Neural stem cell-derived exosomes promote mitochondrial biogenesis and restore abnormal protein distribution in a mouse model of Alzheimer's disease

Mitochondrial dysfunction is a hallmark of Alzheimer’s disease.We previously showed that neural stem cell-derived extracellular vesicles improved mitochondrial function in the cortex of AP P/PS1 mice.Because Alzheimer’s disease affects the entire brain,further research is needed to elucidate alterations in mitochondrial metabolism in the brain as a whole.Here,we investigated the expression of several important mitochondrial biogenesis-related cytokines in multiple brain regions after treatment with neural stem cell-derived exosomes and used a combination of whole brain clearing,immunostaining,and lightsheet imaging to clarify their spatial distribution.Additionally,to clarify whether the sirtuin 1(SIRT1)-related pathway plays a regulatory role in neural stem cell-de rived exosomes interfering with mitochondrial functional changes,we generated a novel nervous system-SIRT1 conditional knoc kout AP P/PS1mouse model.Our findings demonstrate that neural stem cell-de rived exosomes significantly increase SIRT1 levels,enhance the production of mitochondrial biogenesis-related fa ctors,and inhibit astrocyte activation,but do not suppress amyloid-βproduction.Thus,neural stem cell-derived exosomes may be a useful therapeutic strategy for Alzheimer’s disease that activates the SIRT1-PGC1αsignaling pathway and increases NRF1 and COXIV synthesis to improve mitochondrial biogenesis.In addition,we showed that the spatial distribution of mitochondrial biogenesis-related factors is disrupted in Alzheimer’s disease,and that neural stem cell-derived exosome treatment can reverse this effect,indicating that neural stem cell-derived exosomes promote mitochondrial biogenesis.

Combining CUBIC Optical Clearing and Thy1-YFP-16 Mice to Observe Morphological Axon Changes During Wallerian Degeneration

Objective:Wallerian degeneration is a pathological process closely related to peripheral nerve regeneration following injury,and includes the disintegration and phagocytosis of peripheral nervous system cells.Traditionally,morphological changes are observed by performing immunofluorescence staining after sectioning,which results in the loss of some histological information.The purpose of this study was to explore a new,nondestmetive,and systematic method for observing axonal histological changes during Wallerian degeneration.Methods:Thirty male Thy1-YFP-16 mice(SPF grade,6 weeks old,20±5 g)were randomly selected and divided into clear,unobstructed brain imaging cocktails and computational analysis(CUBIC)optical clearing(n=15)and traditional method groups(n=15).Five mice in each group were sacrificed at 1st,3rd,and 5th day following a crush operation.The histological axon changes were observed by CUBIC light optical clearing treatment,direct tissue section imaging,and HE staining.Results:The results revealed that,compared with traditional imaging methods,there was no physical damage to the samples,which allowed for three-dimensional and deep-seated tissue imaging through CUBIC.Local image information could be nicely obtained by direct fluorescence imaging and HE staining,but it was difficult to obtain image information of the entire sample.At the same time,the image information obtained by fluorescence imaging and HE staining was partially lost.Conclusion:The combining of CUBIC and Thy1-YFP transgenic mice allowed for a clear and comprehensive observation of histological changes of axons in Wallerian degeneration.