Neuroprotective amyloid ß N-terminal peptides differentially alter human α7- and α7ß2-nicotinic acetylcholine (nACh) receptor single-channel properties.

BACKGROUND AND PURPOSE: Oligomeric amyloid ß 1-42 (oAß1-42) exhibits agonist-like action at human α7- and α7ß2-containing nicotinic receptors. The N-terminal amyloid ß1-15 fragment (N-Aß fragment) modulates presynaptic calcium and enhances hippocampal-based synaptic plasticity via α7-containing nicotinic receptors. Further, the N-Aß fragment and its core sequence, the N-amyloid-beta core hexapeptide (N-Aßcore), protect against oAß1-42-associated synapto- and neurotoxicity. Here, we investigated how oAß1-42, the N-Aß fragment, and the N-Aßcore regulate the single-channel properties of α7- and α7ß2-nicotinic receptors. EXPERIMENTAL APPROACH: Single-channel recordings measured the impact of acetylcholine, oAß1-42, the N-Aß fragment, and the N-Aßcore on the unitary properties of human α7- and α7ß2-containing nicotinic receptors expressed in nicotinic-null SH-EP1 cells. Molecular dynamics simulations identified potential sites of interaction between the N-Aß fragment and orthosteric α7+/α7- and α7+/ß2- nicotinic receptor binding interfaces. KEY RESULTS: The N-Aß fragment and N-Aßcore induced α7- and α7ß2-nicotinic receptor single-channel openings. Relative to acetylcholine, oAß1-42 preferentially enhanced α7ß2-nicotinic receptor single-channel open probability and open-dwell times. Co-application with the N-Aßcore neutralized these effects. Further, administration of the N-Aß fragment alone, or in combination with acetylcholine or oAß1-42, selectively enhanced α7-nicotinic receptor open probability and open-dwell times (compared to acetylcholine or oAß1-42). CONCLUSIONS AND IMPLICATIONS: Amyloid-beta peptides demonstrate functional diversity in regulating α7- and α7ß2-nicotinic receptor function, with implications for a wide range of nicotinic receptor-mediated functions in Alzheimer's disease. The effects of these peptides on α7- and/or α7ß2-nicotinic receptors revealed complex interactions with these subtypes, providing novel insights into the neuroprotective actions of amyloid ß-derived fragments against the toxic effects of oAß1-42.