Monocyte Functional and Metabolic Re-Programming Induced by Oxidized LDL
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USyd Access
Type
ThesisThesis type
Doctor of PhilosophyAuthor/s
Naralashetty, SravanthiAbstract
Background: Dyslipidaemia affects 2 in 3 adult Australians and increases the lifetime risk of atherosclerotic cardiovascular diseases (ASCVDs). The stability of atherosclerotic lesions is associated with macrophage phenotype, with a higher proportion of inflammatory macrophages ...
See moreBackground: Dyslipidaemia affects 2 in 3 adult Australians and increases the lifetime risk of atherosclerotic cardiovascular diseases (ASCVDs). The stability of atherosclerotic lesions is associated with macrophage phenotype, with a higher proportion of inflammatory macrophages found in vulnerable plaques. Hypothesizing that monocyte phenotype may influence macrophage phenotype, here we are investigating whether oxidised LDL (oxLDL) reprograms monocytes giving them a persistent heightened inflammatory potential. Method: Monocytes were exposed to oxLDL for 24hours, washed and rested (from oxLDL) then re-stimulated with LPS (THP-1 cells) or M1 or M2 polarising stimuli (macrophages) for 24hours. The cellular cytokine expression, metabolic profile, redox status and mitochondrial functional parameters were assessed. Results and Conclusion: oxLDL caused a mixed inflammatory profile, induced lipid accumulation (in THP-1s), and caused a metabolic shift of the cells (both THP-1 and primary human monocytes) towards glycolysis accompanied by a marked mitochondrial dysfunction (decreased mitochondrial respiratory parameters). OxLDL enhanced mitochondrial membrane potential, decreased ROS, NO and mtROS production, reversed complex V activity and possibly de-activated complex I activity. Mitochondrial mass, area and branching were also significantly reduced (THP-1s) by oxLDL. oxLDL-mediated hypoxia-like response or reductive stress was proposed as a mechanism for such effects. The persistent mitochondrial dysfunction induced by oxLDL may lead to dysregulated polarisation of the cells to the M2 macrophage phenotype. In a clinical scenario, the presence of dysfunctional M2 macrophages would heighten necrotic core formation and influence plaque instability. Thereby, we propose that mitigating the oxLDL-induced mitochondrial damage in the monocytes could be a potential way to overcome the subsequent deleterious metabolic changes and thereby rescue macrophage function.
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See moreBackground: Dyslipidaemia affects 2 in 3 adult Australians and increases the lifetime risk of atherosclerotic cardiovascular diseases (ASCVDs). The stability of atherosclerotic lesions is associated with macrophage phenotype, with a higher proportion of inflammatory macrophages found in vulnerable plaques. Hypothesizing that monocyte phenotype may influence macrophage phenotype, here we are investigating whether oxidised LDL (oxLDL) reprograms monocytes giving them a persistent heightened inflammatory potential. Method: Monocytes were exposed to oxLDL for 24hours, washed and rested (from oxLDL) then re-stimulated with LPS (THP-1 cells) or M1 or M2 polarising stimuli (macrophages) for 24hours. The cellular cytokine expression, metabolic profile, redox status and mitochondrial functional parameters were assessed. Results and Conclusion: oxLDL caused a mixed inflammatory profile, induced lipid accumulation (in THP-1s), and caused a metabolic shift of the cells (both THP-1 and primary human monocytes) towards glycolysis accompanied by a marked mitochondrial dysfunction (decreased mitochondrial respiratory parameters). OxLDL enhanced mitochondrial membrane potential, decreased ROS, NO and mtROS production, reversed complex V activity and possibly de-activated complex I activity. Mitochondrial mass, area and branching were also significantly reduced (THP-1s) by oxLDL. oxLDL-mediated hypoxia-like response or reductive stress was proposed as a mechanism for such effects. The persistent mitochondrial dysfunction induced by oxLDL may lead to dysregulated polarisation of the cells to the M2 macrophage phenotype. In a clinical scenario, the presence of dysfunctional M2 macrophages would heighten necrotic core formation and influence plaque instability. Thereby, we propose that mitigating the oxLDL-induced mitochondrial damage in the monocytes could be a potential way to overcome the subsequent deleterious metabolic changes and thereby rescue macrophage function.
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Date
2024Rights statement
The author retains copyright of this thesis. It may only be used for the purposes of research and study. It must not be used for any other purposes and may not be transmitted or shared with others without prior permission.Faculty/School
Faculty of Medicine and HealthDepartment, Discipline or Centre
Westmead Clinical SchoolAwarding institution
The University of SydneyShare