Solid-state NMR evidence for ß-hairpin structure within MAX8 designer peptide nanofibers.

MAX8, a designer peptide known to undergo self-assembly following changes in temperature, pH, and ionic strength, has demonstrated usefulness for tissue engineering and drug delivery. It is hypothesized that the self-assembled MAX8 nanofiber structure consists of closed ß-hairpins aligned into antiparallel ß-sheets. Here, we report evidence from solid-state NMR spectroscopy that supports the presence of the hypothesized ß-hairpin conformation within the nanofiber structure. Specifically, our (13)C-(13)C two-dimensional exchange data indicate spatial proximity between V3 and K17, and (13)C-(13)C dipolar coupling measurements reveal proximity between the V3 and V18 backbone carbonyls. Moreover, isotopic dilution of labeled MAX8 nanofibers did not result in a loss of the (13)C-(13)C dipolar couplings, showing that these couplings are primarily intramolecular. NMR spectra also indicate the existence of a minor conformation, which is discussed in terms of previously hypothesized nanofiber physical cross-linking and possible nanofiber polymorphism.

Traffic jam at the blood-brain barrier promotes greater accumulation of Alzheimer's disease amyloid-ß proteins in the cerebral vasculature.

Amyloid-ß (Aß) deposition in the brain vasculature results in cerebral amyloid angiopathy (CAA), which occurs in about 80% of Alzheimer's disease (AD) patients. While Aß42 predominates parenchymal amyloid plaques in AD brain, Aß40 is prevalent in the cerebrovascular amyloid. Dutch mutation of Aß40 (E22Q) promotes aggressive cerebrovascular accumulation and leads to severe CAA in the mutation carriers; knowledge of how DutchAß40 drives this process more efficiently than Aß40 could reveal various pathophysiological events that promote CAA. In this study we have demonstrated that DutchAß40 shows preferential accumulation in the blood-brain-barrier (BBB) endothelial cells due to its inefficient blood-to-brain transcytosis. Consequently, DutchAß40 establishes a permeation barrier in the BBB endothelium, prevents its own clearance from the brain, and promotes the formation of amyloid deposits in the cerebral microvessels. The BBB endothelial accumulation of native Aß40 is not robust enough to exercise such a significant impact on its brain clearance. Hence, the cerebrovascular accumulation of Aß40 is slow and may require other copathologies to precipitate into CAA. In conclusion, the magnitude of Aß accumulation in the BBB endothelial cells is a critical factor that promotes CAA; hence, clearing vascular endothelium of Aß proteins may halt or even reverse CAA.