Using leucine zipper to facilitate alpha-synuclein assembly.

The accumulation of filamentous alpha-synuclein (alpha-S) is associated with Parkinson's disease. It remains controversial as to the mode (antiparallel or parallel) of alpha-S self-assembly and whether an exact alignment of the central hydrophobic region is essential. In the present study, we performed in vitro assembly using alpha-S with or without the attachment of artificial leucine zippers (Zips) capable of forming either parallel or antiparallel coiled coils and included a spacer in one derivative. Results showed that Zips accelerate filament assembly in both the parallel and antiparallel fashions, that a precise alignment of the central hydrophobic region is not essential, and that the antiparallel pairs displayed the highest thioflavin T signals. More importantly, cells expressing Zip-fused alpha-S, but not alpha-S alone, formed alpha-S immunopositive and thioflavin S-positive inclusions in 7 days. The results suggest that alpha-S can assemble in both parallel and antiparallel modes but have a higher tendency to assemble in the latter mode and that cells overexpressing Zip-fused alpha-S may be used to screen alpha-S assembly inhibitors due to enhanced ability to form inclusions.

Overexpression of nicastrin increases Abeta production.

Gamma-secretase cleavage is the final proteolytic step that releases the amyloid beta-peptide (Abeta) from the amyloid beta-protein precursor (APP). Significant evidence indicates that the presenilins (PS) are catalytic components of a high molecular weight gamma-secretase complex. The glycoprotein nicastrin was recently identified as a functional unit of this complex based on 1) binding to PS and 2) the ability to modulate Abeta production following mutation of a conserved DYIGS region. In contrast to the initial report, we find that overexpression of wild-type (WT) nicastrin increases Abeta production, whereas DYIGS mutations (MT) have little or no effect. The increase in Abeta production is associated with an increase in gamma-secretase activity but not with a detectable increase in PS1 levels. Subcellular fractionation studies show that WT but not MT nicastrin matures into buoyant membrane fractions enriched in gamma-secretase activity. These data support the hypothesis that nicastrin is an essential component of the gamma-secretase complex. The finding that WT nicastrin overexpression can increase gamma-secretase activity without altering levels of the presumed catalytic component (PS) of the enzyme may point to a role for nicastrin in facilitating cleavage by regulating substrate interactions with the gamma-secretase complex.