Expression and cellular localization of messenger RNA for plasminogen activator inhibitor type 1 in human astrocytomas in vivo

We investigated the expression and cellular localization of plasminogen activator inhibitor type 1 (PAI-1) in human astrocytoma in vivo. Northern blot and densitometric quantitation of PAI-1 mRNA indicated that PAI-1 transcripts were significantly higher in human malignant astrocytomas and especially in glioblastomas than in low-grade gliomas and normal brain tissues in vivo. Using in situ hybridization with paraffin-embedded surgical specimens of human gliomas and normal brain tissues, PAI-1 mRNA was abundantly expressed in glioblastomas. PAI-1 mRNA was localized mainly in tumor cells and endothelial cells. The distribution of PAI-1 mRNA expression was particularly abundant around areas of vascular proliferation and in remnant tumor cells surrounding necrotic foci. PAI-1 mRNA was also expressed in both the tumor and endothelial cells of anaplastic astrocytomas, whereas it was not expressed or only weakly expressed in low-grade astrocytomas or normal brain tissues. These results suggest that high expression of PAI-1 is associated with the malignant progression of astrocytic tumors and that excessive PAI-1 expression might be associated with intratumoral necrosis in glioblastomas.

c-erbB-2/neu overexpression enhances metastatic potential of human lung cancer cells by induction of metastasis-associated properties

Previously, we and others have reported high levels of expression of the c-erbB-2/neu gene in non-small cell lung cancer cell lines and primary tumors. We have also found that expression of c-erbB-2/neu-encoded p185neu was correlated with lymph node metastasis in lung squamous cell carcinomas. To investigate the potential role of the c-erbB-2/neu gene in lung cancer metastasis systematically, we introduced the human c-erbB-2/neu gene into very low p185neu-expressing NCI-H460 human non-small cell lung cancer cells and then examined the experimental metastatic potentials among the parental NCI-H460 cells and stable transfectants with increased expression of p185neu. Compared with the parental NCI-H460 cells, the NCI-H460 transfectants overexpressing p185neu produced significantly more pulmonary and extrapulmonary metastatic tumors in nude mice. The changes in experimental metastatic potential in vivo were accompanied by increased invasiveness in vitro. In addition, important steps in the invasion and metastasis process, such as secretion of basement membrane-degradative enzymes and migration through reconstituted basement membrane (Matrigel), were also increased in the NCI-H460 transfectants overexpressing p185neu. Moreover, scanning electron microscopy revealed that the p185neu-overexpressing NCI-H460 transfectants had significantly more microvilli and membrane protrusions than the parental cells, correlating with the increased invasive properties of these cells. The results demonstrate that overexpression of p185neu can enhance the experimental metastatic potential of NCI-H460 human lung cancer cells by promoting invasion and the other steps in the metastatic cascade.

Activities, localizations, and roles of serine proteases and their inhibitors in human brain tumor progression

The plasminogen activation system consists of plasminogen activators and their inhibitors, serine proteases, and serpins. The proteases and inhibitors regulate a variety of processes in tissue morphogenesis, differentiation, cell migration, and cancer cell invasiveness and metastasis. One of the plasminogen activators, urokinase-type plasminogen activator (uPA), binds to a specific surface and provides a localized cell surface proteolytic activity required for the destruction of extracellular matrix, which is a vital step in tumor cell invasion. The proteolytic activity of uPA is modulated by its cell surface receptor, as well as by plasminogen activator inhibitor type-1 (PAI-1) and, to a lesser degree, by other inhibitors. The role of plasminogen activators and their inhibitors in cancer invasion can be demonstrated in the development and progression of malignant brain tumors. Our findings indicate that uPA and PAI-1 expression are dramatically upregulated in malignant brain tumors in parallel with the histological progression of the tumors. The results suggest that these molecules may contribute to tumor invasion in addition to their significant role in angiogenesis. An evaluation of the plasminogen activation system could add diagnostic and prognostic significance to the evaluation of individual patients.

