Therapeutical effect of activated human macrophages on a human tumor line growing in nude mice

Gemcitabine induces polarization of mouse peritoneal macrophages towards M1-like and confers antitumor property by inducing ROS production

In patients with pancreatic cancer (PC), the peritoneal cavity is the second-most common site of metastasis after the liver. Peritoneal macrophages (PMs) have been demonstrated to play a significant role in the peritoneal metastases of different cancers. Gemcitabine (GEM) is known to affect PC-associated immune cells, including macrophages. However, its effect on PMs and its possible clinical implication is yet to be investigated. In this study, mouse-derived PMs were treated with GEM ex vivo to analyze the polarization status. Production of GEM-induced reactive oxygen species (ROS) and reactive nitrogen species was evaluated using DCFH-DA, DAF-FM, and Griess assay. Antitumor effects of PMs on UN-KC-6141and UN-KPC-961 murine PC cells were evaluated in presence and absence of GEM in vitro. Similarly, effect of GEM on human THP-1 macrophage polarization and its tumoricidal effect was studied in vitro. Furthermore, the effect of GEM-treated PMs on peritoneal metastasis of UN-KC-6141 cells was evaluated in a syngeneic mouse model of PC. GEM upregulated M1 phenotype-associated molecular markers (Tnf-α and Inos) in vitro in PMs obtained from naïve mouse. Moreover, IL-4-induced M2-like PMs reverted to M1-like after GEM treatment. Co-culture of UN-KC-6141 and UN-KPC-961 cancer cells with PMs in the presence of GEM increased apoptosis of these cells, whereas cell death was markedly reduced after N-acetyl-L-cysteine treatment. Corroborating these findings co-culture of GEM-treated human THP-1 macrophages also induced cell death in MIAPaCa-2 cancer cells. GEM-treated PMs injected intraperitoneally along with UN-KC-6141 cells into mice extended survival period, but did not stop disease progression and mortality. Together, GEM induced M1-like polarization of PMs from naive and/or M2-polarized PMs in a ROS-dependent manner. GEM-induced M1-like PMs prompted cytotoxicity in PC cells and delayed disease progression in vivo.

Therapeutic potential of nanoparticulate systems for macrophage targeting

The use of non-viral nanoparticulate systems for the delivery of therapeutic agents is receiving considerable attention for medical and pharmaceutical applications. This increasing interest results from the fact that these systems can be designed to meet specific physicochemical requirements, and they display low toxic and immunogenic effects. Among potential cellular targets by drug-loaded nanoparticles, macrophages are considered because they play a central role in inflammation and they act as reservoirs for microorganisms that are involved with deadly infectious diseases. The most common and potent drugs used in macrophage-mediated diseases treatment often induce unwanted side effects, when applied as a free form, due to the necessity of high doses to induce a satisfactory effect. This could result in their systemic spreading, a lack of bioavailability at the desired sites, and a short half-life. Therefore, the use of drug-loaded nanoparticles represents a good alternative to avoid, or at least decrease, side effects and increase efficacy. In this manuscript, we present an overview of the usefulness of nanoparticles for macrophage-mediated therapies in particular. We discuss, though not exhaustively, the potential of therapeutic agent-loaded nanoparticles for some macrophage-mediated diseases. We also underline the most important parameters that affect the interaction mechanisms of the macrophages and the physicochemical aspects of the particulate systems that may influence their performance in macrophage-targeted therapies.

Dynamic assessment of angiogenesis in renal cell carcinoma spheroids by intravital microscopy

PURPOSE

Renal cell cancer represents a suitable tumor model for in vivo observation of neo-angiogenesis. We used intravital microscopy and the well established dorsal skin fold chamber model to characterize neo-angiogenesis in freely implanted renal cell cancer spheroids.

MATERIAL AND METHODS

Tumor spheroids were implanted into dorsal skin fold chambers of 8 nude mice. At days 3, 6, 10 and 14 after implantation the newly vascularized spheroid area, density of perfused microvessels in the spheroid versus the periphery, capillary center erythrocyte velocity and capillary diameter were recorded by intravital microscopy. Video images were analyzed by a computer assisted image analysis device. After the experiments the chambers were analyzed morphologically.

RESULTS

The model enabled quantitative analysis of microcirculation and angiogenesis in the renal cell cancer spheroids during 14 days of observation. Mean spheroid center perfused microvessel density +/- SEM increased from 3 +/- 2 to 269 +/- 21 cm.-1 on days 3 to 10 and subsequently decreased to 189 +/- 38 cm.-1 on day 14. Spheroid periphery perfused microvessel density was significantly higher throughout the experiments, attaining a mean maximum of 522 +/- 34 cm. on day 14. Mean capillary diameter decreased continuously from 14.2 +/- 0.9 to 8.4 +/- 0.4 microm. on days 3 to 14. In contrast, mean capillary center erythrocyte velocity significantly increased during 14 days of observation from 0.09 + 0.02 mm. per second on day 3 to 0.24 +/- 0.08 mm. per second on day 14. Histological analysis after 14 days revealed the spheroids as cell clusters in the upper layers of the dorsal skin fold chamber.

CONCLUSIONS

The model is suitable for the analysis of renal cell cancer angiogenesis. Although it is heterotopic, angiogenesis in renal cell cancer spheroids mimics important characteristics of human renal cell cancer.

Activation of Kupffer cells inhibits tumor growth in a murine model system

Kupffer cells, a liver organ-specific macrophage, play an important role in preventing the development of malignant tumors. The mechanism responsible for their tumoricidal activities is not completely known. In our study, we established in vivo models involving a rat malignant cell line, rat Kupffer cells and tumor implantation in nude mice. A series of relevant in vitro experiments were also carried out to determine possible pathways. LPS-activated Kupffer cells produced significant amounts of NO, TNFalpha and IFNgamma. Malignant cells treated with either Kupffer cells or culture supernatant of the activated Kupffer cells had an increase in caspase-8 activity. Implanted tumors originated from malignant cells treated with either Kupffer cells or culture supernatant of the activated Kupffer cells grew much smaller than those from malignant cells without treatment or treated with control supernatants. The alteration of anti-apoptotic Bcl-2 was inversely associated with the change of pro-apoptotic caspase-8 and their levels in the tumor tissues matched the size of the tumors and treatments they received. It appeared that the above changes resulted in an increase in cellular DNA damage and apoptosis seen in malignant cells. Therefore, Kupffer cells execute their anti-tumor effect via increasing the production of NO, TNFalpha and IFNgamma and these cytotoxic molecules inhibit the growth of tumor by damaging cellular DNA and inducing apoptosis that was featured by downregulation of Bcl-2 but upregulation of caspase-8.