AI Article Synopsis
- Researchers propose that the increase in intracellular calcium seen in cells exposed to the Abeta peptide (linked to Alzheimer's disease) is caused by calcium channels formed by the peptide itself.
- A peptide called NAHis04 effectively inhibits both the calcium currents induced by Abeta in artificial membranes and the resulting intracellular calcium increase in living cells.
- Modeling studies suggest that NAHis04 can block Abeta channels by binding to specific sites on the Abeta peptide, leading to significant implications for understanding calcium regulation in Alzheimer's disease.
Article Abstract
On the basis of the consistent demonstrations that the Abeta peptide of Alzheimer's disease forms calcium permeant channels in artificial membranes, we have proposed that the intracellular calcium increase observed in cells exposed to Abeta is initiated by calcium fluxes through Abeta channels. We have found that a small four-histidine peptide, NAHis04, potently inhibits the Abeta-induced calcium channel currents in artificial lipid membranes. Here we report that NaHis04 also potently blocks the intracellular calcium increase which is observed in cells exposed to Abeta. PC12 cells loaded with Fura-2AM show a rapid increase in fluorescence and a rapid return to baseline after Abeta is added to the medium. This fluorescence change occurs even when the medium contains nitrendipine, a voltage-gated calcium channel blocker, but fails to occur when application of Abeta is preceded by addition of NAHis04. Steep dose-response curves of the percentage of responding cells and cell viability show that NAHis04 inhibits in the micromolar range in an apparently cooperative manner. We have developed numerous models of Abeta pores in which the first part of the Abeta sequence forms a large beta-barrel ending at His 13. We have modeled how up to four NAHis04 peptides may block these types of pores by binding to side chains of Abeta residues Glu 11, His 13, and His 14.
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| http://dx.doi.org/10.1021/bi1006833 | DOI Listing |
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