Margarida P. Pereira scite author profile

Margarida P. Pereira

3Publications

60Citation Statements Received

73Citation Statements Given

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138

Affiliations

University of Lisbon

Publications

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Synthesis and Biological Evaluation of Structurally Varied 5′-/6′-Isonucleosides and Theobromine-Containing N-Isonucleosidyl Derivatives

et al. 2019

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Isonucleosides are rather stable regioisomeric analogs of nucleosides with broad therapeutic potential. We have previously demonstrated the ability of 5′ and 6′-isonucleosides to inhibit the activity of acetylcholinesterase, a major target for Alzheimer’s disease therapy. Continuing with our research on this topic, we report herein on the synthesis and biological evaluation of a variety of novel terminal isonucleosides and theobromine isonucleotide analogs. Xylofuranose-based purine or uracil 5′-isonucleosides and xylofuranos-5′-yl or glucos-6′-yl theobromine derivatives were accessed via Mitsunobu coupling between partially protected xylofuranose or glucofuranose derivatives with a nucleobase using conventional or microwave-assisted heating conditions. Theobromine-containing N-isonucleosidyl sulfonamide and phosphoramidate derivatives were synthesized from isonucleosidyl acetate precursors. The most active compounds in the cholinesterase inhibition assays were a glucopyranose-based theobromine isonucleosidyl acetate, acting as a dual inhibitor of acetylcholinesterase (AChE, Ki = 3.1 µM) and butyrylcholinesterase (BChE, Ki = 5.4 µM), and a 2-O,4-O-bis-xylofuranos-5′-yl uracil derivative, which displayed moderate inhibition of AChE (Ki = 17.5 µM). Docking studies revealed that the active molecules are positioned at the gorge entrance and at the active site of AChE. None of the compounds revealed cytoxic activity to cancer cells as well as to non-malignant mouse fibroblasts.

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Cultivar variability of iron uptake mechanisms in rice (Oryza sativa L.)

Pereira¹,

Santos²,

Gomes³

et al. 2014

Plant Physiology and Biochemistry

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Furanosyl Nucleoside Analogues Embodying Triazole or Theobromine Units as Potential Lead Molecules for Alzheimer's Disease

et al. 2018

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The synthesis of novel types of furanosyl nucleoside analogues, namely N‐(benzyltriazolyl)methyl glucuronamide derivatives, N‐dodecyl glucuronamide‐based phenyltriazole nucleosides, and theobromine xylosyl 5′‐isonucleosides, as potential cholinesterase inhibitors is described herein. O‐Substituted and partially O‐substituted N‐propargyl glucuronamides, accessed from glucofuranurono‐6,3‐lactone, were engaged in CuI‐catalyzed cycloaddition with benzyl azide, whereas their N‐dodecyl uronamide counterparts were converted in three steps into glycosyl azides, which were subjected to cycloaddition with phenylacetylene. A xylofuranose derivative having a free 5‐OH group was coupled with theobromine by Mitsunobu reaction and the obtained isonucleoside was functionalized at C‐1′ with a sulfonamide moiety, leading to a prospective nucleotide mimetic. Five compounds displayed selective inhibition of acetylcholinesterase in the micromolar concentration range, with an α‐glycosyl triazole (Ki = 3.53 µm) and its 1‐azido‐uronamide precursor (Ki = 1.73 µm) being the most active. Docking studies were performed to give insights into the different inhibitory behavior within glycosyl azide anomers. Two of the best inhibitors showed low toxicity in both a neural cell line and human fibroblasts, rendering them promising lead compounds and supporting further investigations.

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