Antitumour activity and tolerability of an EphA2-targeted nanotherapeutic in multiple mouse models.

Antibody-mediated tumour targeting and nanoparticle-mediated encapsulation can reduce the toxicity of antitumour drugs and improve their efficacy. Here, we describe the performance of a nanotherapeutic encapsulating a hydrolytically sensitive docetaxel prodrug and conjugated to an antibody specific for EphA2-a receptor overexpressed in many tumours. Administration of the nanotherapeutic in mice led to slow and sustained release of the prodrug, reduced exposure of active docetaxel in the circulation (compared with administration of the free drug) and maintenance of optimal exposure of the drug in tumour tissue. We also show that administration of the nanotherapeutic in rats and dogs resulted in minimal haematological toxicity, as well as the absence of neutropenia and improved overall tolerability in multiple rodent models. Targeting of the nanotherapeutic to EphA2 improved tumour penetration and resulted in markedly enhanced antitumour activity (compared with administration of free docetaxel and non-targeted nanotherapeutic controls) in multiple tumour-xenografted mice. This nanomedicine could become a potent and safe therapeutic alternative for cancer patients undergoing chemotherapy.

Expression of inflammatory chemokines combined with local tumor destruction enhances tumor regression and long-term immunity.

Expression of chemokines within tumors can be used to recruit immature dendritic cells (DCs) for the initiation of antitumor T-cell responses. Here, we describe the chemokine receptor expression on murine bone marrow-derived immature DCs. On the basis of these receptor studies, we chose to express the chemokines CCL3 (Mip-1alpha) or CCL20 (Mip-3alpha) in tumors. We show that expression of these chemokines in the colorectal tumor model CMT93 significantly decreases tumorigenesis. This decrease is associated with an increase in CD8 T cells, natural killer cells, and Class II DCs in the tumor within the first 24 h. Furthermore, studies in immunodeficient mice show that both natural killer cells and T cells are required for this decrease in immunogenicity. CCL3 and CCL20 expression alone did not significantly inhibit the development of the B16 melanoma tumor. However, coexpression of the Herpes Simplex Virus thymidine kinase gene (HSVtk) and CCL20, cured large established tumors where HSVtk expression alone was not sufficient. Finally, coexpression of HSVtk with either CCL3 or CCL20 was able to significantly increase protection against subsequent tumor rechallenge.