Tumor metastasis to brain: role of endothelial cells, neurotrophins, and paracrine growth factors

An important clinical endpoint in patients with cancer is formation of metastases in the brain. Understanding this phenomenon is important in several types of malignancies, including melanoma, lung and breast cancers. Metastatic tumor cells use specific adhesion molecules to home to brain, and there they must attach to microvessel endothelial cells and respond to brain endothelial cell-derived motility factors and brain invasion factors to invade the CNS. Neurotrophins are important invasion factors in this process, and the ability to invade into the brain may well depend on metastatic cell responses to neurotrophins and production of basement membrane-degradative enzymes capable of locally destroying the blood-brain barrier. Brain-metastatic human melanoma cells express low-affinity p75 receptor for neurotrophins such as nerve growth factor, but they do not express the high-affinity-type receptors for nerve growth factor encoded by the protooncogene trkA. Tumor cells can proliferate in the CNS in response to local paracrine growth factors and inhibitors, but their growth also depends on their producing and responding to autocrine growth factors. A major organ-derived (paracrine) growth factor has been isolated that differentially stimulates the growth of cells metastatic to the brain. Characterization of this mitogen demonstrated that it is a transferrin-like glycoprotein; cells that are metastatic to brain express greater numbers of transferrin receptors on their surfaces than cells that are poorly metastatic or metastatic to other sites. Transferrin-like factors are expressed in fetal brain and could represent the transferrin-like factors that stimulate growth of brain-metastatic melanoma and breast cancer cells. These and other factors are probably important in determining whether metastatic cells can successfully invade, colonize, and grow in the CNS.

Malignant melanoma metastasis to brain: role of degradative enzymes and responses to paracrine growth factors

Mouse and human melanoma cells metastatic to the brain express degradative enzyme activities that are used for invasion of brain basement membrane and parenchyma. Compared to poorly metastatic or lung- or ovary-metastatic murine melanoma lines, the brain-metastatic sublines secreted higher levels of a variety of degradative enzymes. Brain-metastatic murine and human melanoma cells also degraded subendothelial basement membrane and reconstituted basement membrane at rates higher than other metastatic melanoma cells. In some cases these degradative activities in mouse and human melanoma cells can be induced by paracrine factors known to be present in the brain parenchyma, such as nerve growth factor (NGF). NGF stimulates the expression of degradative enzymes, such as the endo-beta-glucuronidase heparanase, that are important in basement membrane penetration but this factor does not stimulate melanoma cell growth. The growth of brain-metastasizing melanoma cells appears to be stimulated by other paracrine growth factors, such as paracrine transferrin. Melanoma cells metastatic to brain express higher numbers of transferrin receptors and respond and proliferate at lower concentrations of transferrin than do melanoma cells metastatic to other sites or poorly metastatic melanoma cells. The results suggest that degradation and invasion of brain basement membrane and responses to paracrine neurotrophins and paracrine transferrins are important properties in brain metastasis of murine and human malignant melanoma cells.

Serum and plasma M(r) 92,000 progelatinase levels correlate with spontaneous metastasis of rat 13762NF mammary adenocarcinoma

