Polycationic amphiphilic cyclodextrins as gene vectors: effect of the macrocyclic ring size on the DNA complexing and delivery properties.

A collection of homologous monodisperse facial amphiphiles consisting of an α-, ß- or γ-cyclodextrin (α, ß or γCD) platform exposing a multivalent display of cationic groups at the primary rim and bearing hexanoyl chains at the secondary hydroxyls have been prepared to assess the influence of the cyclooligosaccharide core size in their ability to complex, compact and protect pDNA and in the efficiency of the resulting nanocondensates (CDplexes) to deliver DNA into cells and promote transfection in the presence of serum. All the polycationic amphiphilic CDs (paCDs) were able to self-assemble in the presence of the plasmid and produce transfectious nanoparticles at nitrogen/phosphorous ratios ≥5. CDplexes obtained from ßCD derivatives generally exhibited higher transfection capabilities, which can be ascribed to their ability to form inclusion complexes with cholesterol, thereby enhancing biological membrane permeability. The presence of thiourea moieties as well as increasing the number of primary amino groups then favour cooperative complexation of the polyphosphate chain, enhancing the stability of the complex and improving transfection. In the α and γCD series, however, only the presence of tertiary amino groups in the cationic clusters translates into a significant improvement of the transfection efficiency, probably by activating endosome escape by the proton sponge mechanism. This set of results illustrates the potential of this strategy for the rational design and optimisation of nonviral gene vectors.

Monodisperse nanoparticles from self-assembling amphiphilic cyclodextrins: modulable tools for the encapsulation and controlled release of pharmaceuticals.

Selective chemical functionalization of cyclodextrins (CDs) is a readily amenable methodology to produce amphiphilic macromolecules endowed with modulable self-organizing capabilities. Herein, the synthesis of well-defined amphiphilic CD derivatives, with a "skirt-type" architecture, that incorporate long-chain fatty esters at the secondary hydroxyl rim and a variety of chemical functionalities (e. g. iodo, bromo, azido, cysteaminyl or isothiocyanato) at the primary hydroxyls rim is reported. Nanoprecipitation of the new CD facial amphiphiles, or binary mixtures of them, resulted in nanoparticles with average hydrodynamic diameters ranging from 100 to 240 nm that were stable in suspension for several months. The precise size, zeta potential and topology of the nanoparticles are intimately dependent on the functionalization pattern at the CD scaffold. Highly efficient molecular encapsulation capabilities of poorly bioavailable drugs such as diazepam (DZ) were demonstrated for certain derivatives, the drug release profile being dependent on the type of formulation (nanospheres or nanocapsules). The efficiency and versatility of the synthetic strategy, together with the possibility of exploiting the reactivity of the functional groups at the nanoparticle surface, offer excellent opportunities to further manipulate the carrier capabilities of this series of amphiphilic CDs from a bottom-up approach.

Mannosyl-coated nanocomplexes from amphiphilic cyclodextrins and pDNA for site-specific gene delivery.

Fully homogeneous facial amphiphiles consisting in a cyclodextrin (CD) platform onto which a polycationic cluster and a multi-tail hydrophobic moiety have been installed (polycationic amphiphilic CDs; paCDs) self-organized in the presence of plasmid DNA to form nanometric complexes (CDplexes) which exhibit broad-range transfection capabilities. We hypothesized that biorecognizable moieties located at the hydrophilic rim in the CD scaffold would be exposed at the surface of the corresponding nanoparticles after DNA-promoted aggregation, endowing the system with molecular recognition abilities towards cell receptors. This concept has been demonstrated by developing an efficient synthetic strategy for the preparation of multivalent polycationic glyco-amphiphilic CDs (pGaCDs). Self-assembled nanoparticles obtained from mannosylated pGaCDs and pDNA (average hydrodynamic diameter 80 nm) have been shown to be specifically recognized by mannose-specific lectins, including concanavalin A (Con A) and the human macrophage mannose receptor (MMR). Further macrophage adhesion studies indicated that unspecific binding, probably due to electrostatic interactions with negatively charged cell membrane components, can also operate. The relative specific versus non-specific internalization is dependent on the pGaCD:pDNA proportion, being optimal at a protonable nitrogen/phosphate (N/P) ratio of 5. The resulting GlycoCDplexes were shown to specifically mediate transfection in Raw 264.7 (murine macrophage) cells expressing the mannose-fucose receptor in vitro. FACS experiments confirmed that transfection using these nanoparticles is mannose-dependent, supporting the potential of the approach towards vectorized gene delivery.

Copper(II)-complex directed regioselective mono-p-toluenesulfonylation of cyclomaltoheptaose at a primary hydroxyl group position: an NMR and molecular dynamics-aided design.

