Therapeutic Potential of Mitophagy-Inducing Microflora Metabolite, Urolithin A for Alzheimer's Disease.

Mitochondrial dysfunction including deficits of mitophagy is seen in aging and neurodegenerative disorders including Alzheimer's disease (AD). Apart from traditionally targeting amyloid beta (Aß), the main culprit in AD brains, other approaches include investigating impaired mitochondrial pathways for potential therapeutic benefits against AD. Thus, a future therapy for AD may focus on novel candidates that enhance optimal mitochondrial integrity and turnover. Bioactive food components, known as nutraceuticals, may serve as such agents to combat AD. Urolithin A is an intestinal microbe-derived metabolite of a class of polyphenols, ellagitannins (ETs). Urolithin A is known to exert many health benefits. Its antioxidant, anti-inflammatory, anti-atherogenic, anti-Aß, and pro-mitophagy properties are increasingly recognized. However, the underlying mechanisms of urolithin A in inducing mitophagy is poorly understood. This review discusses the mitophagy deficits in AD and examines potential molecular mechanisms of its activation. Moreover, the current knowledge of urolithin A is discussed, focusing on its neuroprotective properties and its potential to induce mitophagy. Specifically, this review proposes potential mechanisms by which urolithin A may activate and promote mitophagy.

Reduction of inclusion body pathology in ApoE-deficient mice fed a combination of antioxidants.

Clinical studies have shown that the antioxidant vitamin E can slow the progression of Alzheimer's disease (AD). Other antioxidants reported to affect cognitive function include ginkgo biloba, vitamin C, and lipoic acid. To examine the effects of combination antioxidant therapy (CAT) on longevity and neuropathology in mice, we supplemented the diet of ApoE-deficient mice with vitamin E, ginkgo biloba, pycnogenol, and ascorbyl palmitate. ApoE-deficient mice normally exhibit increased numbers of PAS-positive inclusion bodies with aging. However, supplementation with CAT resulted in a significant increase in life span and a marked reduction of inclusion body histopathology in the hippocampus. In addition, while untreated apoE-deficient mice exhibited increased levels of TUNEL staining, a marker of DNA fragmentation, supplementation with CAT resulted in a significant reduction in the levels of TUNEL staining. These findings suggest that oxidative mechanisms, perhaps related to neuronal apoptosis, are integral to inclusion body formation in aging mice. The association between the reduced number of apoptotic cells and the reduction in inclusion bodies may explain in part the increased longevity of mice fed CAT, and supports the contention that the combined actions of selected antioxidants may be therapeutically effective against neurodegenerative diseases.