Gunter P. Eckert scite author profile

As a fully differentiated organ, our brain is very sensitive to cumulative oxidative damage of proteins, lipids, and DNA occurring during normal aging because of its high energy metabolism and the relative low activity of antioxidative defense mechanisms. As a major consequence, perturbations of energy metabolism including mitochondrial dysfunction, alterations of signaling mechanisms and of gene expression culminate in functional deficits. With the increasing average life span of humans, age-related cognitive disorders such as Alzheimer's disease (AD) are a major health concern in our society. Age-related mitochondrial dysfunction underlies most neurodegenerative diseases, where it is potentiated by disease-specific factors. AD is characterized by two major histopathological hallmarks, initially intracellular and with the progression of the disease extracellular accumulation of oligomeric and fibrillar beta-amyloid peptides and intracellular neurofibrillary tangles composed of hyperphosphorylated tau protein. In this review, we focus on findings in AD animal and cell models indicating that these histopathological alterations induce functional deficits of the respiratory chain complexes and therefore consecutively result in mitochondrial dysfunction and oxidative stress. These parameters lead synergistically with the alterations of the brain aging process to typical signs of neurodegeneration in the later state of the disease, including synaptic dysfunction, loss of synapses and neurites, and finally neuronal loss. We suggest that mitochondrial protection and subsequent reduction of oxidative stress are important targets for prevention and long-term treatment of early stages of AD.

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Chronic Administration of Statins Alters Multiple Gene Expression Patterns in Mouse Cerebral Cortex

Johnson-Anuna

Eckert

Keller

et al. 2004

J Pharmacol Exp Ther

184

148

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Statins have been reported to lower the risk of developing Alzheimer's disease; however, the mechanism of this potentially important neuroprotective action is not understood. Lowering cholesterol levels does not appear to be the primary mechanism. Statins have pleiotropic effects in addition to lowering cholesterol, and statins may act on several different pathways involving distinct gene expression patterns that would be difficult to determine by focusing on a few genes or their products in a single study. In addition, gene expression patterns may be specific to a particular statin. To understand the molecular targets of statins in brain, DNA microarrays were used to identify gene expression patterns in the cerebral cortex of mice chronically treated with lovastatin, pravastatin, and simvastatin. Furthermore, brain statin levels were determined using liquid chromatography/tandem mass spectrometry. These studies revealed 15 genes involved in cell growth and signaling and trafficking that were similarly changed by all three statins. Overall, simvastatin had the greatest influence on expression as demonstrated by its ability to modify the expression of 23 genes in addition to those changed by all three drugs. Of particular interest was the expression of genes associated with apoptotic pathways that were altered by simvastatin. Reverse transcription-polymerase chain reaction experiments confirmed the microarray findings. All three drugs were detected in the cerebral cortex, and acute experiments revealed that statins are relatively rapidly removed from the brain. These results provide new insight into possible mechanisms for the potential efficacy of statins in reducing the risk of Alzheimer's disease and lay the foundation for future studies.

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Gunter P. Eckert

Mitochondrion-Derived Reactive Oxygen Species Lead to Enhanced Amyloid Beta Formation

Mitochondrial Dysfunction: Common Final Pathway in Brain Aging and Alzheimer’s Disease—Therapeutic Aspects

Chronic Administration of Statins Alters Multiple Gene Expression Patterns in Mouse Cerebral Cortex

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