In light of the accelerated aging of the global population and the deterioration of the atmosphere pollution, we sought to clarify the potential mechanisms by which fine particulate matter(PM_(2.5)) can cause cogn...In light of the accelerated aging of the global population and the deterioration of the atmosphere pollution, we sought to clarify the potential mechanisms by which fine particulate matter(PM_(2.5)) can cause cognitive impairment and neurodegeneration through the alteration of mitochondrial structure and function. The results indicate that PM_(2.5) inhalation reduces ATP production by disrupting the aerobic tricarboxylic acid cycle and oxidative phosphorylation, thereby causing the hypophosphorylation of tau in the cortices of middle-aged mice. Furthermore, excessive reactive oxygen species generation was involved in the impairment. Interestingly, these alterations were partially reversed after exposure to PM_(2.5) ended. These findings clarify the mechanism involved in mitochondrial abnormality-related neuropathological dysfunction in response to atmospheric PM_(2.5) inhalation and provide an optimistic sight for alleviating the adverse health outcomes in polluted areas.展开更多
基金supported by the National Science Foundation of China(Nos.21377076,91543203,21477070,21222701)Specialized Research Fund for the Doctoral Program of Higher Education of China(Nos.20121401110003,20131401110005)+1 种基金Project Supported by Shanxi Young Sanjin Scholarship of China,Program for the Outstanding Innovative Teams of Higher Learning Institutions of ShanxiResearch Project Supported by Shanxi Scholarship Council of China(No.2015-006)
文摘In light of the accelerated aging of the global population and the deterioration of the atmosphere pollution, we sought to clarify the potential mechanisms by which fine particulate matter(PM_(2.5)) can cause cognitive impairment and neurodegeneration through the alteration of mitochondrial structure and function. The results indicate that PM_(2.5) inhalation reduces ATP production by disrupting the aerobic tricarboxylic acid cycle and oxidative phosphorylation, thereby causing the hypophosphorylation of tau in the cortices of middle-aged mice. Furthermore, excessive reactive oxygen species generation was involved in the impairment. Interestingly, these alterations were partially reversed after exposure to PM_(2.5) ended. These findings clarify the mechanism involved in mitochondrial abnormality-related neuropathological dysfunction in response to atmospheric PM_(2.5) inhalation and provide an optimistic sight for alleviating the adverse health outcomes in polluted areas.
