Antitumor Effect of IP-10 by Using Two Different Approaches: Live Delivery System and Gene Therapy / 한국유방암학회지

PURPOSE: Immunotherapy is one of the treatment strategies for breast cancer, the most common cancer in women worldwide. In this approach, the patient's immune system is stimulated to attack microscopic tumors and control metastasis. Here, we used interferon γ-induced protein 10 (IP-10), which induces and strengthens antitumor immunity, as an immunotherapeutic agent. We employed Leishmania tarentolae, a nonpathogenic lizard parasite that lacks the ability to persist in mammalian macrophages, was used as a live delivery system for carrying the immunotherapeutic agent. It has been already shown that arginase activity, and consequently, polyamine production, are associated with tumor progression. METHODS: A live delivery system was constructed by stable transfection of pLEXSY plasmid containing the IP-10-enhanced green fluorescent protein (IP-10-egfp) fusion gene into L. tarentolae. Then, the presence of the IP-10-egfp gene and the accurate integration location into the parasite genome were confirmed. The therapeutic efficacy of IP-10 delivered via L. tarentolae and recombinant pcDNA-(IP-10-egfp) plasmid was compared by determining the arginase activity in a mouse 4T1 breast cancer model. RESULTS: The pcDNA-(IP-10-egfp) group showed a significant reduction in tumor weight and growth. Histological evaluation also revealed that only this group demonstrated inhibition of metastasis to the lung tissue. The arginase activity in the tissue of the pcDNA-(IP-10-egfp) mice significantly decreased in comparison with that in normal mice. No significant difference was observed in arginase activity in the sera of mice receiving other therapeutic strategies. CONCLUSION: Our data indicates that IP-10 immunotherapy is a promising strategy for breast cancer treatment, as shown in the 4T1-implanted BALB/c mouse model. However, the L. tarentolae-(IP-10-EGFP) live delivery system requires dose modifications to achieve efficacy in the applied regimen (six injections in 3 weeks). Our results indicate that the arginase assay could be a good biomarker to differentiate tumoral tissues from the normal ones.

HPV16 E7-CT [gp96] fusion protein: molecular cloning, expression and purification of a recombinant 6xHis-tagged protein in E. coli

The development of a therapeutic vaccine against human papillomavirus [HPV] is important for the control of cervical cancer. E7 is the major transforming protein produced in cervical cancers, and therefore represents potential tumor-specific antigen that could be the target of immunotherapy for cervical cancer. Among different vaccine strategies, protein-based vaccines are capable of generating CD8+ T cell responses in vaccinated animals and humans. Recently, development of novel strategies that enhance protein vaccine potency is important for generation of effective cancer vaccines and immunotherapies. Heat shock proteins [HSPs] including Gp96 have been shown to act as potent immuno-adjuvant to enhance antigen-specific tumor immunity. Therefore, the HSP-based protein vaccines can be administered by fusing antigens to HSPs, in vitro. It has been known that the HSP fragments [e.g., N-/or C-terminal regions] as mini-chaperones are better choice for immunization. The most straightforward method to produce large amounts of recombinant protein suitable for a vaccine is to clone the gene into a prokaryotic expression vector and produce the protein in Escherichia coli. In current study, we describe cloning of the HPV16 E7 gene linked to C-terminal fragment of gp96, identification and purification of the resultant E7-CT [gp96] fusion protein for next usage as a potential vaccine candidate protein against HPV in a pre-clinical trial. The recombinant E7-CT [gp96] migrated as a 51 kDa protein in SDS-PAGE. In Western blot experiment, the existence of a 51 kDa band for rE7-CT [gp96] was confirmed by rabbit anti-His as well as mouse anti-HPV16 E7 monoclonal antibodies. The protein of interest was both in the insoluble and the soluble fraction; therefore, purification was performed under denaturating and native conditions by affinity chromatography on Ni-NTA resin using 6xHis-tag