Drug discovery heavily relies on cell viability studies to assess the potential toxicity of drug candidates. L-Lactate dehydrogenase (LDH) is a cytoplasmic enzyme that catalyzes the concomitant interconversions of pyruvate to L-lactate and NADH to NAD+ during glycolysis, and the reverse reactions during the Cori cycle (Decker and Lohmann-Matthes, 1988; Nachlas et al., 1960). In response to cellular damage, induced by endogenous cellular mechanisms or as a result of exogenously applied insults, LDH is released from the cytoplasm into the extracellular environment. Its stability in cell culture medium makes it a well-suited correlate for the presence of damage and toxicity in tissues and cells (Stoddart, 2011). We herein present protocols for a reproducible and validated LDH assay optimized for several cell types. In contrast to commercially available LDH assays often associated with proprietary formulations and high cost, our protocols provide ample opportunities for experiment-specific optimization with low variability and cost.
Resveratrol is a naturally occurring compound contributing to cellular defense mechanisms in plants. Its use as a nutritional component and/or supplement in a number of diseases, disorders, and syndromes such as chronic diseases of the central nervous system, cancer, inflammatory diseases, diabetes, and cardiovascular diseases has prompted great interest in the underlying molecular mechanisms of action. The present review focuses on resveratrol, specifically its isomer trans-resveratrol, and its effects on intracellular calcium signaling mechanisms. As resveratrol's mechanisms of action are likely pleiotropic, its effects and interactions with key signaling proteins controlling cellular calcium homeostasis are reviewed and discussed. The clinical relevance of resveratrol's actions on excitable cells, transformed or cancer cells, immune cells and retinal pigment epithelial cells are contrasted with a review of the molecular mechanisms affecting calcium signaling proteins on the plasma membrane, cytoplasm, endoplasmic reticulum, and mitochondria. The present review emphasizes the correlation between molecular mechanisms of action that have recently been identified for resveratrol and their clinical implications.
The molecular pathways contributing to visual signal transduction in the retina generate a high energy demand that has functional and structural consequences such as vascularization and high metabolic rates contributing to oxidative stress. Multiple signaling cascades are involved to actively regulate the redox state of the retina. Age-related processes increase the oxidative load, resulting in chronically elevated levels of oxidative stress and reactive oxygen species, which in the retina ultimately result in pathologies such as glaucoma or age-related macular degeneration, as well as the neuropathic complications of diabetes in the eye. Specifically, oxidative stress results in deleterious changes to the retina through dysregulation of its intracellular physiology, ultimately leading to neurodegenerative and potentially also vascular dysfunction. Herein we will review the evidence for oxidative stress-induced contributions to each of the three major ocular pathologies, glaucoma, age-related macular degeneration, and diabetic retinopathy. The premise for neuroprotective strategies for these ocular disorders will be discussed in the context of recent clinical and preclinical research pursuing novel therapy development approaches.
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