E. A. Seftor

Effects of antioxidant enzyme overexpression on the invasive phenotype of hamster cheek pouch carcinoma cells

To examine the role of reactive oxygen species on the invasive phenotype of cancer cells, we overexpressed manganese- and copper-zinc-containing superoxide dismutases (MnSOD, CuZnSOD) and catalase (Cat) in hamster cheek pouch carcinoma (HCPC-1) cells in vitro using adenoviral vector-mediated gene transfer. Hamster cheek pouch carcinoma cells were transduced with these adenoviral vector constructs alone, or in combination, at concentrations [i.e., multiplicity of infectivity (MOI)] of 100 MOI each. The Escherichia coli beta-galactosidase reporter construct was used as a control virus. Protein expression was examined by Western blot analysis and enzymatic activities were measured using spectrophotometry. To observe the effects of transgene overexpression on in vitro tumor cell invasion, we used the membrane invasion culture system, an accurate and reliable method for examining tumor cell invasion, in vitro. This assay measures the ability of tumor cells to invade a basement membrane matrix consisting of type IV collagen, laminin, and gelatin. MnSOD overexpression resulted in a 50% increase in HCPC-1 cell invasiveness (p < .001); co-overexpression of MnSOD with Cat partially inhibited this effect (p < .05). Moreover, co-overexpression of both SODs resulted in a significant increase in invasiveness compared with the parental HCPC-1 cells (p < .05). These changes could not be correlated with the 72 kDa collagenase IV or stromolysin activities using zymography, or the downregulation of the adhesion molecules E-cadherin or the alpha4 subunit of the alpha4beta1 integrin. These results suggest that hydrogen peroxide may play a role in the process of tumor cell invasion, but that the process does not rely on changes in matrix metalloproteinase activity in the cells, or the expression of cell adhesion molecules.

Adriamycin-induced inhibition of melanoma cell invasion is correlated with decreases in tumor cell motility and increases in focal contact formation

Tumor cell adhesion to the extracellular matrix (ECM) is closely linked with tumor cell invasion and metastasis. In this study, we demonstrate that low levels of adriamycin, a widely used anticancer drug, can inhibit the invasion of highly metastatic K1735-M2 mouse melanoma cellsin vitro through a reconstituted basement membrane extract. Adriamycin-induced inhibition of melanoma cell invasion occurred at levels of the drug (i.e. 1 ng/ml) that did not inhibit tumor cell growth, suggesting that the observed inhibition in tumor cell invasion was not due to the well-documented ability of adriamycin to interfere with DNA and/or RNA synthesis. Rather, these studies indicated that adriamycin-induced inhibition of melanoma cell invasion was accompanied by a corresponding decrease in the ability of adriamycin-treated tumor cells to migrate in response to several isolated ECM components including fibronectin, laminin and basement membrane (type IV) collagen. The decreased migration of adriamycin-treated tumor cells was not accompanied by a decrease in the adhesion or spreading of the adriamycin-treated cells on substrata coated with these ECM components. Instead, adriamycin-treated cells actually exhibited a slightly increased propensity (compared to untreated control cells) to adhere on fibronectin-, laminin-, and type IV collagen-coated substrata. Additionally, adriamycin treatment caused a dramatic increase in focal contact formation by these melanoma cells, as assessed by fluorescent microscopy of actin and vinculin. In addition to providing a useful model for which to study the molecular and cellular basis for focal contact formation, these results further emphasize the results of several other investigators that have suggested an important role for focal contacts in modulating tumor cell motility, invasion and metastasis.

Application of chemically modified tetracyclines (CMTs) in experimental models of cancer and arthritis.

The biological mechanisms underlying cancer and arthritis share many commonalities, of which destruction of extracellular matrix (ECM) barriers and invasion are critical events. Liotta and colleagues have presented a model which describes the invasive process as a logical progression of events involving three discernible stages: attachment of tumor cells to an extracellular matrix (ECM), proteolytic digestion of the matrix, and movement of cells through the proteolytically degraded barrier—regulated by myriad signal transduction pathways (Liotta et al, 1986; Stetler-Stevenson et al, 1993). Thus, a key factor in this process is the regulation of the matrix metalloproteinases (MMPs; including gelatinases A and B; MMP-2 and MMP-9, respectively), which play a major role in the degradation of the ECM during degradation and invasion (Stetler-Stevenson et al, 1993, 1996; Cockett et al, 1994; Himelstein et al, 1994; Noel et al, 1994; Kohn and Liotta. 1995). With these principal biological parameters in mind, investigators have focused therapeutic strategies on inhibiting the invasive activity of tumor cells and arthritic synoviocytes in an attempt to suppress the invasive phenotype. Indeed, an extensive body of research has demonstrated that tetracyclines are potent inhibitors of MMP activity, particularly collagenase, gelatinases, and macrophage elastase, both in vitro and in vivo, which is distinct from their antimicrobial activities (see Golub et al [1991],

Cloning efficiency of human melanoma cells is modulated after invasion through a reconstituted basement membrane

Three human malignant melanoma cell strains (C8146A, C8146C, and C83-2CY), three established human melanoma cell lines (A375P, A375M, and C8161), and one selected human melanoma subline (A375P-5) were studied to determine if invasion through a reconstituted basement membrane-coated filter (RBMF), which selects the most aggressively invasive cells, would also modulate the cloning efficiency of these cells in soft agar. With the use of the Membrane Invasion Culture System (MICS), all cell strains tested showed a significant increase in cloning efficiency (1.05-9.3-fold) following transit through the RBMF when compared to unmanipulated populations. The established cell lines (A375P, A375M, and C8161) and the A375P-5 subline showed either a decrease or unaltered status in cloning efficiency after invasion. However, all cells demonstrated a consistent decrease in clonogenicity following transit through an uncoated filter compared with RBMFs, thus suggesting the influence of the extracellular matrix on tumor cell clonogenic properties. In general, the established cell lines were more clonogenic before invasion of the RBMF compared with the cell strains, and no correlation was found between clonogenic potential and invasive or metastatic capability. These data may provide important insight into the underlying mechanisms of tumor cell invasion and the subsequent formation and dissemination of metastases in vivo.

A comparison of levels of intrinsic single strand breaks/alkali labile sites associated with human melanoma cell invasion

Intrinsic levels of protein-free single strand breaks/alkali-labile sites in human melanoma cell populations of varying in vitro invasive capacity have been assayed with DNA filter elution methodology. DNA from two human melanoma cell lines, A375P and C8161, and from a subpopulation selected from A375P, A375P-5, were assayed to test the hypothesis that increased levels of DNA damage may be associated with the phenotype of increased invasive and metastatic capacities. The elution profiles obtained reveal statistically significant increases in the level of single strand breaks and/or alkali-labile sites (SSB/ALS) which correlate with increasing invasive and metastatic capacities. The increased levels of SSB/ALS in A375P-5 observed in freshly selected cells decline as these cells are maintained in culture. The stability of this A375P-5 phenotype correlates with previously reported levels of double minute chromosomes, an indicator of genomic instability. Alterations in average intrinsic levels of cellular lesions are therefore an additional factor to be considered in the phenotypic characterization of invasive and metastatic tumor cells and may reflect or contribute to the genomic instability characteristic of tumor cell populations.