Mitochondrial aconitase 1 regulates age‐related memory impairment via autophagy/mitophagy‐mediated neural plasticity in middle‐aged flies

Age‐related memory impairment (AMI) occurs in many species, including humans. The underlying mechanisms are not fully understood. In wild‐type Drosophila (w1118), AMI appears in the form of a decrease in learning (3‐min memory) from middle age (30 days after eclosion [DAE]). We performed in vivo, DN...

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Bibliographic Details
Published in:Aging cell 2021-12, Vol.20 (12), p.e13520-n/a
Main Authors: Cho, Yun‐Ho, Kim, Gye‐Hyeong, Park, Joong‐Jean
Format: Article
Language:English
Subjects:
aconitase
Aconitate Hydratase - metabolism
Age
age‐related memory disorders
Animals
Autophagy
Citric acid
DNA microarrays
Eclosion
Humans
Learning
Life span
Memory Disorders - genetics
Middle Aged
Mitochondria
Mitochondria - metabolism
Mitophagy
Mitophagy - genetics
Mushroom bodies
neural plasticity
Neuronal Plasticity - genetics
Neuroplasticity
Original Paper
Original Papers
Phagocytosis
PTEN-induced putative kinase
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Summary:Age‐related memory impairment (AMI) occurs in many species, including humans. The underlying mechanisms are not fully understood. In wild‐type Drosophila (w1118), AMI appears in the form of a decrease in learning (3‐min memory) from middle age (30 days after eclosion [DAE]). We performed in vivo, DNA microarray, and behavioral screen studies to identify genes controlling both lifespan and AMI and selected mitochondrial Acon1 (mAcon1). mAcon1 expression in the head of w1118 decreased with age. Neuronal overexpression of mAcon1 extended its lifespan and improved AMI. Neuronal or mushroom body expression of mAcon1 regulated the learning of young (10 DAE) and middle‐aged flies. Interestingly, acetyl‐CoA and citrate levels increased in the heads of middle‐aged and neuronal mAcon1 knockdown flies. Acetyl‐CoA, as a cellular energy sensor, is related to autophagy. Autophagy activity and efficacy determined by the positive and negative changes in the expression levels of Atg8a‐II and p62 were proportional to the expression level of mAcon1. Levels of the presynaptic active zone scaffold protein Bruchpilot were inversely proportional to neuronal mAcon1 levels in the whole brain. Furthermore, mAcon1 overexpression in Kenyon cells induced mitophagy labeled with mt‐Keima and improved learning ability. Both processes were blocked by pink1 knockdown. Taken together, our results imply that the regulation of learning and AMI by mAcon1 occurs via autophagy/mitophagy‐mediated neural plasticity. As aging progresses, the expression of the TCA enzyme mAcon1 decreases. Accordingly, the amounts of citrate and acetyl‐CoA increase, and the increased acetyl‐CoA inhibits autophagy/mitophagy. After that, synaptic plasticity is reduced by decreased autophagy/mitophagy, and as a result, AMI appears in middle‐aged flies.
ISSN:1474-9718
1474-9726
DOI:10.1111/acel.13520