Interactions between cyclomaltoheptaose (ß-cyclodextrin, ßCD) and p-toluenesulfonyl chloride (TsCl) were investigated using MD simulations, both in vacuum, approximating the hydrophobic environment of the CD cavity, and with water as a solvent. In both cases, the minimum energy adiabatic paths, and the mean force potentials (MFP) for the insertion of TsCl along a reaction coordinate perpendicular to the CD plane, were calculated for the two possible orientations of TsCl. The results show a preferred entry of TsCl in the CD cavity with the sulfonyl chloride group pointing to the primary hydroxyls rim. In each orientation, two energy minima for the complex are detected in vacuum that reflect the H-H contacts between host and guest observed by NMR spectroscopy (ROESY, NOESY). These separate minima collapsed into a single broader minimum, when the solvent was introduced in the simulations. The resulting association constant between TsCl and ßCD (K(a) ≈ 100 M(-1)) is in good agreement with the NMR results (K(a) = 102 ± 12 M(-1)) in deuterated water solution at 298 K. Advantage has been taken of the dynamics of the reagent inclusion to set up a one step process involving a transient Cu(2+) chelate at the secondary hydroxyls rim position for the electrophilic monoactivation of ßCD at the primary hydroxyls rim using water as solvent.

Symmetry complementarity-guided design of anthrax toxin inhibitors based on ß-cyclodextrin: Synthesis and relative activities of face-selective functionalized polycationic clusters.

Three new series of potential anthrax toxin inhibitors based on the ß-cyclodextrin (ßCD) scaffold were developed by exploiting face-selective Cu(I)-catalyzed azide-alkyne 1,3-cycloadditions, amine-isothiocyanate coupling, and allyl group hydroboration-oxidation/hydroxy → amine replacement reactions. The molecular design follows the "symmetry-complementarity" concept between homogeneously functionalized polycationic ßCD derivatives and protective antigen (PA), a component of anthrax toxin known to form C7-symmetric pores on the cell membrane used by lethal and edema factors to gain access to the cytosol. The synthesis and antitoxin activity of a collection of ßCD derivatives differing in the number, arrangement, and face location of the cationic elements are reported herein. These results set the basis for a structure-activity relationship development program of new candidates to combat the anthrax threat.

Polycationic amphiphilic cyclodextrins for gene delivery: synthesis and effect of structural modifications on plasmid DNA complex stability, cytotoxicity, and gene expression.

A molecular-diversity-oriented approach for the preparation of well-defined polycationic amphiphilic cyclodextrins (paCDs) as gene-delivery systems is reported. The synthetic strategy takes advantage of the differential reactivity of primary versus secondary hydroxyl groups on the CD torus to regioselectively decorate each rim with cationic elements and lipophilic tails, respectively. Both the charge density and the hydrophobic-hydrophilic balance can be finely tuned in a highly symmetrical architecture that is reminiscent of both cationic lipids and cationic polymers, the two most prominent types of nonviral gene vectors. The monodisperse nature of paCDs and the modularity of the synthetic scheme are particularly well suited for structure-activity relationship studies. Gel electrophoresis revealed that paCDs self-assemble in the presence of plasmid DNA (pDNA) to provide homogeneous, stable nanoparticles (CDplexes) of 70-150 nm that fully protect pDNA from the environment. The transfection efficiency of the resulting CDplexes has been investigated in vitro on BNL-CL2 and COS-7 cell lines in the absence and presence of serum and found to be intimately dependent on architectural features. Facial amphiphilicity and the presence of a cluster of cationic and hydrogen-bonding centers for cooperative and reversible complexation of the polyanionic DNA chain is crucial to attain high transgene expression levels with very low toxicity profiles. Further enhancement of gene expression, eventually overcoming that of polyplexes from commercial polyethyleneimine (PEI) polymers (22 kDa), is achieved by building up space-oriented dendritic polycationic constructs.

Tailoring beta-cyclodextrin for DNA complexation and delivery by homogeneous functionalization at the secondary face.

An efficient general strategy for the incorporation of functional elements onto the secondary hydroxyl rim of beta-cyclodextrin has been developed and applied to the synthesis of a novel series of C7-symmetric homogeneous macromolecular polycations with improved DNA complexing and delivery properties.

Rational design of cationic cyclooligosaccharides as efficient gene delivery systems.

Self-assembled cyclodextrin (CD)-DNA nanoparticles (CDplexes) exhibiting transfection efficiencies significantly higher than PEI-based polyplexes have been prepared from homogeneous seven-fold symmetric polyaminothiourea amphiphiles constructed on a beta-cyclodextrin scaffold.

Differential effects of cyclodextrins and derivatives on the biological behavior of the myocardial perfusion imaging agent 99mTcN-NOET.

In addition to improving drug solubilization, cyclodextrins (CDs) also affect the biological behavior of the included compound. We evaluated the effects of two natural CDs beta-CD and gamma-CD, and six beta-CD derivatives, Dimeb, Trimeb, SBb, 2-HP, 6AD, and 6 MTU on the biological behavior of (99m)TcN-NOET, a technetium-99m-labeled, lipophilic compound readily detectable through radioactivity assessment. Determination of CDs' affinities for (99m)TcN-NOET indicated that the cavity size of gamma-CD was not suitable for (99m)TcN-NOET inclusion, and that beta-CD derivatization mostly resulted in decreased CDs affinities for (99m)TcN-NOET to various extents compared with the natural beta-CD. In vitro and ex vivo experiments performed on newborn rat cardiomyocytes and isolated perfused rat hearts, respectively, showed 1.7- and 2.3-fold maximal differences in (99m)TcN-NOET cellular and tissue activities. Regression analyzes indicated no significant correlation between these observed biological differences and the affinities of the eight CDs tested for (99m)TcN-NOET or for cellular membranes. In conclusion, CD derivatization often resulted in impaired affinity of the derivatives for the lipophilic compound (99m)TcN-NOET. Moreover, the in vitro and ex vivo biological behavior of (99m)TcN-NOET was greatly affected depending on the CD used for inclusion of the tracer.

