Tuning
Reactivity of Diphenylpropynone Derivatives with Metal-Associated
Amyloid‑β Species via Structural Modifications
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Abstract
A diphenylpropynone derivative, <b>DPP2</b>, has been recently demonstrated to target metal-associated
amyloid-β (metal–Aβ) species implicated in Alzheimer’s
disease (AD). <b>DPP2</b> was shown to interact with metal–Aβ
species and subsequently control Aβ aggregation (reactivity)
in vitro; however, its cytotoxicity has limited further biological
applications. In order to improve reactivity toward Aβ species
and lower cytotoxicity, along with gaining an understanding of a structure-reactivity-cytotoxicity
relationship, we designed, prepared, and characterized a series of
small molecules (<b>C1</b>/<b>C2</b>, <b>P1</b>/<b>P2</b>, and <b>PA1</b>/<b>PA2</b>) as structurally
modified <b>DPP2</b> analogues. A similar metal binding site
to that of <b>DPP2</b> was contained in these compounds while
their structures were varied to afford different interactions and
reactivities with metal ions, Aβ species, and metal–Aβ
species. Distinct reactivities of our chemical family toward in vitro
Aβ aggregation in the absence and presence of metal ions were
observed. Among our chemical series, the compound (<b>C2</b>) with a relatively rigid backbone and a dimethylamino group was
observed to noticeably regulate both metal-free and metal-mediated
Aβ aggregation to different extents. Using our compounds, cell
viability was significantly improved, compared to that with <b>DPP2</b>. Lastly, modifications on the <b>DPP</b> framework
maintained the structural properties for potential blood-brain barrier
(BBB) permeability. Overall, our studies demonstrated that structural
variations adjacent to the metal binding site of <b>DPP2</b> could govern different metal binding properties, interactions with
Aβ and metal–Aβ species, reactivity toward metal-free
and metal-induced Aβ aggregation, and cytotoxicity of the compounds,
establishing a structure-reactivity-cytotoxicity relationship. This
information could help gain insight into structural optimization for
developing nontoxic chemical reagents toward targeting metal–Aβ
species and modulating their reactivity in biological systems