Actin-dependent tumour cell adhesion after short-term exposure to the antimetastasis ruthenium complex NAMI-A.

Imidazolium trans-imidazoledimethylsulphoxidetrachlororuthenate (NAMI-A) was tested in vitro on the pro-adhesive properties, evaluated as resistance to trypsin treatment, which is a bona fide measure of adhesion strength, of KB and HeLa carcinoma cell lines and on human polymorphonuclear neutrophils (HPMN). NAMI-A increased the pro-adhesive activity of KB cells at 0.001 mM concentration, after few minutes incubation and this effect was not influenced by the vehicle used for cell challenge, neither did it depend on NAMI-A concentration or on temperature. The same effect occurred on HeLa cells at 0.01 mM NAMI-A. This effect, detected at concentrations up to 100 times lower than those necessary to block cells at the G(2)-M premitotic phase of cell cycle, or to inhibit matrix metalloproteinase release or cell invasion, was not related to ruthenium uptake by tumour cells. HeLa cells and healthy HPMN, following short exposure to 0.1 mM NAMI-A, assumed a different shape, with the extrusion of filopodia (HeLa) and of large lamellopodia (HPMN), which increased their interactions with the substrate. This effect was attributed to stabilisation, altered turnover and sensitivity to cytochalasin D of actin filaments. Provided that adhesion is associated with cell motility and invasion, these data suggest that NAMI-A may exert antimetastatic properties at concentrations lower than those observed in the lungs at the end of a conventional intraperitoneal treatment in vivo.

Preparation of an antibody recognizing both human and rodent MRP1.

Based on the high level of identity among human, mouse, and rat MRP1 protein sequence, we produced a specific polyclonal antibody (MRP1-A23) against a synthetic polypeptide covering the C-terminus of the human protein. Western blot analysis showed a reactivity against human MRP1 similar to that obtained with the monoclonal QCRL1 antibody. Differently from other available antibodies against human MPR1, MRP1-A23 also detected both rat and mouse MRP1. No cross-reactivity was observed with either human or mouse MRP2 while MRP1-A23 weakly cross-reacted with rat MRP2 in the protein region ranging from 1512 to 1533 amino acids. These data indicate that MRP1-A23 allows specific MRP1 detection in both human and rodent tissues and may provide an important tool in the study of MRP1 expression and function in both experimental and clinical materials.