Project description:Intermittent fasting (IF) has been extensively reported to participate in improved energy homeostasis and metabolic switching, which in turn promotes protection against numerous age-associated metabolic diseases that have plagued the global population in recent years. Despite the observation that IF may be a plausible strategy to ameliorate these epidemiological burdens in many societies, investigation into the underlying molecular mechanisms behind these purported effects are still in their infancy. Particularly, the relationship between IF and genetic changes are poorly understood, which forms the basis of this research.

Project description:Genome-Wide Transcriptome Analysis Reveals Intermittent Fasting-Induced Metabolic Rewiring in the Liver

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Project description:Intermittent fasting is previously reported to exhibit neuroprotection against experimental ischemic stroke. However, the detailed understanding of protection mechanisms are lacking. By observing the overall transcriptomic changes in each timepoint of ischemic stroke would benefit the understanding of underlying active pathways and mechanisms. Here, we conduct experimental MCAO ischemic stroke on mice exposed to different daily intermittent fasting method to compare not only among the ischemic stroke timepoints but also the efficacy of different intermittent fasting interventions. Our current study presented the transcriptomic changes for the first time in specific timepoints of ischemic stroke as well as under the condition of intermittent fasting. A number of neuroprotective mechanisms-related genes were significantly affected by intermittent fasting conditions in differential manners.

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Project description:Transcriptome analysis reveals intermittent fasting-induced genetic changes in ischemic stroke

Project description:Intermittent fasting (IF) is a dietary regimen aimed to restrict energy intake via alternate periods of ad libitum food consumption and fasting, without compromise of nutritional composition intake. Prophylactic IF have been well-established in many animal studies to promote longevity as well as ameliorate the development and manifestation of age-related diseases such as cardiovascular, neurodegenerative as well as metabolic diseases. However, while vast experimental evidences have pointed out that IF is able to exert plethora effects against these diseases, understanding with regards to the underlying mechanisms remain in their infancy. Recently, an emerging area of research in the field of epigenetics have been shown to be a cornerstone in mediating the interaction between environmental factors and genome status. IF is a lifestyle intervention that may serves as potential environmental influences over the epigenome status of individuals. However, there is no current information available that shows that IF can induce epigenetic changes. Here, we show that IF is able to influence the modulation of histone H3 lysine 9 trimethylation (H3K9me3) epigenetic mark in C57/BL6 male mice cerebellum, which in turn helps to control a plethora of transcriptomic changes involved in robust metabolic switching processes commonly observed during IF. Interestingly, both epigenomic and transcriptomic modulation are still observed following a refeeding regimen, which may suggest the possibility of epigenetic maintenance induced by IF at this epigenetic locus. However, we found a loss of H3K9me3 maintenance of transcriptomic changes after abolishment of IF. Collectively, our study helps to characterize a novel mechanism of IF in the epigenetic-transcriptomic axis, which control a myriad of metabolic process changes that provide better understanding of IF-induced effects.

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Project description: Not available