Glycodendrimers as new tools in the search for effective anti-HIV DC-based immunotherapies.

Dendritic cells (DC), which play a major role in development of cell-mediated immunity, represent opportunities to develop novel anti-HIV vaccines. Dendrimers have been proposed as new carriers to ameliorate DC antigen loading and in this way, we have determined the potential use of maltose decorated neutrally and positively charged G4 glycodendrimers. Thus, immunostimulatory properties of these glycodendrimers on human DC were evaluated in the context of HIV infection. We have demonstrated that DC treated with glycodendrimers were fully functional with respect to viability, maturation and HIV-derived antigens uptake. Nevertheless, iDC and mDC phenotypes as well as mDC functions such as migration ability and cytokines profile production were changed. Our results showed the potential carrier properties of glycodendrimers to activate the immune system by the way of DC stimulation. This is the first study for exploring the use of maltose-functionalized dendrimers-peptides complexes as a potential DC-based vaccine candidate. FROM THE CLINICAL EDITOR: In this paper, maltose-functionalized dendrimer-peptide complexes are demonstrated to activate the immune system by way of dendritic cell (DC) stimulation. DC vaccination using this methodology may be applicable to a variety of conditions, including infections and potentially cancer.

In vitro evaluation of the effectiveness of new water-stable cationic carbosilane dendrimers against Acanthamoeba castellanii UAH-T17c3 trophozoites.

Acanthamoeba is one of the most common free-living amoebas which is widespread in the environment and can infect humans, causing diseases such as keratitis and encephalitis. In this paper we examine for the first time the amebicidal activity of the family of cationic dendrimers nG-[Si{(CH(2))(3)N(+)(Me)(Et)(CH(2))(2)NMe(3) (+)}2I(-)]( x ) (where n denotes the generations: zero (n = 0, x = 1), first (n = 1, x = 4), and second (n = 2, x = 8); for simplicity, they were named as 0G-CNN2, 1G-CNN8, and 2G-CNN16, respectively) against Acanthamoeba castellanii UAH-T17c3 trophozoites. In order to test the amebicidal activity, we cultured the strain A. castellanii UAH-T17c3 in PYG-Bactocasitone medium and later, we treated it with different concentrations of these dendrimers and monitored the effects and damage by optical count, flow cytometry, and scanning electron microscopy. The results showed that all the nanosystems assayed had a strong amebicidal activity. The dendrimer 1G-CNN8 was the most effective against the amoeba. In the morphology of treated throphozoites of A. castellanii UAH-T17c3 analyzed by light and scanning electron microscopy techniques, morphological changes were evident in amoeba cells, such as loss of pseudopodia, ectoplasm increase, roundness, and cellular lysis. Furthermore, flow cytometry results showed alterations in cell granularity, which was dose-time dependent. In conclusion, this family of cationic carbosilane dendrimers has a strong amebicidal activity against the trophozoites of A. castellanii UAH-T17c3 in vitro. They could potentially become new agents significant to the development of new amebicidal compounds for prevention and therapy of Acanthamoeba infections.

Characterization of carboxylate-terminated carbosilane dendrimers and their evaluation as nanoadditives in capillary electrophoresis for vegetable protein profiling.

Protein profiles are becoming an important tool to differentiate and classify varieties of several cultivars and to obtain a specific fingerprint for them. The use of protein profiles for these purposes needs to achieve high separation efficiencies to obtain a high number of well resolved peaks. In this work, carbosilane dendrimers with interior carbon-silicon bonds and negatively charged in the dendrimer surface with carboxylic acid as functional groups were employed as nanoadditives to separate soybean and olive seeds proteins. First, these dendrimers were characterized using CE to evaluate their possible impurities. A potentiometric titration was later carried out to determine their pK(a) values. Afterwards, the characterized dendrimers were used to improve the protein profiles obtained by EKC for vegetable proteins. Different dendrimer generations (G1, G2, and G3) and concentrations (0.01-1% m/v) were tested. The highest dendrimer generation G3 at 0.1% (m/v) allowed observing the best protein profiles for soybean and olive seeds. These results demonstrate that carboxylate-terminated carbosilane dendrimers are attractive nanoadditives in EKC for the effective separation of vegetable proteins.

In vitro studies of water-stable cationic carbosilane dendrimers as delivery vehicles for gene therapy against HIV and hepatocarcinoma.

Here we present a synthetic procedure for water-stable carbosilane dendrimers containing ammonium groups at the periphery of type Gn-{[Si(CH2)3N+(Me)(Et)CH2CH2N+Me3]x (CF3SO3 -)y} which have been used as non-viral vectors for transfecting different types of nucleic acids against two different medical problems, HIV and hepatocarcinoma. These systems have shown to be non-toxic in both PBMC and HepG2 cell lines under the experimental conditions and are able to form nanoconjugates with nucleic acids perfectly stable over time and in a wide range of pH values, which leads to the conclusion that the interaction between dendrimer and nucleic acid is very strong. In addition, a high degree of transfection using these nanoconjugates has been observed, ranging from 70-90% depending on the generation and in the particular case of PBMC transfection with anti-HIV oligonucleotides. However, besides of the good properties shown by the dendrimers here prepared as transfecting agents, only moderate effect was observed in functional experiments for hepatocarcinoma, as a result of the strong interaction between dendrimer and nucleic acid. Nevertheless, it is important to mention that an IRS-4 knock-down of 40% in HepG2 achieves an analogous degree of cell sensitization to cancer treatment, which may represent a major advance in the hepatocarcinoma treatment when appropriate dendrimers as transfection agents are used.

Carbosilane dendrimer nanotechnology outlines of the broad HIV blocker profile.

Researchers have been working hard for more than 20 years to develop safe and effective microbicides to empower women to better control their own sexual life and to protect themselves against HIV and other sexually transmitted infections (STIs). Microbicide classes include moderately specific macromolecular anionic polymers that block HIV and other STIs, and HIV specific drugs that inhibit viral entry and reverse transcription. Based on innovative nanotechnology design, we showed a novel water-soluble anionic carbosilane dendrimer (2G-S16) as a propitious molecule against HIV-infection. A state-of-the-art research was accomplished that focused on biomedical cutting-edge techniques such as in vitro and in vivo cytotoxicity assays performed on female rabbit genital tracts, simulate in vitro model of vaginal epithelium in order to evaluate HIV transmission blockade through the monolayer, complete gene expression profiling experiment to study deregulated genes after 2G-S16 exposition, molecular dynamics simulation of 2G-S16 molecule against principal proteins of HIV particles and pro- and anti-inflammatory cytokine profile study. Therefore, a high-throughput study and detailed analysis of the results were achieved in this article. We provided promising outcomes to encourage 2G-S16 as a hopeful microbicide.