| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 599053 | Colloids and Surfaces B: Biointerfaces | 2016 | 9 Pages |
•The use of biologically-derived vesicles as vehicles for the delivery of compounds was studied.•Plant membrane vesicles increased stability of glucosinolates for potential food/therapeutic uses.•Plant aquaporins residues have been identified as main stabilizing binds.
Their biodegradable nature and ability to target cells make biological vesicles potential nanocarriers for bioactives delivery. In this work, the interaction between proteoliposomes enriched in aquaporins derived from broccoli plants and the glucosinolates was evaluated. The vesicles were stored at different temperatures and their integrity was studied. Determination of glucosinolates, showed that indolic glucosinolates were more sensitive to degradation in aqueous solution than aliphatic glucosinolates. Glucoraphanin was stabilized by leaf and root proteoliposomes at 25 °C through their interaction with aquaporins. An extensive hydrogen bond network, including different aquaporin residues, and hydrophobic interactions, as a consequence of the interaction between the linear alkane chain of glucoraphanin and Glu31 and Leu34 protein residues, were established as the main stabilizing elements. Combined our results showed that plasma membrane vesicles from leaf and root tissues of broccoli plants may be considered as suitable carriers for glucosinolate which stabilization can be potentially attributed to aquaporins.
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