Abstract
Established disease models have helped unravel the mechanistic underpinnings of pathological phenotypes in Parkinson’s disease (PD), the second most common neurodegenerative disorder. However, these discoveries have been limited to relatively simple cellular systems and animal models, which typically manifest with incomplete or imperfect recapitulation of disease phenotypes. The advent of induced pluripotent stem cells (iPSCs) has provided a powerful scientific tool for investigating the underlying molecular mechanisms of both familial and sporadic PD within disease-relevant cell types and patient-specific genetic backgrounds. Overwhelming evidence supports mitochondrial dysfunction as a central feature in PD pathophysiology, and iPSC-based neuronal models have expanded our understanding of mitochondrial dynamics in the development and progression of this devastating disorder. The present review provides a comprehensive assessment of mitochondrial phenotypes reported in iPSC-derived neurons generated from PD patients’ somatic cells, with an emphasis on the role of mitochondrial respiration, morphology, and trafficking, as well as mitophagy and calcium handling in health and disease. Furthermore, we summarize the distinguishing characteristics of vulnerable midbrain dopaminergic neurons in PD and report the unique advantages and challenges of iPSC disease modeling at present, and for future mechanistic and therapeutic applications.
Highlights
The brain is responsible for nearly 20% of the body’s energy consumption, which is remarkable considering that it represents a mere 2% of total body mass [1]
A study using human fibroblasts and induced pluripotent stem cells (iPSCs)-derived dopaminergic neurons demonstrated that LRRK2 forms a complex with Miro1 as a precondition for its removal from damaged mitochondria, a process that is disrupted in LRRK2 G2019S Parkinson’s disease (PD) patient models [119]
One of the greatest breakthroughs of regenerative medicine in this century was the discovery of iPSC technology in 2006 by Shinya Yamanaka and Kazutoshi Takahashi
Summary
The brain is responsible for nearly 20% of the body’s energy consumption, which is remarkable considering that it represents a mere 2% of total body mass [1]. Mitochondria regulate neuronal health and function by buffering calcium (Ca2+) transients from both extracellular sources and intracellular storage organelles like the endoplasmic reticulum (ER), protecting against Ca2+ overload and encoding these complex electrochemical signals into coordinated neurotransmission [5]. To accomplish this and to meet the energy demands of distinct neuronal microdomains, mitochondrial transport along axonal microtubules is tightly regulated in both retrograde and anterograde directions. In this article we present a comprehensive review of studies on mitochondrial phenotypes in iPSC-derived neuronal models of PD, and how this may contribute to the disease-specific degeneration of susceptible neuronal populations in PD
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