membranes, recovered respiration and modulated antioxidant gene expression. These results show that adaptation to sustained glucocorticoid exposure in elephant seal myotubes involves a metabolic shift toward glycolysis, which is supported by alterations in mitochondrial morphology and a reduction in mitochondria-ER interactions, resulting in decreased respiration without compromising cell survival.
Ferroptosis is a newly described form of regulated cell death driven by an iron‐dependent accumulation of phospholipid hydroperoxides. Glutathione peroxidase 4 (GPx4) suppresses ferroptosis through its ability to reduce phospholipid hydroperoxides. Peroxiredoxin 6 (Prdx6) expresses phospholipid hydroperoxide glutathione peroxidase activity, but its role in the regulation of ferroptosis remains unexplored. We compared Prdx6 and GPx4 mRNA levels in murine lungs. Prdx6 expression was five times higher than GPx4 expression. We then visualized the spatial localization of lung Prdx6. Prdx6 was expressed in both pulmonary epithelial (epCAM+) and endothelial (Ve‐cadherin+) cells. We studied the role of Prdx6 on lung ferroptosis induced by erastin, an inhibitor of the cystine‐glutamate antiporter, which is critical to glutathione production. Erastin (1‐5μM, 24h) increased lipid peroxidation and cell death in mouse pulmonary microvascular endothelial cells (MPMVECs) in primary culture; this effect was higher in Prdx6‐KO MPMVECs than in WT‐MPMVECs. Co‐treatment with the ferroptosis suppressor ferrostatin‐1 prevented erastin‐induced lipid peroxidation and cell death in both WT and Prdx6‐KO MPMVECs. Similarly, knockdown (KD) of Prdx6 in human pulmonary microvascular endothelial cells (HPMVECs) increased erastin‐induced cell death, suggesting that Prdx6 limits ferroptosis in the pulmonary endothelium. We then conducted extracellular flux assays and RNA‐seq analyses in Prdx6‐deficient cells to further explore how the loss of Prdx6 sensitizes cells to ferroptosis. Cellular respiration and mitochondrial function were blunted in Prdx6‐deficient cells compared to corresponding controls. Top differentially expressed genes in Prdx6‐KD HPMVECs include known regulators of iron metabolism and ferroptosis such as hmox1, cybrd1, and sfxn1. Upregulated Reactome pathways enriched in Prdx6‐KD HPMVECs include mitochondrial and amino acid metabolism and p53‐mediated DNA damage response, while downregulated pathways include biological oxidations, transport of bile salts and organic acids, metal ions and amine compounds, cytochrome P450, and phase 1 metabolism. These results show that loss of Prdx6 sensitizes lung endothelial cells to ferroptosis by promoting lipid peroxidation and altering transcriptional signatures associated with cell cycle progression and mitochondrial metabolism.
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