Bioengineered viral vectors for targeting and killing prostate cancer cells

Anti-Colorectal Cancer Effects of Probiotic-Derived p8 Protein

Recently, we reported a novel therapeutic probiotic-derived protein, p8, which has anti-colorectal cancer (anti-CRC) properties. In vitro experiments using a CRC cell line (DLD-1), anti-proliferation activity (about 20%) did not improve after increasing the dose of recombinant-p8 (r-p8) to >10 μM. Here, we show that this was due to the low penetrative efficiency of r-p8 exogenous treatment. Furthermore, we found that r-p8 entered the cytosol through endocytosis, which might be a reason for the low penetration efficiency. Therefore, to improve the therapeutic efficacy of p8, we tried to improve delivery to CRC cells. This resulted in endogenous expression of p8 and increased the anti-proliferative effects by up to 2-fold compared with the exogenous treatment (40 μM). Anti-migration activity also increased markedly. Furthermore, we found that the anti-proliferation activity of p8 was mediated by inhibition of the p53-p21-Cyclin B1/Cdk1 signal pathway, resulting in growth arrest at the G2 phase of the cell cycle. Taken together, these results suggest that p8 is toxic to cancer cells, shows stable expression within cells, and shows strong cancer suppressive activity by inducing cell cycle arrest. Therefore, p8 is a strong candidate for gene therapy if it can be loaded onto cancer-specific viruses.

Promoter-Operating Targeted Expression of Gene Therapy in Cancer: Current Stage and Prospect

The technique of targeted expression of interesting genes, including distinct delivery systems and specific gene promoter-operating expression, is an important strategy for gene therapy against cancers. Up to now, extensive literature documented the efficacy of distinct delivery systems, such as the liposome system, nano-particle system, polyetherimide (PEI) system, and so on, in cancer gene therapy. However, a related document on the potential value of using a specific gene promoter, such as a tumor suppressor, in cancer gene therapy was still scary. The main obstacle might be that the selection of an ideal gene promoter to operate interesting gene expression in cancer gene therapy is still not fully understood. Therefore, many efforts need to be done in order to make it a real power tool for the human clinical treatment of cancer patients. The purpose of this review is to clarify the current state and some problematics in development of promoter-operating targeted expression of interesting genes and highlight its potential in cancer gene therapy.

Off-on polyadenylation strategy as a supplemental mechanism for silencing toxic transgene expression during lentiviral vector production

Many gene therapy strategies rely on lentiviral-mediated transfer and expression of genes coding for toxic proteins. Methods of controlling transgene expression in target cells have been extensively investigated, but comparatively little attention has been given to controlling toxic protein expression in viral vector-producing cells, despite its potential implications for viral production and transduction efficiency. In this work, we tested a new lentiviral vector with a backbone that inhibits transgene mRNA polyadenylation and subsequent transgene expression in vector-producing cells. Transgene mRNA polyadenylation was not affected in transduced cells. In a model using enhanced green fluorescent protein (EGFP) cDNA under the control of the human phosphoglycerate kinase (PGK) promoter, flow cytometry demonstrated that transgene expression was dramatically decreased in 293T cells transfected with this new vector in its plasmid configuration. Viral production was maintained, and expression was fully restored in transduced HuH7 and 293T cells. These results provide the basis for a new strategy to improve the production of lentiviral vectors expressing toxic transgenes.