The expression of metalloproteinases, such as type IV collagenase/gelatinase, enables tumor cells to degrade type IV collagen present in the basement membrane and correlates with metastatic potential of several tumor types. We found that increased levels of rat serum type IV collagenolytic activity are associated with increased 13762NF mammary adenocarcinoma metastases in lungs and lymph nodes of syngeneic rats. To investigate serum metalloproteinases responsible for type IV collagenolysis, we performed zymography and Western blot analysis of rat sera. A M(r) 92,000 progelatinase (progelatinase B, M(r) 92,000 type IV procollagenase, MMP-9) was detected on zymograms of rat sera within 16 days after intramammary fat pad inoculation of highly metastatic MTLn3 cells. The activated serum M(r) 92,000 progelatinase degraded sodium dodecyl sulfate-denatured type I and IV collagens but was not active on casein, albumin, hemoglobin, and immunoglobulin. Sera from rats with fat pad tumors and lung metastases formed from highly metastatic clones possessed greater than 7 times higher levels of serum M(r) 92,000 progelatinase than control sera or sera from rats bearing similar size fat-pad tumors of low or nonmetastatic clones. The results were confirmed by Western blot analysis of rat sera using rabbit anti-human M(r) 92,000 progelatinase antibodies. Similar results were obtained from the analysis of rat plasma samples. The serum and plasma M(r) 92,000 progelatinase levels correlated with the extent of metastases in the lung and lymph nodes. The results indicate that high levels of serum and plasma M(r) 92,000 progelatinase are associated with the presence of disseminated metastatic adenocarcinoma cells and suggest that this enzyme may facilitate the invasion of blood-borne tumor cells through vascular basement membranes.

Selection for enhanced adhesion to microvessel endothelial cells or resistance to interferon-gamma modulates the metastatic potential of murine RAW117 large-cell lymphoma cells

Poorly liver metastatic large-cell lymphoma RAW117-P cells were sequentially selected in vitro for increased adhesion to murine hepatic sinusoidal endothelial cells. After three or four sequential selections, the selected sublines showed increased rates of adhesion to target hepatic microvessel endothelial cells and increased formation of experimental metastases in the liver. However, the endothelial cell adhesion-selected RAW117 sublines were generally unstable and gradually lost their enhanced adhesive and metastatic properties during passage in culture. Highly metastatic, liver-selected RAW117-H10 large-cell lymphoma cells were more resistant to the cytostatic effects of interferon-gamma (IFN-gamma) than poorly metastatic unselected parental RAW117-P cells. When tested for their sensitivity to IFN-gamma, the endothelial cell adhesion variants were significantly more resistant than the unselected RAW117-P cells, but after a 72-h treatment with IFN-gamma, the in vitro-selected cells lost their enhanced endothelial cell adhesion characteristics, their potential to colonize the liver, and their ability to grow when injected at subcutaneous or intramuscular sites. In contrast, the metastatic potential of similarly treated RAW117-P cells was unaffected by IFN-gamma during a 72-h treatment. Sequential selection of RAW117-P cells for increased resistance to IFN-gamma in vitro resulted in variant lines that were refractory to the growth-inhibiting effects of IFN-gamma, and these IFN-gamma-selected variants were also less adhesive to liver microvessel endothelial cells. The IFN-gamma-selected variants also lost their experimental metastatic potentials completely and their tumorigenicities at sites of subcutaneous or intramuscular injection. Cytofluorographic analysis indicated reduced cell surface expression of H-2Kd antigen and fibronectin receptor on the selected variant cells but no change in cell surface mu heavy chain immunoglobulin. The unselected and selected RAW117 lines had similar sensitivities to natural killer (NK) cell-mediated cytolysis, indicating that the in vivo differences were probably not due to differences in NK cell-mediated cytolysis. The results suggest that selection for adhesion to organ microvessel endothelial cells or sequential exposure to certain cytokines can affect the adhesive, growth and metastatic properties of RAW117 cells without modifying their responses to NK cells.

Mediation of NGF-stimulated extracellular matrix invasion by the human melanoma low-affinity p75 neurotrophin receptor: melanoma p75 functions independently of trkA

