Tannu Dhingra’s research while affiliated with National Institute of Pharmaceutical Education And Research Ahmedabad and other places

The progressive brain damage following ischemic stroke is primarily due to oxidative stress and activation of inflammatory pathways. Post-stroke neurodegeneration can lead to the loss of neurons and glial cells, including oligodendrocytes, contributing to demyelination. Following ischemic stroke, reperfusion results in increased intracellular calcium, generation of free radicals, and inflammation culminating in accumulation of misfolded proteins in the endoplasmic reticulum (ER) lumen augmenting the ER stress. ER stress has been shown to aggravate post-stroke neurodegeneration by triggering neuronal apoptosis and also contributing towards demyelination of neurons. To address the limitations of current stroke therapies, repurposing of drugs as future adjunctive therapy may be promising. Clemastine, an antihistaminic drug, improves post stroke outcome as evident in the present study. Male Sprague Dawley (SD) rats were treated with clemastine following ischemic stroke. Harvested brain tissues were subjected to different biochemical assays, molecular assays, and histopathological analysis. Clemastine was able to reduce infarct size, alleviate oxidative stress, improve neuronal count, and functional outcomes. Clemastine downregulated genes and proteins responsible for ER stress, apoptosis and demyelination as shown by the western blot and qPCR results. Our study suggests that clemastine may alleviate endoplasmic reticulum stress-mediated demyelination by modulating PERK/ATF4/CHOP axis, and may be used as one of the adjunctive therapies for stroke in future.

Eukaryotic cells utilize oxygen for different functions of cell organelles owing to cellular survival. A balanced oxygen homeostasis is an essential requirement to maintain the regulation of normal cellular systems. Any changes in the oxygen level are stressful and can alter the expression of different homeostasis regulatory genes and proteins. Lack of oxygen or hypoxia results in oxidative stress and formation of hypoxia inducible factors (HIF) and reactive oxygen species (ROS). Substantial cellular damages due to hypoxia have been reported to play a major role in various pathological conditions. There are different studies which demonstrated that the functions of cellular system are disrupted by hypoxia. Currently, study on cellular effects following hypoxia is an important field of research as it not only helps to decipher different signaling pathway modulation, but also helps to explore novel therapeutic strategies. On the basis of the beneficial effect of hypoxia preconditioning of cellular organelles, many therapeutic investigations are ongoing as a promising disease management strategy in near future. Hence, the present review discusses about the effects of hypoxia on different cellular organelles, mechanisms and their involvement in the progression of different diseases.