Interleukin-6 and the Gut Microbiota Influence Melanoma Progression in Obese Mice.

There is a strong correlation between obesity and cancer. Here, we investigated the influence of IL-6 and gut microbiota of obese mice in melanoma development. We first evaluated B16F10 melanoma growth in preclinical models for obesity: mice deficient for leptin (ob/ob) or adiponectin (AdpKO) and in wild-type mice (WT, C57BL/6J) fed a high-fat diet (HFD; 60% kcal from fat) for 12 weeks. The survival rates of ob/ob and HFD-fed mice were lower than those of their respective controls. AdpKO mice also died earlier than WT control mice. We then verified the involvement of IL-6 signaling in obese mice that were inoculated with melanoma cells. Both ob/ob and AdpKO mice had higher circulating IL-6 levels than wild-type mice. Melanoma tumor volumes in IL-6 KO mice fed an HFD were reduced compared to those of WT mice subjected to the same diet. Also evaluated the effect of microbiota in tumor development. Cohousing and fecal matter transfer experiments revealed that microbiota from ob/ob mice can stimulate tumor development in lean WT mice. Taken together, our data show that in some conditions IL-6 and the gut microbiota are key mediators that link obesity and melanoma.

A natural bacterial-derived product, the metalloprotease arazyme, inhibits metastatic murine melanoma by inducing MMP-8 cross-reactive antibodies.

The increased incidence, high rates of mortality and few effective means of treatment of malignant melanoma, stimulate the search for new anti-tumor agents and therapeutic targets to control this deadly metastatic disease. In the present work the antitumor effect of arazyme, a natural bacterial-derived metalloprotease secreted by Serratia proteomaculans, was investigated. Arazyme significantly reduced the number of pulmonary metastatic nodules after intravenous inoculation of B16F10 melanoma cells in syngeneic mice. In vitro, the enzyme showed a dose-dependent cytostatic effect in human and murine tumor cells, and this effect was associated to the proteolytic activity of arazyme, reducing the CD44 expression at the cell surface, and also reducing in vitro adhesion and in vitro/in vivo invasion of these cells. Arazyme treatment or immunization induced the production of protease-specific IgG that cross-reacted with melanoma MMP-8. In vitro, this antibody was cytotoxic to tumor cells, an effect increased by complement. In vivo, arazyme-specific IgG inhibited melanoma lung metastasis. We suggest that the antitumor activity of arazyme in a preclinical model may be due to a direct cytostatic activity of the protease in combination with the elicited anti-protease antibody, which cross-reacts with MMP-8 produced by tumor cells. Our results show that the bacterial metalloprotease arazyme is a promising novel antitumor chemotherapeutic agent.