Prof. Michele Caraglia- University of Campania “L. Vanvitelli”
Abstract
Glioblastoma (GBM) is a highly aggressive brain cancer with poor clinical outcome. Unfortunately, chemotherapy with temozolomide (TMZ) has a limited efficacy due to resistance mainly attributed to O6-methylguanine methyl transferase (MGMT) activity. Recently, miR-603 and miR-221 have been identified to target MGMT, thus improving the efficacy of temozolomide (TMZ) in the treatment of GBM. Previously, self-assembling nanoparticles (SANPs) have been proposed to deliver miRNAs into the brain and were patented by our group. Here, SANP co-encapsulating miRNA-603 (miR-603) and miRNA-221 (miR-221) have been developed to enhance the efficacy of TMZ in the treatment of GBM by preventing the occurrence of chemoresistance. Preliminarily, SANPs encapsulating miRNAs were optimized in terms of lipid composition to assure physical stability and no hemolytic activity. Subsequently, SANPs with the lowest cytotoxicity and excellent internalization efficiency of miRNAs were selected through MTT assay and real-time PCR, respectively. To evaluate a potential synergistic effect between TMZ and miRNAs, MTT and clonogenic assays were performed. In our biological model, miRNA delivery via SANPs in combination with TMZ treatment strongly reduced cell viability and tumorigenic potential. Finally, in vivo assays were carried out on orthotopic xenograft mouse models. The treatment with SANPs encapsulating both miRNAs in combination with TMZ greatly decreased tumour growth, and even more significantly increased animal survival. In conclusion, this strategy provides the rationale for the development of new therapeutic approaches based on SANP technology to deliver miRNAs that play a key role in suppressing tumour. Another way to deliver miRNAs are innovative nanocrystalline carbon particles nanodiamonds. Nanodiamonds were tested and optimized to deliver miR-34a, a miRNA playing a key role in inhibiting tumor development and progression in many cancers. The physical-chemical properties of nanodiamonds were investigated suggesting electrical stability and uniformity of structure and size. Moreover, we evaluated nanodiamond cytotoxicity on breast and pancreatic cancer cell models and confirmed their excellent biocompatibility. Subsequently, nanodiamonds were conjugated with miR-34a, using the chemical crosslinker polyethyleneimine; real-time PCR analysis revealed a higher level of miR-34a in cancer cells treated with nanodiamonds than with commercial transfectant. A significant and early nanodiamond-miR-34a uptake was recorded by FACS and fluorescence microscopy analysis. Moreover, nanodiamond-miR-34a significantly inhibited both cell proliferation and migration. Finally, a remarkable anti-tumor effect of miR-34a-conjugated nanodiamonds was observed in both heterotopic and orthotopic murine xenograft models. In conclusion, this study provides a rationale for the development of new therapeutic strategies based on use of miR-34a delivered by nanodiamonds to improve the clinical treatment of neoplasms.
Bio
