Project description:We have used long-term experimental selection over many generations to obtain Drosophila melanogaster strains that can live perpetually in extremely low, normally lethal O2 conditions (4-5% O2). These strains show a dramatic phenotypic divergence from control animals, including a decreased recovery time after anoxia, a higher rate of O2 consumption in hypoxic conditions, and a decrease in body mass due to both decreased cell proliferation and cell size. We used gene expression profiling to identify altered transcript levels in the adapted flies and we show that mutations in many of the corresponding genes confer the ability to survive under extremely low O2 conditions. Keywords: genetic bases of hypoxia adaptation

Project description:Hypoxia is a physiological stress that frequently occurs in solid tissues. Autophagy, a ubiquitous degradation/recycling system in eukaryotic cells, renders cells tolerant to multiple stressors. However, the mechanisms underlying autophagy initiation upon hypoxia remains unclear. This study identifies an oxygen-sensitive methylation of ULK1 with an important role in hypoxic stress adaptation by promoting autophagy induction.

Project description:he dynamic balance of hypoxia and oxidative stress constitutes the oxygen-related microenvironment in injured tissues. Oxygen homeostasis is highly variable; therefore, it is not a therapeutic target for injured tissue repair. We found an enrichment and extensive apoptosis of mesenchymal stem cells (MSCs) infused intravenously in the wound microenvironment with co-existing hypoxia and oxidative stress. Apoptotic bodies (ABs), generated from in situ apoptosis, significantly promotes angiogenesis. We improved the derivation pathway of ABs by simulating oxygen homeostasis in injured tissues, with cobalt chloride-induced hypoxia or hydrogen peroxide-induced oxidative stress in MSCs. Oxygen-related environmental stressed ABs, derived from environments of hypoxic and oxidative stress, were identified and loaded onto hydrogel microspheres for accurate regulation of endothelial cells (ECs) vascularization. These ABs directly targeted ECs; oxidative stress ABs (Oxi-ABs) have a 2.5- and 4-fold higher tube-forming ability than hypoxic and normoxic ABs, respectively. miRNA microarray analysis revealed that different oxygen-stressed ABs deliver similar miRNAs, which leads to the broad upregulation of EC phosphokinase activity. Finally, local delivery of Oxi-ABs-loaded hydrogel microspheres promotes wound healing. Oxi-ABs-loaded hydrogel microspheres achieved controlled AB release, targeting EC by reducing the consumption of early inflammatory cells and adapting to the proliferative phase of wound healing. Thus, the biogenerated apoptotic bodies responding to oxygen-related environmental stress can target ECs to promote vascularization.

Project description:Hypoxia in coastal waters is an increasing concern, with the frequency of hypoxic events rising because of climate change and human-driven impacts such as eutrophication. The Atlantic killifish (Fundulus heteroclitus), an estuarine species known for its resilience to environmental stressors, provides a valuable model to investigate the physiological, transcriptional, and epigenetic mechanisms underlying adaptation. Some killifish populations, like those in New Bedford Harbor (NBH), Massachusetts, have evolved resistance to dioxin-like polychlorinated biphenyls (PCBs) due to chronic exposure. These populations offer a unique opportunity to investigate how toxicant resistance might influence responses to secondary stressors like hypoxia. The objective of this study is to characterize the impacts of evolved resistance to toxicants on the ability to cope with acute hypoxia. We compared hepatic gene expression and DNA methylation patterns in response to two levels of hypoxia in killifish from NBH and Scorton Creek (SC), a reference population from a relatively pristine environment. We hypothesized that NBH fish would exhibit altered molecular responses to hypoxia due to trade-offs associated with toxicant resistance. Our results revealed significant differences between the two populations. SC fish demonstrated a dose-dependent increase in gene expression in response to hypoxia, while NBH fish exhibited a muted transcriptional response to severe hypoxia, indicating potential impairment in their ability to cope with hypoxic stress. Interestingly, NBH fish showed significant DNA methylation changes in response to hypoxia, while SC fish did not exhibit notable epigenetic alterations. These findings suggest that toxicant-adapted killifish may face trade-offs in their response to additional environmental stressors, with potential consequences for their ability to survive in increasingly hypoxic coastal habitats. Further research is needed to elucidate the functional implications of these epigenetic modifications and their role in adaptive stress responses.

Project description:Hypoxic stress is a feature of rapidly growing thyroid tumors. Cancer progression is thought to be driven by reactive oxygen species (ROS) induced hypoxia adaptation. NADPH oxidases (NOXs), which produce ROS as their primary and sole function, has become of particular interest in thyroid malignancy. NOX4 was demonstrated to be upregulated in papillary thyroid cancers, functioning as a mitochondrial energetic sensor to modulate ATP levels, mediating overproduction of ROS induced by IL-δ, inversely correlating to thyroid differentiation. In this study, we analyzed hypoxia-treated BCPAP cells transfected with siRNA against NOX4. Results provides insight into the role of NOX4 in hypoxia adaptation.

