Abstract
The C-terminal 40-residue t peptide of acetylcholinesterase (AChE) forms an amphiphilic alpha helix with a cluster of seven aromatic residues. It allows oligomerization and induces a partial degradation of AChE subunits through the endoplasmic reticulum-associated degradation pathway. We show that the t peptide induces the misfolding of a fraction of AChE subunits, even when mutations disorganized the cluster of aromatic residues or when these residues were replaced by leucines, indicating that this effect is due to hydrophobic residues. Mutations in the aromatic-rich region affected the cellular fate of AChE in a similar manner, with or without mutations that prevented dimerization. Degradation was decreased and secretion was increased when aromatic residues were replaced by leucines, and the opposite occurred when the amphiphilic alpha helix was disorganized. The last two residues (Asp-Leu) somewhat resembled an endoplasmic reticulum retention signal and caused a partial retention but only in mutants possessing aromatic residues in their t peptide. Our results suggested that several "signals" in the catalytic domain and in the t peptide act cooperatively for AChE quality control.
Highlights
The major function of acetylcholinesterase (AChE)1 is to regulate the cholinergic transmission by cleaving the neurotransmitter acetylcholine
We show that the t peptide induces the misfolding of a fraction of AChE subunits, even when mutations disorganized the cluster of aromatic residues or when these residues were replaced by leucines, indicating that this effect is due to hydrophobic residues
The presence of a t peptide induces an intracellular degradation of AChET subunits, which is strongly increased with the F535A mutation (AChE*), unless they assemble with a PRADcontaining N-terminal fragment of ColQ (QN), forming PRADlinked complexes
Summary
The major function of acetylcholinesterase (AChE)1 is to regulate the cholinergic transmission by cleaving the neurotransmitter acetylcholine. Influence of the Aromatic-rich Segment on Cellular and Secreted AChE Activities—Fig. 3 shows the levels of AChE activity obtained in cellular extracts and in the medium for the different mutants expressed in COS cells normalized to those obtained for the wild type AChET subunit.
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