Although overexpression of the low-affinity p75 neurotrophin receptor (p75NTR) is frequently associated with advanced stages of human melanoma progression, the functional significance of this finding is unknown. We examined whether the degree of cell surface expression of p75NTR in human melanoma cell variants determines their extent of invasion stimulated by nerve growth factor (NGF). Treatment of MeWo melanoma cells or a metastatic spontaneous wheat germ agglutinin-resistant variant subline (70W) of MeWo cells with 2.5S NGF resulted in a dose-dependent enhancement of invasion through a reconstituted basement membrane. This effect was most pronounced with the 70W subline that exhibits brain-metastasizing potential in nude mice but was not found with a poorly metastatic MeWo variant subline (3S5). The expression of p75NTR as determined by Northern blotting and immunoprecipitation analysis of 125I-labeled cell surface proteins correlated with NGF-stimulated invasion. The MeWo melanoma sublines used in this study did not express p140proto-trkA mRNA or any p140proto-trkA variant transcripts including p70trkA as determined by Northern analysis and RT-PCR analysis. Thus, these melanoma cells would not be expected to form functional p75-p140 heterodimers or p140-p140 homodimers capable of transducing an NGF-generated signal to p140proto-trkA cytoplasmic substrates. These cells did express authentic p145trkC transcripts. However, NGF did not catalytically activate p145trkC receptors via increased tyrosine phosphorylation as would be expected if p145trkC participated in the signaling established by NGF. Furthermore, a NGF-stimulated purine-analogue-sensitive kinase activity was found to coimmunoprecipitate with p75NTR. This p75NTR-associated kinase may coordinate initial signaling events evoked by p75NTR ligand interaction. Addition of 2.5S NGF, at concentrations that should saturate cell surface p75NTR, to matrix-adherent cultures of human MeWo and 70W but not 3S5 melanoma cells suppressed the expression of 92-kDa type IV collagenase and stimulated the production of 72-kDa type IV collagenase in its fully active 68-kDa form. In the absence of p140proto-trkA, the matrix-dependent effects of NGF on metalloproteinase expression of brain-metastatic 70W melanoma cells suggest a signaling role for the low-affinity melanoma p75NTR receptor and its associated purine-analogue-sensitive kinase in signaling enhanced matrix penetration of NGF-rich stromal microenvironments such as the brain.

Extracellular annexin II is associated with divalent cation-dependent tumor cell-endothelial cell adhesion of metastatic RAW117 large-cell lymphoma cells

Using fixed microvessel endothelial cell monolayers the molecules involved in the adhesion of liver-preferring murine RAW117 large cell lymphoma cells to murine liver-derived microvessel endothelial cells were identified by affinity isolation. Detergent lysates obtained from poorly (P) or highly (H10) liver-metastatic cells inhibited RAW117-H10 cell adhesion to hepatic sinusoidal endothelial (HSE) cell monolayers. Allowing detergent lysates of cell surface-labeled RAW117 cells to bind to fixed HSE cell monolayers and eluting the bound components indicated that several tumor cell surface molecules (approximately 70, approximately 35, approximately 32, approximately 22, and approximately 14 kDa) might be involved in RAW117 cell-HSE cell adhesion. The approximately 35 kDa component was cation dependent in its binding to target HSE cells. Increasing detergent concentration had no effect on binding of the approximately 35 kDa component to HSE cell monolayers, whereas treatment with 0.5 M NaCl resulted in its selective elution from HSE cells. Incubation of the HSE cell monolayers with detergent lysates from cell surface-labeled RAW117-H10 cells resulted in selective depletion of the approximately 35 kDa component, suggesting that the binding is saturable. This divalent cation-dependent molecule is one of the major tumor cell surface components bound by several types of endothelial cells and murine hepatocytes, whereas there was poor binding of this component to unfixed or fixed human red blood cells. The purified, partially (approximately 40%) sequenced molecule had amino acid sequence identity with murine but not bovine annexin II, indicating that it was not bound from the bovine serum used to grow RAW117 cells. Using antibodies specific for annexin II flow cytometry indicated equivalent amounts of annexin II are expressed on RAW117 cell surfaces in the absence or presence of excess EDTA, whereas annexin I was only found in low amounts on the surfaces of RAW117 cells. Annexin II antibodies inhibited by approximately 40-50% the adhesion of RAW117 tumor cells to live or fixed endothelial cells, and purified tumor cell surface fractions containing the approximately 35 kDa component partially inhibited (approximately 35%) RAW117 cell-HSE cell adhesion. The data indicate that annexin II is expressed on the extracellular surface of RAW117 cells, and cell surface-annexin II mediates a portion of the Ca(2+)-dependent RAW117 cell adhesion to liver microvessel endothelial cells.

