Heat shock protein (Hsp) 90 is a key regulator of various oncogene products and cell-signaling molecules, while Hsp70 protects against heat-induced apoptosis. We previously described a system in which hyperthermia was produced using thermosensitive ferromagnetic particles (FMPs) with a Curie temperature (T c) of 43 °C to mediate automatic temperature control, and demonstrated its antitumor effect in a mouse melanoma model. In the present study, the antitumor effects of combining Hsp90 inhibitor (17DMAG) and Hsp70 inhibitor (quercetin) with FMP-mediated hyperthermia were examined.

Expressions of Hsp90/70 and Akt were evaluated using Western blotting in vitro. In an in vivo study, melanoma cells were subcutaneously injected into the backs of C57BL/6 mice. FMPs were then injected into the resultant tumors, and the mice were divided into groups treated with quercetin and/or 17DMAG with/without hyperthermia. When exposed to a magnetic field, the temperature of tissues containing FMPs increased and stabilized at the T c. The TUNEL method was used to determine whether hyperthermia induced apoptosis within tumors.

In the group pretreated with hyperthermia + quercetin + 17DMAG, Akt expression was reduced in vitro, the incidence of apoptosis within tumors was greater, and tumor growth was significantly suppressed 20 days after FMP injection in vivo, compared with other treatment groups. The survival rates among tumor-bearing mice observed for a period of 40 days were significantly higher in the hyperthermia + quercetin + 17DMAG group.

Combining Hsp90/70 inhibition with hyperthermia appears to increase their antitumor effects. Thus, the combination of FMP-mediated, self-regulating hyperthermia with Hsp90/70 inhibition has important implications for cancer treatment.