Apoptosis, programmed cell death type I, is a critical part of neurodegeneration in cerebral ischemia, Parkinson’s, and Alzheimer’s disease. Apoptosis begins with activation of pro-death proteins Bax and Bak, release of cytochrome c and activation of caspases, loss of membrane integrity of intracellular organelles, and ultimately cell death. Approaches that block apoptotic pathways may prevent or delay neurodegenerative processes. Carotenoids are a group of pigments found in fruits, vegetables, and seaweeds that possess antioxidant properties. Over the last several decades, an increasing number of studies have demonstrated a protective role of carotenoids in neurodegenerative disease. In this review, we describe functions of commonly consumed carotenoids including lycopene, β-carotene, lutein, astaxanthin, and fucoxanthin and their roles in neurodegenerative disease models. We also discuss the underlying cellular mechanisms of carotenoid-mediated neuroprotection, including their antioxidant properties, role as signaling molecules, and as gene regulators that alleviate apoptosis-associated brain cell death.
Objectives Oxidative stress plays an important role in neuronal loss associated with mitochondrial dysfunction. Excess reactive oxygen species (ROS) production damages mitochondria, impairing neuronal energy metabolism. The damaged mitochondria promote aberrant ROS production leading to neuronal death. Fucoxanthin, a carotenoid with antioxidant properties primarily found in brown seaweeds, has been shown to protect mitochondria in various disease models. However, limited studies have demonstrated the mechanisms of fucoxanthin-mediated neuroprotection. In this study, we hypothesize that fucoxanthin regulates DJ-1, an oxidative stress sensing protein, and protects neurons against ROS-mediated mitochondrial dysfunction. Methods Rat primary hippocampal neurons were treated with fucoxanthin, hydrogen peroxide, or a combination of both. After 6 h of incubation, mitochondrial superoxide and the mitochondrial membrane potential were measured using mitoSOX and TMRM, respectively. Middle-aged male Sprague Dawley rats were supplemented with or without fucoxanthin (1 mg/kg, 5 d/w for 4 wk). After supplementation was completed, brain tissues were harvested, and DJ-1 protein levels were quantified using immunoblotting. Results Treatment with fucoxanthin decreased mitochondrial superoxide accumulation and prevented loss of mitochondrial membrane potential against ROS challenge in rat primary hippocampal neurons. Oral supplementation of fucoxanthin increased DJ-1 protein levels in the hippocampal tissues isolated from middle-aged rats. Conclusions We found that fucoxanthin treatment upregulates DJ-1 expression in the hippocampus in vivo and protects mitochondria during ROS challenges in primary hippocampal neurons in vitro. Our data suggest fucoxanthin has neuroprotective potential against ROS-associated mitochondrial dysfunction. Funding Sources RGC Program (University of Alabama); Crenshaw Research Fund (University of Alabama).
The Role of Alpha-Tocotrienol during Development of Primary Hippocampal Neurons
Objectives Alpha-tocotrienol (α-TCT), a form of vitamin E, is a lipophilic antioxidant with neuroprotective properties. We recently reported that α-TCT treatment prevents oxidative stress-induced proteolytic cleavage of B-cell lymphoma-extra large (Bcl-xL), a pro-survival mitochondrial protein necessary during neuronal growth. However, it is still unclear if α-TCT exhibits beneficial effects during the physiological development of neurons. In this study, we hypothesized that chronic α-TCT treatment advances the development of primary hippocampal neurons by improving mitochondrial function. Methods Primary rat hippocampal neurons were grown in neurobasal media with or without α-TCT for three weeks, and media was replaced with conditioned media containing fresh α-TCT every week. Intracellular α-TCT levels were quantified using HPLC-MS, and intracellular ATP and mitochondrial superoxide levels were determined using luciferase and mitoSOX, respectively. Neurite morphology was examined by Sholl analysis. mRNA and protein levels of Bcl-xL were quantified using qPCR and immunoblotting, respectively. Results Primary hippocampal neurons grown in media containing α-TCT had increased intracellular α-TCT levels and decreased mitochondrial superoxide. Treatment with α-TCT increased mRNA and protein levels of Bcl-xL, neuronal ATP, and the number of neurite branches in primary hippocampal neurons. Conclusions We found that primary rat hippocampal neurons treated with α-TCT developed advanced neurite complexity. We suggest that α-TCT treatment improves mitochondrial function via upregulation of Bcl-xL, supporting normal neuron development. Funding Sources RGC Program (University of Alabama); Crenshaw Research Fund (University of Alabama).
Vitamin E Improves Neurite Complexity by Enhancing Mitochondrial Function
Objectives Neurite outgrowth is a foundational process in brain development and recovery from brain injury. Assembly of the cytoskeleton and formation of new synapses during neurite outgrowth requires an abundance of energy. We have reported that the mitochondrial protein Bcl-xL is necessary for neurite outgrowth and arborization. However, Bcl-xL undergoes post-translational cleavage during oxidative stress resulting in a product that impairs mitochondrial function. Our recent publication demonstrated that treatment with alpha-tocotrienol, an antioxidant member of the vitamin E family, prevents cleavage of Bcl-xL and protects neurons from oxidative stress. In this study, we hypothesize that treatment with alpha-tocotrienol improves mitochondrial function to support the energy demanding processes of growth and development in the neurons. Methods Primary hippocampal neurons were grown in neurobasal media with or without alpha-tocotrienol for 3 weeks. Then, the number of neurite branches was quantified applying Sholl analysis. We also assayed the ATP/ADP ratio at neurites using the PercevalHR fluorescence biosensor. mRNA and protein levels of total Bcl-xL and cleaved Bcl-xL were measured using real time PCR and immunoblotting. Results Neurons grown with alpha-tocotrienol achieved more advanced neurite complexity than the control group. Treatment with alpha-tocotrienol enhanced both total ATP and local neurite ATP levels in primary hippocampal neurons. Furthermore, we found that alpha-tocotrienol Increased mRNA and protein levels of Bcl-xL without enhancing post-translational cleavage of Bcl-xL, consistent with our previous study. Conclusions Our data show that alpha-tocotrienol improves mitochondria-mediated ATP production by enhancing Bcl-xL to support metabolically demanding processes in neurons. We suggest a novel function of alpha-tocotrienol in normal physiological development of the brain. This study also suggests a potential therapeutic role of alpha-tocotrienol in brain diseases associated with neurite injury. Funding Sources RGC Program (University of Alabama) Crenshaw Research Fund (University of Alabama).
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