Nerve growth factor effects on human and mouse melanoma cell invasion and heparanase production

The role of growth factor networks in regulating the progression of human melanocytes towards tumorigenicity and ultimately the malignant phenotype is poorly understood. In particular, the autocrine and paracrine influences that modulate cellular invasion and extracellular matrix degradative enzymes of melanoma cells remain undefined at the molecular level. We report here that nerve growth factor (NGF) can modify some metastasis-associated cellular properties of human and mouse melanoma cells. Treatment of early-passage human metastatic melanoma cells (MeWo) or their variants (3S5, 70W) with biologically active 2.5S NGF resulted in (a) delayed density-dependent inhibition of melanoma cell growth; (b) increased in vitro invasion through a reconstituted basement membrane; and (c) time- and dose-dependent induction of heparanase, a heparan-sulfate-specific endo-beta-D-glucuronidase associated with human melanoma metastasis. These effects of NGF were most marked in the 70W brain-colonizing cells (70W > MeWo > 3S5). The NGF enhancement of heparanase secretion was not species-specific, since it was also observed in murine B16 melanoma cells; the highest NGF stimulation of heparanase was found in brain-colonizing murine B16-B15b variant (B16-B15b > B16-BL6, B16-F10, B16-F1). NGF also increased the invasive capacity of the human 70W and murine B16-B15b sublines in a chemoinvasion assay performed with filters coated with purified heparan sulfate proteoglycan (HSPG). The enhancement of chemotactic response and heparanase production was detected at NGF concentrations sufficient to fully saturate both low- and high-affinity NGF receptors (NGFR), the neurotrophin receptor (p75) and the trkA gene product, respectively. The results suggest that, in addition to the effects of NGF on cellular development and differentiation within the peripheral and central nervous systems, NGF can exert changes in the invasive properties of neuroectoderm-derived melanoma cells.

A paracrine migration-stimulating factor for metastatic tumor cells secreted by mouse hepatic sinusoidal endothelial cells: identification as complement component C3b

Selective malignant cell invasion at secondary sites mediated by organ-specific (paracrine) motility factors may be of importance in preferential organ colonization of metastatic cells. In this study we isolated and examined a migration-stimulating activity present in mouse hepatic sinusoidal endothelial cell-conditioned medium (HSE-CM). HSE-CM contains migration-stimulating activity for highly liver-metastatic (RAW117-H10) and highly lung- and liver-metastatic (RAW117-L17) mouse large cell lymphoma sublines but not for the poorly metastatic parental line (RAW117-P). A migration-stimulating factor for H10 cells was purified from HSE-CM by hydroxylapatite affinity and DEAE anion exchange chromatography, Sephacryl S-200 gel filtration, and preparative native gel electrophoresis. The activity in each of the purification fractions was measured in a Transwell chamber assay using 3-microns diameter pore filters. Upon sodium dodecyl sulfate polyacrylamide gel electrophoresis, the component migrated as a single component of M(r) > 200,000 (nonreducing conditions) or as two components or M(r) approximately 110,000 and approximately 67,000 (reducing conditions). The factor was bound to Concanavalin A-Sepharose but not to heparin- or gelatin-Sepharose affinity columns, induced mainly H10 chemotactic cell activity and some chemokinetic activity, and preferentially stimulated the chemotaxis of liver-colonizing RAW117 sublines (H10 > L17 > P). NH2-terminal amino acid sequence analysis of each subunit indicated that the HSE-CM-derived migration-stimulating factor was a proteolytic fragment of complement component C3. HSE-derived migration-stimulating factors may be important in determining the ability of RAW117 tumor cells to invade and colonize the liver.

