Characterization of TNP-470-induced modifications to cell functions in HUVEC and cancer cells.

The aim of the present work is to characterize (both in vitro and in vivo) the influence of TNP-470 on different cell functions involved in angiogenesis and, more particularly, on endothelial cell growth, cell migration and vessel formation. In addition, a possible direct anti-tumor activity was investigated. To this end, we made use in vitro of human umbilical cord endothelial vein (HUVEC) cells and two human cancer cell lines. The TNP-470 effects on the growth of cancer cell lines were compared to those of Taxol (an inhibitor of microtubule depolymerization), a cytotoxic reference which also displays strong antiogenic activity at low (non-toxic) doses. The in vitro effects were characterized on the mouse mammary MXT adenocarcinoma, on which we also characterized the influence of three clinically active anti-tumor compounds (as cytotoxic references). The purpose of this part of the study was to determine the actual TNP-470-related anti-tumor activity and to evaluate the possible toxic side-effects at the doses at which this compound induces tumor growth inhibition. These investigations were completed by analyzing the TNP-470 effects on HUVEC cell motility and in vitro and in vivo vessel formation. The results show that in vitro, TNP-470 inhibited the growth not only of HUVEC, but also of neoplastic cells. Furthermore, TNP-470 clearly inhibited in vitro endothelial cell motility (p<10(-5)). However, it had only a minor effect (p=0.02) on the formation of HUVEC cell networks on Matrigel(R). In vivo, TNP-470 was able to inhibit tumor growth (on the MXT model) at a dose (50 mg/kg) associated with toxic side-effects. Histological examination showed a significant inhibition of vessel formation (p<0.001) at high (toxic) and intermediary (non-toxic) doses (50 and 20 mg/kg). However, we also observed that TNP-470 stimulated lymphocyte proliferation. Thus, care must be taken with the TNP-470 compound in combination with other anti-tumoral agents in order to avoid certain unfortunate clinical complications.

In vitro and in vivo pharmacological characterizations of the antitumor properties of two new olivacine derivatives, S16020-2 and S30972-1.

S16020-2, a new olivacine derivative and a topoisomerase II inhibitor, has recently entered clinical trials. New analogues and derivatives have been synthesized from the S16020-2 compound. Preliminary data indicate that S30972-1, one of these S16020-2 derivatives, may exhibit a comparatively higher level of antitumor potency associated with an improved therapeutic index than does S16020-2. The antitumor activities of S16020-2 and S30972-1 were therefore characterized both in vitro and in vivo, with Adriamycin and etoposide chosen as reference compounds. The in vitro data show that S30972-1 is a topoisomerase II inhibitor, mediating its activity through an ATP-dependent mechanism such as S16020-2. The two olivacine derivatives exhibited similar activities in vitro at the levels of the global growth of six human cancer cell lines, of the induction of apoptosis, and of the G2 cell cycle phase arrest. The in vivo antitumor activity characterization included the use of two murine leukemia types (P388-LEU and L1210-LEU), two murine lymphoma-like models (P388-LYM and L1210-LYM), two mammary adenocarcinomas (MXT-HI and MXT-HS), and one melanoma (B16). The data show that S30972-1 is actually more efficient in vivo than S16020-2, a feature that may relate to the fact that S30972-1 is less toxic than S16020-2. The S30972-1 compound exhibited in vivo a level of antitumor activity that was also actually higher than that exhibited by Adriamycin and similar to that exhibited by etoposide.

Characterization of biological features and chemosensitivity of a new experimental lung metastasis model originating from the MXT mouse mammary adenocarcinoma.

The present study shows how an original mouse metastatic lung model was established from the MXT mammary adenocarcinoma. This metastatic model was obtained by injecting the C/MET clone into the tail veins of B6D2F1 mice. The C/MET clone corresponds to one of eleven cell clones that were isolated in vitro from the MXT model. Of these 11 clones, only the C/MET leads to lung metastatic tumor development when injected i.v. into mice. Furthermore, the C/MET clone colonizes the lung only. The present data show that the C/MET metastatic model and the MXT parental line are weakly (if reference is made to the P388 leukemia model) sensitive to adriamycin, clyclophosphamide and etoposide. However, under specific experimental conditions, the chemosensitivity of the C/MET model can be significantly increased. The C/MET model therefore appears to be an interesting pharmacological tool to test new investigational agents with anti-tumor potentialities to lung metastases.

Setting up of an original computer-assisted methodology to characterize in vitro drug-induced anti-angiogenic effects.

The development of angiogenesis within a tumor brings on a sequence of extremely complex molecular events. We have developed a methodology which enables a wide set of biological parameters to be quantitatively determined in the field of anti-angiogenesis pharmacology. This methodology which includes a video cell tracking device, is unique because it offers the possibility of evaluating the specific influence of a given compound with potential anti-angiogenic properties on cell cycle kinetics, cell death, global cell line growth, and cell motility. We chose TNP-470, a synthetic analogue of fumagilin, to test our methodology on HUVEC cell lines taken from various human umbilical cord veins. The experiments carried out with TNP-470 did not confirm all the data reported in the literature. Our results show that i) TNP-470 could be considered as a cytotoxic agent; ii) this compound had an apparently marginal cytostatic effect; and iii) it did not increase the apoptosis level. Our methodology also revealed that the HUVEC cell lines are very heterogeneous in terms of different biological parameters. This highlights the problem of the reproductibility of the result.