Litcius/Paper detail

Tuning the Topological Landscape of DNA–Cyclodextrin Nanocomplexes by Molecular Design

Tania Neva, Ana I. Carbajo‐Gordillo, Juan M. Benito, Hugo Lana, Gema Marcelo, Carmen Ortiz Mellet, Conchita Tros de Ilarduya, Francisco Mendicuti, José M. Garcı́a Fernández

2020Chemistry - A European Journal21 citationsDOI

Abstract

Original molecular vectors that ensure broad flexibility to tune the shape and surface properties of plasmid DNA (pDNA) condensates are reported herein. The prototypic design involves a cyclodextrin (CD) platform bearing a polycationic cluster at the primary face and a doubly linked aromatic module bridging two consecutive monosaccharide units at the secondary face that behaves as a topology-encoding element. Subtle differences at the molecular level then translate into disparate morphologies at the nanoscale, including rods, worms, toroids, globules, ellipsoids, and spheroids. In vitro evaluation of the transfection capabilities revealed marked selectivity differences as a function of nanocomplex morphology. Remarkably high transfection efficiencies were associated with ellipsoidal or spherical shapes with a lamellar internal arrangement of pDNA chains and CD bilayers. Computational studies support that the stability of such supramolecular edifices is directly related to the tendency of the molecular vector to form noncovalent dimers upon DNA templating. Because the stability of the dimers depends on the protonation state of the polycationic clusters, the coaggregates display pH responsiveness, which facilitates endosomal escape and timely DNA release, a key step in successful transfection. The results provide a versatile strategy for the construction of fully synthetic and perfectly monodisperse nonviral gene delivery systems uniquely suited for optimization schemes.

Topics & Concepts

TransfectionSupramolecular chemistryBiophysicsDNACyclodextrinDNA origamiGene deliveryDispersityChemistryNanotechnologyMolecular dynamicsTopology (electrical circuits)Materials scienceMoleculeBiologyGeneBiochemistryComputational chemistryOrganic chemistryCombinatoricsMathematicsRNA Interference and Gene DeliveryAdvanced biosensing and bioanalysis techniquesDNA and Nucleic Acid Chemistry
Tuning the Topological Landscape of DNA–Cyclodextrin Nanocomplexes by Molecular Design | Litcius