Complex Interplay of Genes Underlies Invasiveness in Fibrosarcoma Progression Model

Sarcomas are a heterogeneous group of mesenchymal tumours, with a great variability in their clinical behaviour. While our knowledge of sarcoma initiation has advanced rapidly in recent years, relatively little is known about mechanisms of sarcoma progression. JUN-murine fibrosarcoma progression series consists of four sarcoma cell lines, JUN-1, JUN-2, JUN-2fos-3, and JUN-3. JUN-1 and -2 were established from a single tumour initiated in a H2K/v-jun transgenic mouse, JUN-3 originates from a different tumour in the same animal, and JUN-2fos-3 results from a targeted in vitro transformation of the JUN-2 cell line. The JUN-1, -2, and -3 cell lines represent a linear progression from the least transformed JUN-2 to the most transformed JUN-3, with regard to all the transformation characteristics studied, while the JUN-2fos-3 cell line exhibits a unique transformation mode, with little deregulation of cell growth and proliferation, but pronounced motility and invasiveness. The invasive sarcoma sublines JUN-2fos-3 and JUN-3 show complex metabolic profiles, with activation of both mitochondrial oxidative phosphorylation and glycolysis and a significant increase in spared respiratory capacity. The specific transcriptomic profile of invasive sublines features very complex biological relationships across the identified genes and proteins, with accentuated autocrine control of motility and angiogenesis. Pharmacologic inhibition of one of the autocrine motility factors identified, Ccl8, significantly diminished both motility and invasiveness of the highly transformed fibrosarcoma cell. This progression series could be greatly valuable for deciphering crucial aspects of sarcoma progression and defining new prognostic markers and potential therapeutic targets.

Chemical Characterization of the Lichen-symbiont Microalga Asterochloris erici and Study of Its Cytostatic Effect on the L929 Murine Fibrosarcoma Cell Line

New resources of food, pharmaceuticals or biotechnological products are needed. The huge biodiversity of aero-terrestrial lichen-symbiont microalgae remains unexplored. Viability of these for human consumption demands the demonstration of the absence of toxic effects. In vitro biocompatibility of crude homogenates of axenic microalga Asterochloris erici, symbiotic in the lichen Cladonia cristatella, was analyzed after treatment of cultured L929 fibroblasts with different doses of microalgal homogenates. The results show that crude homogenates of A. erici do not induce fibroblast cytotoxicity but seem to have some cytostatic effect inducing slight cell cycle alterations and intracellular reactive oxygen species (ROS) increase at the highest dose. Carotenoid analysis demonstrates high content of lutein, a xanthophyll with antioxidant and cytostatic properties in vivo. These findings confirm that Asterochloris erici can be considered suitable for the development of alimentary or pharmaceutical applications. The cytostatic effects should be further investigated for antitumor agents.

Cytotoxic effect of Montivipera bornmuelleri’s venom on cancer cell lines: in vitro and in vivo studies

Background Montivipera bornmuelleri’s venom has shown immunomodulation of cytokines release in mice and selective cytotoxicity on cancer cells in a dose-dependent manner, highlighting an anticancer potential. Here, we extend these findings by elucidating the sensitivity of murine B16 skin melanoma and 3-MCA-induced murine fibrosarcoma cell lines to M. bornmuelleri’s venom and its effect on tumor growth in vivo. Methods The toxicity of the venom on B16 and MCA cells was assessed using flow cytometry and xCELLigence assays. For in vivo testing, tumor growth was followed in mice after intratumoral venom injection. Results The venom toxicity showed a dose-dependent cell death on both B16 and MCA cells. Interestingly, overexpression of ovalbumin increased the sensitivity of the cells to the venom. However, the venom was not able to eradicate induced-tumor growth when injected at 100 µg/kg. Our study demonstrates a cytotoxic effect of M. bornmuelleri’s venom in vitro which, however, does not translate to an anticancer action in vivo.

Combination Therapy of a Host Defense-Like Lytic Peptide and Continuous Low-Dose Doxorubicin Inhibits Tumor Growth in a Syngeneic Immunocompetent Murine Fibrosarcoma (BFS-1) Model

Background: The concept of a multimodality therapy in the treatment of soft tissue sarcomas (STS) has been discussed with controversy. Surgical resection with clear margins and radiation therapy remain gold standard in STS therapy. It is still questionable whether a systemic therapy with chemotherapeutics has a positive impact on the overall survival rate especially in early stages of disease, because the therapeutic effect in the treatment of STS is limited by its toxicities and its low responding rates. Treatment options are rare. As a result the search for combination therapies by using low dose approaches is of high importance. Recent studies showed the therapeutic efficiency of a designer host defense-like lytic D,L- amino acid peptide [D]-K 3 H 3 L 9 . Therefore we tested a combination of this peptide with Doxorubicin on two different sarcoma cell lines in vitro and also in a syngeneic immunocompetent murine fibrosarcoma mouse model. Methods: In vitro the human synovial sarcoma cell line SW 982 and the murine fibrosarcoma cell line BFS-1 were exposed to the oncolytic peptide [D]-K 3 H 3 L 9 , to the Anthracycline Doxorubicin and to both agents simultaneously. In vivo the murine fibrosarcoma cell line BFS-1 was injected subcutaneously into the syngeneic mice. When the tumors engrafted the oncolytic designer peptide [D]-K 3 H 3 L 9 , Doxorubicin or a combination of both was administered thrice a week for a three weeks’ follow-up. Results: The combination treatment approach using an oncolytic designer host defense peptide and Doxorubicin inhibited the in vitro sarcoma cell proliferation significantly. The single therapies, either with local intratumoral application of [D]-K 3 H 3 L 9 or with intraperitoneal application of Doxorubicin in the syngeneic mouse model, inhibited at least the tumor progression. The combination of both substances revealed a significant inhibition of tumor growth and weight. Conclusion: The in vivo low dose combination schedule inhibited the tumor growth significantly. Histological analyses of the tumor sections revealed an antiproliferative and antiangiogenic effect. So, these results demonstrate the effectiveness of combined low-dose application forms with designer host defense-like lytic peptides and chemotherapeutics.