Multimodal highly fluorescent-magnetic nanoplatform to target transferrin receptors in cancer cells.

BACKGROUND: Site-specific multimodal nanoplatforms with fluorescent-magnetic properties have great potential for biological sciences. For this reason, we developed a multimodal nanoprobe (BNPs-Tf), by covalently conjugating an optical-magnetically active bimodal nanosystem, based on quantum dots and iron oxide nanoparticles, with the human holo-transferrin (Tf). METHODS: The Tf bioconjugation efficiency was evaluated by the fluorescence microplate assay (FMA) and the amount of Tf immobilized on BNPs was quantified by fluorescence spectroscopy. Moreover, relaxometric and fluorescent properties of the BNPs-Tf were evaluated, as well as its ability to label specifically HeLa cells. Cytotoxicity was also performed by Alamar Blue assay. RESULTS: The FMA confirmed an efficient bioconjugation and the fluorescence spectroscopy analysis indicated that 98% of Tf was immobilized on BNPs. BNPs-Tf also presented a bright fluorescence and a transversal/longitudinal relaxivities ratio (r2/r1) of 65. Importantly, the developed BNPs-Tf were able to label, efficiently and specifically, the Tf receptors in HeLa cells, as shown by fluorescence and magnetic resonance imaging assays. Moreover, this multimodal system did not cause noteworthy cytotoxicity. CONCLUSIONS: The prepared BNPs-Tf hold great promise as an effective and specific multimodal, highly fluorescent-magnetic, nanoplatform for fluorescence analyses and T2-weighted images. GENERAL SIGNIFICANCE: This study developed an attractive and versatile multimodal nanoplatform that has potential to be applied in a variety of in vitro and in vivo studies, addressing biological processes, diagnostic, and therapeutics. Moreover, this work opens new possibilities for designing other efficient multimodal nanosystems, considering other biomolecules in their composition able to provide them important functional properties.

CdTe quantum dots as fluorescent probes to study transferrin receptors in glioblastoma cells.

BACKGROUND: Overexpression of transferrin receptors (TfRs), which are responsible for the intracellular uptake of ferric transferrin (Tf), has been described in various cancers. Although molecular biology methods allow the identification of different types of receptors in cancer cells, they do not provide features about TfRs internalization, quantification and distribution on cell surface. This information can, however, be accessed by fluorescence techniques. In this work, the quantum dots (QDs)' unique properties were explored to strengthen our understanding of TfRs in cancer cells. METHODS: QDs were conjugated to Tf by covalent coupling and QDs-(Tf) bioconjugates were applied to quantify and evaluate the distribution of TfRs in two human glioblastoma cells lines, U87 and DBTRG-05MG, and also in HeLa cells by using flow cytometry and confocal microscopy. RESULTS: HeLa and DBTRG-05MG cells showed practically the same TfR labeling profile by QDs-(Tf), while U87 cells were less labeled by bioconjugates. Furthermore, inhibition studies demonstrated that QDs-(Tf) were able to label cells with high specificity. CONCLUSIONS: HeLa and DBTRG-05MG cells presented a similar and a higher amount of TfR than U87 cells. Moreover, DBTRG-05MG cells are more efficient in recycling the TfR than the other two cells types. GENERAL SIGNIFICANCE: This is the first study about TfRs in human glioblastoma cells using QDs. This new fluorescent tool can contribute to our understanding of the cancer cell biology and can help in the development of new therapies targeting these receptors.

Liposomal and viral vectors for gene therapy of the central nervous system.

Due to the presence of the blood-brain barrier, the central nervous system (CNS) is not easily accessible to systemically delivered macromolecules with therapeutic activity such as growth factors, cytokines or enzymes. Therefore, the expression of exogenously administered genes in the brain has been proposed for a wide variety of inherited and acquired diseases of the CNS, for which classical pharmacotherapy is unavailable or not easily applicable. Gene therapy to the CNS has been the target of a great number of studies aiming at finding a viable therapeutic strategy for the treatment of neurological disorders. This approach has already been used as a promising tool for brain protection and repair from neuronal insults and degeneration in several animal models, and is currently being applied in clinical trials. The choice of an appropriate vector system for transferring the desired gene into the affected brain area is an important issue for developing a safe and efficient gene therapy approach for the CNS. In this review, we focus on the various types of vectors that have been used for gene delivery into the CNS. Particular emphasis is given to their mode of preparation, biological activity, safety and in vivo behavior. Examples illustrating the potential of both viral and non-viral vectors in therapeutic applications to brain disorders are provided. In addition, the use of lentiviral vectors for in vivo modeling of genetic disorders of the CNS is discussed.