Project description:Oxygen (O2) is a double-edged sword to cells for while it is vital for energy production in all aerobic animals and insufficient O2 (hypoxia) can lead to cell death, the reoxygenation of hypoxic tissues may trigger the generation of reactive oxygen species (ROS) that can destroy any biological molecule. Indeed, both hypoxia and hypoxia-reoxygenation (H/R) stress are harmful, and may play a critical role in the pathophysiology of many human diseases such as myocardial ischemia and stroke. Therefore, understanding how animals adapt to hypoxia and H/R stress is critical for developing better treatments for these diseases. Previous studies showed that the neuroglobin GLB-5(Haw) is essential for the fast recovery of the nematode Caenorhabditis elegans (C. elegans) from H/R stress. Here, we characterize the changes in neuronal gene expression during the adaptation of worms to hypoxia and recovery from H/R stress. Our analysis show that innate immunity genes are differentially expressed during both adaptation to hypoxia and recovery from H/R stress.

Project description:Protein recoding by RNA editing is required for normal health and evolutionary adaptation. However, de novo induction of RNA editing in response to environmental factors is an uncommon phenomenon. While APOBEC3A edits many mRNAs in monocytes/macrophages in response to hypoxia and interferons, the physiological significance of such editing is unclear. Here we show that the related APOBEC3G cytidine deaminase induces site-specific C-to-U RNA editing in natural killer (NK), CD8+ T cells and lymphoma cell lines upon cellular crowding and hypoxia. RNA seq analysis of hypoxic NK cells reveals C-to-U recoding mRNA editing in dozens of genes including multiple translational and ribosomal genes. APOBEC3G promotes Warburg-like metabolic remodeling and reduces proliferation of HuT78 T cells under similar conditions. Hypoxia-induced RNA editing by APOBEC3G can be mimicked by the inhibition of mitochondrial respiration, and occurs independently of HIF-1α. Thus, APOBEC3G induces mRNA editing in lymphocytes to promote adaptation to mitochondrial hypoxic stress.

Project description:To understand the role of hypoxia in metastatic progression, we sought to spatially map gene expression in hypoxic cells compared with cells that migrated to oxygenated tumor regions. We adapted the Visium spatial transcriptomics protocol to perform concurrent transcriptional profiling and fluorescent imaging of our hypoxia fate-mapping system.

Project description:The transcriptome of the amphipod Echinogammarus marinus was sequenced after exposure to hypoxia following acclimation to different temperatures using 100BP paired-end Illumina HiSeq sequencing. Amphipods were acclimated to two temperatures, 10 or 20 °C, for one week before individuals were then acutely exposed to normoxic (80% air saturation) or hypoxic conditions (30% air saturation) at 10 °C (n = 5 per experimental treatment).

Project description:Dissolved oxygen (DO) has an important impact on fish survival and reproduction, and is also one of the keys limiting conditions for healthy fish life. Rainbow trout (Oncorhynchus mykiss), an economically significant cold-water fish globally, are highly susceptible to hypoxia stress. However, the physiological changes and molecular mechanisms of rainbow trout under different hypoxic conditions are still unknown. In the present study, we used RNA-seq analysis and measurement of biochemical parameters at different time points (0-, 4-, 8-, 12-, 24 h) under acute (3.0 ± 0.1 mg/L), chronic (4.5 ± 0.1 mg/L) hypoxic stress and reoxygenation (R12-, R24 h) to reveals the physiological changes and molecular mechanism of the hypoxic stress response in rainbow trout. The transcriptome results showed that a total of 424 differentially expressed genes (DEGs) were identified in the CM-vs-Tm12M, CM-vs-Ts12M and Tm12M-vs-Ts12M groups and the genes for FOXO signaling pathway, p53 signaling pathway, Adipocytokine signaling pathway, Autophagy, Glycine, serine and threonine metabolism, etc. were significantly enriched under hypoxic stress, as shown by Gene Ontology (GO), Kyoto Encyclopedia of Genes and Genomes enrichment analyses (KEGG) and Gene Set Enrichment Analysis (GSEA). Based on DEGS expression trend analysis, the most significant 2 clusters were selected to construct protein-protein interaction (PPI) networks, which resulted in the prediction of ddit4, txnip, slc3a2 and p4ha1 as the hypoxia-induced hub genes in cluster 7. fgg, f7, serpina1 and serpinf2 are the hypoxia-induced hub genes of cluster 3. This study preliminarily elucidated the adaptive mechanism of rainbow trout in response to hypoxic stress and provide a basis for the study of the molecular mechanism of fish adaptation to different hypoxic stresses.