Soluble factors from the target organ enhance tumor cell angiogenesis: role of laminin SIKVAV sequence.

The ability of tumor cells to respond to microenvironmental factors present in the target organ determines in part the successful development of a metastasis. In a previous work it was demonstrated that the conditioned medium (CM) from lungs of normal mice stimulates in vitro migration, proliferation and uPA activity of cells from a murine mammary adenocarcinoma moderately metastatic to lung. This CM also enhanced local and metastatic tumor growth. Here, we show that lung CM enhanced neovascularization when inoculated together with LM3 tumor cells into the skin of syngeneic mice. A similar tumor-induced angiogenesis response was obtained when lung CM was injected systemically. Western blot analysis of lung CM revealed the presence of some laminin fragments containing the sequence SIKVAV. To determine whether those molecules were responsible for the observed angiogenic effects, the CM was depleted of the peptides containing the SIKVAV sequence. We observed that the SIKVAV-depleted lung CM lost its ability to induce an enhancement of the tumor neovascular response. Our results suggest a role for the target organ in facilitating the neovascularization of tumor cells, probably through the participation of active peptides derived from the proteolytic degradation of the basement membrane component laminin.

Differential nitric oxide release and sensitivity to injury in different murine mammary tumor cell lines.

The purpose of this study was to determine whether nitric oxide (NO) production by different mammary tumor cell lines correlated with their sensitivity to NO mediated injury. Three mammary tumor cell lines LM2, LM3 and LMM3 syngeneic to BALB/c mice were cultured in vitro with IFNgamma + LPS. Different levels of NO production among the three lines were detected in culture supernatants. The only tumor cell line which did not produce NO (LM2) showed the highest sensitivity to SNP-derived NO cytotoxicity (87%), while LM3 and LMM3 which both produced higher levels of NO than LM2, showed lower cytotoxicity by SNP (39% and 22% respectively). Spleen cells (SC) from M2 tumor bearing mice (TBM) were able to lyse LM2 cells by NO-dependent mechanisms. SC from M3-TBM exerted cytotoxicity against LM3 cells mainly by NO-independent mechanisms. Thus, we postulate an inverse correlation between NO production and NO mediated cytotoxicity in the three mammary tumor cell lines. It is possible that tumor cells producing NO develop mechanisms to resist NO injury.

Hydrogen peroxide is involved in lymphocyte activation mechanisms to induce angiogenesis.

T-lymphocytes from tumour-bearing mice are able to trigger the angiogenic cascade. Since it is known that tumour growth produces reactive oxygen species (ROS), the aim of this study was to evaluate the role of hydrogen peroxide (H2O2) on the activation of lymphocytes and their induction of this vascular response. Studies on lymphocytes, stimulated in vitro by ROS to induce angiogenesis, showed that only the enzyme catalase (CAT) could block the activation. The incubation of normal lymphocytes with H2O2 stimulated these cells to induce angiogenesis. The administration of H2O2 or an oxidative stress-producing drug (doxorubicin) to normal mice activated in vivo angiogenesis. In tumour-bearing mice, high levels of lipid peroxidation products were observed in the spleen, but not in the liver or kidney. Moreover, when the ROS scavenger enzyme activities (superoxide dismutase (SDM) and CAT) were determined, we observed low CAT activity in normal spleens, reflected in a high SDM/CAT ratio, when compared to liver or kidney values. We also showed an increasing value of the SDM/CAT ratio with tumour growth. These results strongly suggest that H2O2 could be involved in the mechanisms of lymphocyte activation and their induction of angiogenesis during tumour growth.

Lymphocyte-induced angiogenesis: effect of different antigenic stimuli.

It is known that tumor cells activate spleen cells to induce an angiogenic response. In this report we studied whether different antigenic stimuli, other than tumor cells, were able to activate spleen lymphocytes to induce angiogenesis in syngeneic combination (SLIA). For this purpose, mice were inoculated with sheep red blood cells (SRBC), allogeneic kidney and syngeneic fetal tissues. The effect of pregnancy (syngeneic or allogeneic) on the ability of spleen cells to induce a neovascular response was also assessed. None of the different stimuli were able to induce spleen lymphocytes to evoke angiogenesis. Although allogeneic lymphocytes from virgin females induced a strong neovascular response, the same population, but from allogeneic pregnant mice, did not evoke this response. We conclude that tumor cells seem to be the only antigenic stimuli able to activate spleen lymphocytes to induce SLIA.

Inhibition of lymphocyte-induced angiogenesis by free radical scavengers.

Solid tumors induce an angiogenic response by the host blood vessels to form a new vascular network for the supply of fresh nutrients and oxygen responsible for tumor growth. Furthermore, tumor growth and metastatic spread is abrogated or markedly reduced in the absence of neovascularization. Spleen T lymphocytes from tumor-bearing mice elicit a strong neovascular response. It is well known that certain T cell responses require the presence of active oxygen radicals. Because these metabolites are produced during tumor growth, we studied whether oxygen free radicals play a role in the angiogenesis induction by lymphocytes. In this study, we demonstrated that the administration of a free radical scavenger (EGb-761) to tumor-bearing mice, blocked the angiogenic response and decreased the lung metastatic incidence. On the other hand, when normal lymphocytes were incubated with the xanthine-xanthine oxidase system (X-XO), a known superoxide anion generator, this elicited a dose-response positive angiogenic reaction in normal recipient mice. No angiogenic response was observed in the absence of X-XO, or when EGb-761 or superoxide dismutase (SOD) plus catalase (CAT) were added to the incubation medium. These results suggest that free radicals are involved in some step of the angiogenic process, and that the EGb-761 treatments block this response due to the free radical scavenging activity of this compound.