Probing secondary carbohydrate-protein interactions with highly dense cyclodextrin-centered heteroglycoclusters: the heterocluster effect.

Comparison of the lectin-binding properties for highly dense beta-cyclodextrin-centered homo- and heteroglycoclusters with defined architecture provides evidence for the existence of strong synergic effects (heterocluster effect) on carbohydrate-protein recognition events.

Optimizing saccharide-directed molecular delivery to biological receptors: design, synthesis, and biological evaluation of glycodendrimer-cyclodextrin conjugates.

Dendritic beta-cyclodextrin (betaCD) derivatives bearing multivalent mannosyl ligands have been prepared and assessed for their binding efficiency toward the tetrameric plant lectin concanavalin A (Con A) and a mammalian mannose/fucose specific cell surface receptor from macrophages. The synthetic strategy exploits the reactivity between isothiocyanate and amine functionalities for the high-yielding assembly via thioureido links of the various building blocks, including host, spacer, branching, and carbohydrate ligand elements. The methodology has been applied to the preparation of a series of betaCD-polymannoside scaffolds differing in the ligand valency and geometry. This series allowed us to explore: (i) The effects of the glycodendritic architecture on the binding efficiency; (ii) the mutual influence between the cyclodextrin core and the glycodendritic moieties on the molecular inclusion and lectin-binding properties; and (iii) the consequence of inclusion complex formation, using the anticancer drug docetaxel (Taxotère) as a target guest, on biological recognition. Our results confirm the high drug solubilization capability of this new type of betaCD-dendrimer construct and indicate that subtle changes in the architecture of the conjugate may have important consequences on receptor affinity. Interestingly, the host-guest interaction can be monitored to build up supramolecular dynamic glycoclusters with increased lectin affinity. Alternatively, the information obtained from the structure-lectin-binding avidity-inclusion capability studies has been put forward in the design of very efficient molecular transporters for docetaxel based on glycodendritic CD dimers.

Regioselective sulfonylation at O-2 of cyclomaltoheptaose with 1-(p-tolylsulfonyl)-(1H)-1,2,4-triazole.

2(I)-O-p-Tolylsulfonylcyclomaltoheptaose was obtained in 42% yield by reaction of 1-(p-tolylsulfonyl)-(1H)-1,2,4-triazole on NaH-deprotonated cyclomaltoheptaose in DMF and further converted into the corresponding mono-2(I),3(I)-manno-epoxide.

One-step synthesis of non-anomeric sugar isothiocyanates from sugar azides.

Tandem Staudinger-aza-Wittig reaction of primary azidodeoxy sugars with triphenylphosphine-carbon disulfide affords the corresponding primary deoxyisothiocyanato sugars in high yield. No products arising from O --> N acyl migration or formation of dimeric carbodiimides were observed. Interestingly, a polymer-supported triarylphosphine can advantageously replace triphenylphosphine, thus limiting the purification step to a simple filtration process. The reaction also allows the preparation of 5-deoxy-5-isothiocyanato sugars, a hitherto unknown class of compounds, from the corresponding azide precursors. Secondary sugar azides bearing the azido group at an endocyclic carbon atom afforded much lower isothiocyanation yields under these reaction conditions.

Influence of chemical structure of amphiphilic beta-cyclodextrins on their ability to form stable nanoparticles.

The aim of the study was to establish a correlation between the chemical structure of amphiphilic beta-cyclodextrins (beta-CDa) and their ability to form stable nanospheres. Amphiphilic derivatives were obtained according to an optimized well-known three-step synthesis. The selective acylation of the secondary face of beta-CD being well controlled, several beta-CDa presenting different substitution degree were synthesized. The self-organization properties of the derivatives were evaluated. The peracylated beta-CD, i.e. bearing 14 alkyl chains on the secondary hydroxyl groups, does not yield stable nanosphere suspension, even in the presence of a non ionic surfactant in the aqueous phase. However, the presence of partially acylated derivatives within the beta-CDa allows self-assembly into stable nanosphere suspension.

Multivalent cyclooligosaccharides: versatile carbohydrate clusters with dual role as molecular receptors and lectin ligands.

Results obtained over the past decade towards the preparation of multitopic carbohydrate architectures combining the molecular inclusion capabilities of cyclomaltooligosaccharide receptors (cyclodextrins, CDs) and the recognition properties of saccharide ligands towards biological receptors are discussed. The potential of these new sugar-based "intelligent" transporters for site specific delivery of therapeutics is outlined.