The facile synthesis of a novel bis-(guanidinium)-tetrakis-(beta-cyclodextrin) tetrapod, the first example of a new host family, was described, and the ability of the cyclodextrin CyD tetrapod to form molecular association with siRNA and DNA guest molecules was demonstrated. Affinity capillary electrophoresis was used to determine the binding constant with the evaluation of the shift in the electrophoretic mobility mu of injected siRNA when various CyD tetrapod concentrations were added to the run buffer. A significant association constant (K(a) =16,000 M(-1)) was obtained with borate buffer when double-stranded siRNA was primarily opened with the help of temperature. An efficient cellular transfection of siRNA into human embryonic lung fibroblasts was observed by fluorescence microscopy.
Seven upper‐rim fully tethered cyclodextrins (URFT‐CDs) have been synthesised in a good average coupling yield using the one‐step “phosphine imide” approach and their metal complexation behaviour with lanthanides and transition metals was explored. We observed that the A‐TE‐E light conversion process (antennae effect) occurs in the URFT‐CD lanthanide complexes. A molecular redox switch based on the corresponding iron complexes is also reported. A reversible intramolecular translocation of the FeII and FeIII ions, between two distinct binding cavities has been monitored spectroscopically and achieved by chemical triggering. Finally, a negative allosteric control of ion recognition through the formation of a CD pseudocryptand is discussed.
The ability of cyclodextrins to enhance the antiviral activity of a phosphodiester oligodeoxynucleotide has been investigated. A 18-mer oligodeoxynucleotide complementary to the initiation region of the mRNA coding for the spike protein and containing the intergenic consensus sequence of an enteric coronavirus has been tested for antiviral action against virus growth in human adenocarcinoma cells. The phosphodiester oligodeoxynucleotide only showed a limited effect on virus growth rate (from 12 to 34% viral inhibition in cells treated with 7.5 to 25 microM oligodeoxynucleotide, respectively, at a multiplicity of infection of 0.1 infectious particle per cell). In the same conditions, the phosphorothioate analogue exhibited stronger antiviral activity, the inhibition increased from 56 to 90%. The inhibitory effect of this analogue was antisense and sequence-specific. Northern blot analysis showed that the sequence-dependent mechanism of action appears to be the inhibition of mRNA transcription. We conclude that the coronavirus intergenic consensus sequence is a good target for an antisense oligonucleotide antiviral action. The properties of the phosphodiester oligonucleotide was improved after its complexation with cyclodextrins. The most important increase of the antiviral activity (90% inhibition) was obtained with only 7.5 microM oligonucleotide complexed to a cyclodextrin derivative, 6-deoxy-6-S-beta-D-galactopyranosyl-6-thio-cyclomalto-heptaose+ ++ in a molar ratio of 1:100. These studies suggest that the use of cyclodextrin derivatives as carrier for phosphodiester oligonucleotides delivery may be an effective method for increasing the therapeutic potential of these compounds in viral infections.
The synthesis of new 'bridged' p-cyclodextrin (p-CD) 'dimers' 7-12 was successfully achieved by two one-pot reactions from p-CD (3) and 6A-azido-6A-deoxy-p-CD (4). The 'phosphine imine' reaction was shown to be a superior approach compared to the Mitsunobu reaction as coupling strategy for the preparation of these 'dimers'. NMR Data, along with molecular-modelling calculations, suggest a 'helical-like' arrangement for the phenanthroline-diyl-linked 'dimer' derivative 9. Complexation properties of 9 were established by UV-VIS-spectrophotometric titration toward four metals. Among them Cu" or Eu"' ions were complexed selectively by 9, but no complexation occurred with La"' and Zn". In addition a specific and interesing esterase activity toward the phosphodiester bond of bis(4-nitrophenyl) phosphate anion was found in the case of the Cu" complex of 9.
A new efficient and safe synthesis of 3,3'-dimethyl-5,5'-bis-(1,2,4-triazine) is presented. The electron-density distribution and electrostatic properties (charge, electrostatic potential) of this molecule were analyzed. These properties were derived from a high-resolution single-crystal X-ray diffraction experiment at 100 K and compared to the results obtained from ab initio DFT quantum-mechanical calculations. Comparisons of its electrostatic potential features and integrated atomic charges (quantum theory of atoms in molecules, QTAIM) have been made with those of related molecules such as bipyrimidine ligands. Two methods were used to derive integrated charges: one is based on the conventional analytical procedure and the second uses a steepest-ascent numerical algorithm. Excellent agreement was obtained between these two methods. Charges and electrostatic potential were used as predictive indices of metal chelation and discussed in the light of complexation abilities of the title compound and related molecules. The crystal structure of a Cu(I) complex of 3,3'-dimethyl-5,5'-bis(1,2,4-triazine) is reported here. In the solid state, this complex forms a three-dimensional multibranch network with open channels in which counterions and solvent molecules are located. This architecture involves both cis and trans isomers of the title compound.
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