AI Article Synopsis
- The study identifies a subpopulation of cells that show resistance to Abeta toxicity even after prolonged exposure, similar to changes seen in specific brain regions affected by Alzheimer's disease.
- Using techniques like flow cytometry, researchers were able to separate and analyze Abeta-sensitive and resistant cell types, revealing that sensitivity is linked to the binding of Abeta to cell membranes.
- Key cell features such as apoptotic signals, cell size, cell cycle stage, and ATP levels play crucial roles in determining a cell's sensitivity to Abeta, with those showing high binding affinity exhibiting more severe responses like increased calcium activity and cell death.
Article Abstract
Measurement of Abeta toxicity of cells in culture exposes a subpopulation of cells with resistance to Abeta, even at high concentrations and after long periods of treatment. The cell-selective toxicity of Abeta resembles the selective damage observed in cells of specific regions of the Alzheimer's disease (AD) brain and suggests that there must be particular characteristics or stages of these cells that make them exceptionally sensitive or resistant to the effect of Abeta. Using flow cytometry and cell sorting, we efficiently separated and analyzed the Abeta-sensitive and the Abeta-resistant subpopulations within a variety of neuronal cell lines (PC12, GT1-7) and primary cultured neurons (hippocampal, cortex). We found that this distinctive sensitivity to Abeta was essentially associated with cell membrane Abeta binding. This selective Abeta binding was correlated to distinctive cell characteristics, such as cell membrane exposure of the apoptotic signal molecule phosphatidyl serine, larger cell size, the G1 cell cycle stage, and a lower than normal cytosolic ATP level. The response to Abeta by the cells with high Abeta binding affinity was characterized by a larger calcium response and increased mortality, lactate dehydrogenase release, caspase activation, and DNA fragmentation. The distinctive sensitivity or resistance to Abeta of the different subpopulations was maintained even after multiple cell divisions. We believe that these distinctive cell characteristics are the determining factors for the selective attack of Abeta on cells in culture and in the AD brain.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6673638 | PMC |
| http://dx.doi.org/10.1523/JNEUROSCI.3006-07.2007 | DOI Listing |
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