Preethi Sheshadri scite author profile

Synaptic mitochondria are particularly vulnerable to physiological insults, and defects in synaptic mitochondria are linked to early pathophysiology of Alzheimer's disease (AD). Mitophagy, a cargo‐specific autophagy for elimination of dysfunctional mitochondria, constitutes a key quality control mechanism. However, how mitophagy ensures synaptic mitochondrial integrity remains largely unknown. Here, we reveal Rheb and Snapin as key players regulating mitochondrial homeostasis at synapses. Rheb initiates mitophagy to target damaged mitochondria for autophagy, whereas dynein–Snapin‐mediated retrograde transport promotes clearance of mitophagosomes from synaptic terminals. We demonstrate that synaptic accumulation of mitophagosomes is a feature in AD‐related mutant hAPP mouse brains, which is attributed to increased mitophagy initiation coupled with impaired removal of mitophagosomes from AD synapses due to defective retrograde transport. Furthermore, while deficiency in dynein–Snapin‐mediated retrograde transport recapitulates synaptic mitophagy stress and induces synaptic degeneration, elevated Snapin expression attenuates mitochondrial defects and ameliorates synapse loss in AD mouse brains. Taken together, our study provides new insights into mitophagy regulation of synaptic mitochondrial integrity, establishing a foundation for mitigating AD‐associated mitochondria deficits and synaptic damage through mitophagy enhancement.

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Making surrogate β-cells from mesenchymal stromal cells: Perspectives and future endeavors

Bhonde

Sheshadri

Sharma

et al. 2014

The International Journal of Biochemistry & Cell Biology

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Broad activation of the Parkin pathway induces synaptic mitochondrial deficits in early tauopathy

Jeong

Han

Jia

et al. 2022

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Mitochondrial defects are a hallmark of early pathophysiology in Alzheimer’s disease, with pathologically phosphorylated tau reported to induce mitochondrial toxicity. Mitophagy constitutes a key pathway in mitochondrial quality control by which damaged mitochondria are targeted for autophagy. However, few details are known regarding the intersection of mitophagy and pathologies in tauopathy. Here, by applying biochemical and cell biological approaches including time-lapse confocal imaging in live tauopathy neurons, combined with gene rescue experiments via stereotactic injections of adeno-associated virus particles into tauopathy mouse brains, electrophysiological recordings and behavioural tests, we demonstrate for the first time that mitochondrial distribution deficits at presynaptic terminals are an early pathological feature in tauopathy brains. Furthermore, Parkin-mediated mitophagy is extensively activated in tauopathy neurons, which accelerates mitochondrial Rho GTPase 1 (Miro1) turnover and consequently halts Miro1-mediated mitochondrial anterograde movement towards synaptic terminals. As a result, mitochondrial supply at tauopathy synapses is disrupted, impairing synaptic function. Strikingly, increasing Miro1 levels restores the synaptic mitochondrial population by enhancing mitochondrial anterograde movement and thus reverses tauopathy-associated synaptic failure. In tauopathy mouse brains, overexpression of Miro1 markedly elevates synaptic distribution of mitochondria and protects against synaptic damage and neurodegeneration, thereby counteracting impairments in learning and memory as well as synaptic plasticity. Taken together, our study reveals that activation of the Parkin pathway triggers an unexpected effect—depletion of mitochondria from synaptic terminals, a characteristic feature of early tauopathy. We further provide new mechanistic insights into how parkin activation-enhanced Miro1 degradation and impaired mitochondrial anterograde transport drive tauopathy-linked synaptic pathogenesis and establish a foundation for future investigations into new therapeutic strategies to prevent synaptic deterioration in Alzheimer’s disease and other tauopathies.

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Zic3 Enhances the Generation of Mouse Induced Pluripotent Stem Cells

Declercq

Sheshadri

Verfaillie

et al. 2013

Stem Cells and Development

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Zinc finger protein of the cerebellum (Zic)3, a member of Gli family of transcription factors (TFs), is essential for maintaining pluripotency of embryonic stem cells (ESCs) and has been reported to activate TF Nanog in an Oct4/Sox2-independent manner. Previously, we showed that Zic3 (Z), in combination with the Yamanka factors OCT4, SOX2, and KLF4 (OSK), induces neural progenitor-like cells from human fibroblasts. However, a similar combination of TFs (OSKZ) transduced in mouse embryonic fibroblasts resulted in enhanced induced pluripotent stem cells (iPSCs) formation compared with OSK alone, but not neuroprogenitors. OSKZ-derived iPSCs are indistinguishable from mESCs in colony morphology, expression of alkaline phosphatase and pluripotency genes, and embryoid body and teratoma formation. Zic3 activates the transcription of Nanog, a key pluripotency regulator, as evidenced by a luciferase promoter assay. During the course of iPSC derivation, Zic3-mediated enhanced expression of Nanog and Tbx3, gene known to enhance iPSCs derivation, is observed. Not only does Zic3 enhance the reprogramming efficiency, but also reactivation of the endogenous Zic3 protein is essential for the generation of iPSCs, as knockdown of Zic3 during the iPSC generation with OSKM significantly reduced the number of colonies. Together, our result uncovers an important role of Zic3 in generating mouse iPSCs.

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Paradoxical neuronal hyperexcitability in a mouse model of mitochondrial pyruvate import deficiency

Rossa

Laporte

Astori

et al. 2022

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Neuronal excitation imposes a high demand of ATP in neurons. Most of the ATP derives primarily from pyruvate-mediated oxidative phosphorylation, a process that relies on import of pyruvate into mitochondria occuring exclusively via the mitochondrial pyruvate carrier (MPC). To investigate whether deficient oxidative phosphorylation impacts neuron excitability, we generated a mouse strain carrying a conditional deletion of MPC1, an essential subunit of the MPC, specifically in adult glutamatergic neurons. We found that, despite decreased levels of oxidative phosphorylation and decreased mitochondrial membrane potential in these excitatory neurons, mice were normal at rest. Surprisingly, in response to mild inhibition of GABA mediated synaptic activity, they rapidly developed severe seizures and died, whereas under similar conditions the behavior of control mice remained unchanged. We report that neurons with a deficient MPC were intrinsically hyperexcitable as a consequence of impaired calcium homeostasis, which reduced M-type potassium channel activity. Provision of ketone bodies restored energy status, calcium homeostasis and M-channel activity and attenuated seizures in animals fed a ketogenic diet. Our results provide an explanation for the seizures that frequently accompany a large number of neuropathologies, including cerebral ischemia and diverse mitochondriopathies, in which neurons experience an energy deficit.

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