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Sepsis is a deadly and debilitating condition resulting from a hyperinflammatory response to infection. Most organ systems are severely impacted, including the neurological complications for survivors of sepsis. Sepsis associated encephalopathy (SAE) is characterized by dysregulated molecular pathways of the

Sepsis is a deadly and debilitating condition resulting from a hyperinflammatory response to infection. Most organ systems are severely impacted, including the neurological complications for survivors of sepsis. Sepsis associated encephalopathy (SAE) is characterized by dysregulated molecular pathways of the immune response impinging upon normal central nervous system (CNS) function and ultimately resulting in lasting cognitive and behavioral impairments. Sepsis predominantly occurs in a few neonates but mostly elderly individuals where they are at high risk of sepsis-induced delirium and other neurological implications that may have overlap with neurodegenerative diseases. This study seeks to identify gene candidates that exhibit altered transcriptional expression in tissues between pigs injected with saline control vs lipopolysaccharide (LPS) to model the early inflammatory aspects of the septic response. Specifically, brain frontal cortex was examined to see which genes and pathways are altered at these early stages and could be targeted for further investigation to alter the cognitive/behavioral decline seen in sepsis survivors. This experiment uses a bulk RNA-seq approach on Yorkshire pigs to identify the variance in gene expression profile. Data analysis showed several gene candidates that were downregulated in the brain in response to LPS that point to early endothelial cell disruption, including OCLN (occludin), SLC19A3 (thiamine transporter), and SLC52A3 (riboflavin transporter). Genes that were upregulated in LPS brain samples implicate endothelial cell dysfunction as well as immune/inflammatory alterations, possibly due to alterations in microglia, the primary immune cell of the brain. Several studies are now underway to understand the cellular origin of these transcriptional changes, as well as analyzing the molecular signatures altered in response to sepsis in whole blood and kidney using bulk RNAseq. In conclusion, specific gene candidates were identified as early changes in the septic brain that could be targets to prevent long-term cognitive and behavioral changes in future studies, establishing a baseline panel to interrogate in animal models with the goal of advancing treatments for human patients who experience sepsis.
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    Title
    • Transcriptional Characterization of Sepsis in a Novel LPS Pig Model
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    Date Created
    2021
    Resource Type
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    • Partial requirement for: M.S., Arizona State University, 2021
    • Field of study: Biology

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