Paracrine and autocrine growth mechanisms in tumor metastasis to specific sites with particular emphasis on brain and lung metastasis

Once metastatic cells successfully seed at distant sites, their clinical detection and danger to the host are dependent on growth to form gross metastases. Metastatic tumor cells proliferate in response to local paracrine growth factors and inhibitors, and their growth also depends on production and responses to autocrine growth factors. A major organ-derived (paracrine) growth factor from lung tissue-conditioned medium has been isolated that differentially stimulates the growth of cells metastatic to brain or lung. Characterization of this mitogen demonstrated that it is a transferrin or a transferrin-like glycoprotein. Furthermore, antibodies to transferrin can remove significant growth activity from lung tissue-conditioned medium. Cells that are metastatic to brain or lung express greater numbers of transferrin receptors on their surfaces than cells that are poorly metastatic or metastatic to liver. Growth responses of metastatic cells and organ preferences of colonization appear to change during progression to more malignant states. At early stages of metastatic progression there is a tendency for many common malignancies to metastasize and grow preferentially at particular sites, suggesting that paracrine growth mechanisms may dominate the growth signals at this stage of progression. In contrast, at later stages of metastatic progression widespread dissemination to various tissues and organs occurs, and autocrine growth mechanisms may dominate the growth responses of metastatic cells. Ultimately, the progression of malignant cells to completely autonomous (acrine) states can occur, and at this stage of metastatic progression cell growth may be completely independent of autocrine and paracrine growth factors or inhibitors.

Role and regulation of expression of 92-kDa type-IV collagenase (MMP-9) in 2 invasive squamous-cell-carcinoma cell lines of the oral cavity

The present study was undertaken to determine the role of the metalloproteinase MMP-9 in the invasive phenotype of squamous-cell carcinoma of the oral cavity and the regulation of its expression. Zymographic analysis of conditioned medium from 2 highly invasive squamous-cell-carcinoma cell lines indicated large amounts of an enzyme which was indistinguishable, in size (92 kDa) from the MMP-9 pro-enzyme. Conversion of the 92-kDa gelatinase into a lower-molecular-weight species (84 kDa), identical in size to the activated gelatinase, was evident when both cell lines, which are avid secretors of urokinase, were cultured in the presence of plasminogen. Penetration of an extracellular-matrix-coated filter was dramatically reduced in the presence of the collagenase inhibitor, tissue inhibitor of metalloproteinase-2, suggesting a critical role for MMP-9 in the invasive process. Immunohistochemical studies demonstrating the presence of MMP-9 in tumor cells of resected squamous-cell cancers suggested that secretion of this collagenase by cells in vitro was reflective of the in vivo setting. Since several phorbol-ester response elements are present in the MMP-9 promoter, we determined the role of protein-kinase-C pathways in the regulation of MMP-9 expression in cultured SCC. Treatment of cells with PMA resulted in a more-than-20-fold increase in the level of protein and mRNA. Conversely, culturing of cells in the presence of the protein-kinase-C inhibitor, calphostin-C, led to a dose-dependent decrease in the amount of MMP-9 mRNA and protein, suggesting that the constitutive expression of this collagenase reflects activation of this signal transduction pathway. In summary, our data suggest that, for a sub-population of squamous-cell carcinomas, secreted MMP-9 is an important determinant of the invasive phenotype, and that the expression of this metalloproteinase is regulated by protein-kinase-C pathways.

Modulating the metastatic potential of murine RAW117 large-cell lymphoma cells by selection for resistance to interferon-gamma

