Project description:Transcriptomic sequencing reveals gene expression profiles underlying photobiomodulation-mediated amelioration of hypobaric hypoxia-induced synaptic plasticity deficits in mice

Project description:To determine hypoxia mediated changes in whole blood, normal swiss webster mice were gradually exposed to a chronic hypobaric hypoxic environment up to 8500m, for 2 weeks in vivo. Control, age-matched mice were maintained under normoxic conditions in Kathmandu (c. 1300 mts above sea level). Purpose: To examine and characterize the expression profile of genes expressed at hypobaric hypoxia on Mt. Everest of whole blood in comparison to the control. Methods: At the beginning of the experiment mice were divided into two groups, control (room condition, Kathmandu, Nepal) and hypoxic (hypoxic condition). For conditioning, the hypoxic group was exposed to lower levels of hypobaric hypoxia during our mountaineering expedition to Mt Everest. The oxygen level was decreased according to our climbing protocol from 21% to about 7% over a period of 15 days. Food and water were changed daily during the course of the experiment. After 15 days animals were euthanized after whole blood extraction from V. Cava for further analysis. RNA from whole blood was isolated, processed and used for microarray-based expression profiling. Profiles were generated for genes differentially expressed at control versus hypobaric hypoxia in whole blood using a false discovery rate (FDR) of 0%.We validated the profiles by real-time quantitative reverse transcription-polymerase chain reaction (qPCR). Results: The regional transcriptomes associated with hypobaric hypoxia on Mt. Everest in whole blood were identified. We found 947 genes that were differentially expressed in normobaric hypoxic whole blood compared to control with a 0% FDR and a 2 fold cutoff. Conclusion: Transcriptome level differences exist between control and hypobaric hypoxia in whole blood. Our definition of the synaptic transcriptome provides insight into the functioning of the unique response to hypoxia in whole blood.

Project description:For individuals migrating to or residing permanently at high-altitude regions, environmental hypobaric hypoxia is a primary challenge which induces several physiological or pathological responses. It is well documented that human beings adapt to hypobaric hypoxia via some protective mechanisms, such as erythropoiesis and overproduction of hemoglobin, however little is known on the changes of plasma proteome profiles in accommodation to high-altitude hypobaric hypoxia. In the present study, we investigated differential plasma proteomes of high altitude natives and lowland normal controls by a TMT-based proteomic approach. A total of 818 proteins were identified, of which 137 were differentially altered. Bioinformatics (including GO, KEGG, protein-protein interactions, etc.) analysis revealed the dysregulated proteins were primarily involved in complement and coagulation cascades, anti-oxidative stress and glycolysis. Validations via magnetic Luminex® Assays and ELISA demonstrated that CCL18, C9, PF4, MPO and S100A9 notably up-regulated, and HRG and F11 down-regulated in high altitude natives compared with lowland controls, which were consistent with the proteomic results. Our findings highlight the roles of complement and coagulation cascades, anti-oxidative stress and glycolysis in acclimatization to hypobaric hypoxia and provide a foundation for developing potential diagnostic or/and therapeutic biomarkers for high altitude hypobaric hypoxia-induced diseases.

Project description:Sprague Dawley rats were exposed to Hypobaric Hypoxia for 1, 3 and 7 days followed isolation of Hippocampus. Microarray was performed utilizing RNA isolated from these samples. Each group included 5 animals.

Project description:Sprague Dawley rats were exposed to Hypobaric Hypoxia for 1, 3 and 7 days followed isolation of Hippocampus. Microarray was performed utilizing RNA isolated from these samples. Each group included 5 animals. Agilent Rat Gene Expression 8X60K (AMADID: 028279) , Labeling kit: Agilent Quick-Amp labeling Kit (p/n5190-0442)

Project description:Aim: Acute hypobaric hypoxia occurs during fast ascent and brief sojourns to high altitudes. We aimed to elucidate early phase molecular mechanisms during hypobaric hypoxia that may contribute towards differential physiological responses in susceptible and tolerant rats. Methods: Sprague-Dawley rats representing susceptible, normal (moderate) and tolerant male and female groups were subjected to simulated acute hypobaric hypoxia for one hour at 9144 m and 24°C. The lung tissue samples were subjected to high throughput mRNA-seq based transcriptome profiling. Differential gene expression of selected genes was validated by qRT-PCR. Results: The cellular mechanisms found to be playing significant role in hypobaric hypoxia included MAPK, p53 and JAK-STAT signaling, and hypometabolism. Upregulated expression of early response genes including Dusp1, Cdkn1a, Txnip, Rgs1 and Rgs2 in susceptible rats indicated a progression towards growth arrest and apoptosis, while elevated expression of cell adhesion molecules, wound healing and repair bioprocesses was found in tolerant males. Upregulated Kcnj15 and Vsig4 variants in tolerant females suggested hypoxia adaptation by fluid reabsorption to avoid edematous conditions and suppression of T cell proliferation to avoid acute lung inflammation. Conclusion: The differential gene expression patterns in different experimental sets elucidated the physiological mechanisms associated with progressive damage in the lung tissues of susceptible and normal (moderate) rats, and tissue protective measures in tolerant rats during acute hypobaric hypoxia.

Project description:Hypobaric Hypoxia Induced Transcriptional profiling of Bovine (Bos indicus)

Project description:Extreme hypobaria is a novel abiotic stress that is outside the evolutionary experience of terrestrial plants. In natural environments, the practical limit of atmospheric pressure experienced by higher plants is about 50 kPa or ~.5 atmospheres; a limit that is primarily imposed by the combined stresses inherent to high altitude conditions of terrestrial mountains. However, in highly controlled chambers and within extra-terrestrial greenhouses the atmospheric pressure component can be isolated from other high altitude stresses such as temperature, desiccation, and even hypoxia. In addition, hypobaria can be carried to extremes beyond what is possible in terrestrial biomes, and explored as a single variable in the examination of plant responses to novel stress. Previous studies have shown that plants adjust to hypobaric stress by differentially expressing suites of genes in unique combinations that are not equal to the dissected components of hypobaric stress (such as hypoxia and desiccation). Here we examine the organ-specific progression of transcriptional strategies for physiological adaptation to hypobaric stress over time. An abrupt transition from a near-sea level pressure of 97 kPa to only 5 kPa is accompanied by the differential expression of hundreds of genes. However, the transcriptomic reaction to hypobaric conditions lying between these two extremes reveals complex, organ-specific responses that vary over a time course of hypobaric exposure, and that are also not linear with respect to a simple gradient of severity. It is also clear that plants adjust over time such that the gene expression patterns that are initially elicited to cope with hypobaria are mediated as plants adjust their metabolism to this environment. The patterns of genome-wide changes in gene expression across a gradient of atmospheric pressures, and over a time course of several days allows for the development of theories of how plant metabolisms may be adapting to changes in atmospheric pressures.

Project description:Extreme hypobaria is a novel abiotic stress that is outside the evolutionary experience of terrestrial plants. In natural environments, the practical limit of atmospheric pressure experienced by higher plants is about 50 kPa or ~.5 atmospheres; a limit that is primarily imposed by the combined stresses inherent to high altitude conditions of terrestrial mountains. However, in highly controlled chambers and within extra-terrestrial greenhouses the atmospheric pressure component can be isolated from other high altitude stresses such as temperature, desiccation, and even hypoxia. In addition, hypobaria can be carried to extremes beyond what is possible in terrestrial biomes, and explored as a single variable in the examination of plant responses to novel stress. Previous studies have shown that plants adjust to hypobaric stress by differentially expressing suites of genes in unique combinations that are not equal to the dissected components of hypobaric stress (such as hypoxia and desiccation). Here we examine the organ-specific progression of transcriptional strategies for physiological adaptation to hypobaric stress over time. An abrupt transition from a near-sea level pressure of 97 kPa to only 5 kPa is accompanied by the differential expression of hundreds of genes. However, the transcriptomic reaction to hypobaric conditions lying between these two extremes reveals complex, organ-specific responses that vary over a time course of hypobaric exposure, and that are also not linear with respect to a simple gradient of severity. It is also clear that plants adjust over time such that the gene expression patterns that are initially elicited to cope with hypobaria are mediated as plants adjust their metabolism to this environment. The patterns of genome-wide changes in gene expression across a gradient of atmospheric pressures, and over a time course of several days allows for the development of theories of how plant metabolisms may be adapting to changes in atmospheric pressures.

Project description:C57BL/6J mice were assigned to the hypobaric hypoxia chamber for simulation of high-altitude conditions. iTRAQ proteomics analysis/nanoUHPLC-MS/MS analysis was performed accordingly in the right myocardium of mice that had been allowed to develop hypoxia-induced pulmonary hypertension after hypobaric hypoxia exposure.