Highly metastatic, in vivo-selected cells of RAW117-H10 large-cell lymphoma have been shown to be more resistant than poorly metastatic parental RAW117-P cells to the cytolytic and cytostatic activities of activated macrophages in co-culture experiments. Activated macrophages are known to produce soluble, cytostatic respiration-inhibiting factors, and such activities can be duplicated by interferon-gamma (IFN-gamma) or by combinations of IFN-gamma and Escherichia coli lipopolysaccharide (LPS). Highly metastatic RAW117-H10 cells are more resistant to the cytostatic effects of IFN-gamma and LPS than poorly metastatic RAW117-P cells, and short-term (up to 72 hr) treatment with IFN-gamma and LPS does not change the metastatic potentials of RAW117 cells. We have studied the effects of sequential selection of RAW117-P cells for increased resistance to IFN-gamma and LPS. After 7 to 13 sequential selections, the resulting variant lines were completely refractory to the growth-inhibitory effects of IFN-gamma and LPS and cross-tolerant to macrophage-conditioned medium. The selected variants also completely lost their experimental metastatic potentials and their tumorigenicities after s.c. or i.m. injection. Cytofluorographic analysis indicated reduced cell-surface expression of H-2Kd antigen and fibronectin receptor on the variant cells but no change in surface mu heavy-chain immunoglobulin. The IFN-gamma-selected lines were less adhesive to liver microvascular endothelial cells than the unselected RAW117 cell lines, but were equally sensitive to NK cytolysis by spleen cells. Our results suggest that exposure to certain cytokines can affect the growth and metastatic potential of RAW117 cells and result in the selection of resistant variants with altered biologic properties.

Differences in transferrin response and numbers of transferrin receptors in rat and human mammary carcinoma lines of different metastatic potentials

We previously found that transferrin (Tf) differentially stimulated the growth of highly metastatic variant lines of murine melanoma and that these highly metastatic cells also had greater numbers of Tf receptors on their cell surfaces. In the present study we found that highly metastatic rat mammary adenocarcinoma cell lines also responded differentially to Tf in proliferation assays, and cell monolayers bound Tf in relation to their metastatic potential (MTPaB10 > MTPaB5 > MTLn3 > MTLn2 > MTC > MTF7 > MTPa). The brain-colonizing lines PaB10 and PaB5 were the most responsive to Tf and had the highest numbers of Tf receptors. Different human breast cancer cell lines also responded differentially to Tf in proliferation assays and bound different amounts of Tf to their cell surface Tf receptors. Transferrin binding, but not growth response, correlated with metastatic and invasive properties of lines selected from the human MCF-7 series (MCF7/LCC2 > MCF7/LCC1 > MCF7). In examining the transferrin binding and growth response of lines from the human MDA series, the Tf binding and growth response was MDA231 > MDA435 > MDA468. The lines MDA435 and MDA231 were metastatic in nude mouse assays, whereas the line MDA468 was not. Scatchard analysis indicated the presence of a single class of receptor for Tf on the rat and human mammary cell lines. The results suggest that neoplastic cells displaying various metastatic properties may express differing numbers of Tf receptors and respond differently to growth factors such as Tf.

Molecular basis of tumor progression: mechanisms of organ-specific tumor metastasis

Tumor cell metastasis is an extremely complex process governed by many different classes of molecules with each class having a separate function. Metastasis is the result of multiple sequential steps and is a highly organized, nonrandom, and organ-selective process. Recent advances in tumor and molecular biology have permitted the identification of a variety of heterogeneous molecules governing invasion (degradative enzymes, motility factors), adhesion (integrins, selectins, cadherins, immunoglobulin-like superfamily, annexins), and growth (paracrine and autocrine growth factors) of tumor cells. This diverse group of biological molecules is collectively responsible for determining whether tumor cells can progress from a single malignant cell to a lethal, multiorgan, metastatic disease.

Regulation of urokinase-type plasminogen activator expression in squamous-cell carcinoma of the oral cavity

We undertook a study to determine the role and regulation of expression of urokinase-type plasminogen activator in squamous-cell carcinoma of the oral cavity. The contribution of urokinase to the invasive process was clearly demonstrated in experiments in which in vitro invasion by a cultured squamous-cell carcinoma cell line was substantially reduced by a monoclonal antibody directed at the catalytic site of urokinase. The conditioned medium from 2 invasive cell lines contained high levels of urokinase. Examination of resected tumors for urokinase revealed (a) localization of the antigen to the tumor cells and (b) higher levels of the plasminogen activator in tumor tissue than in adjacent non-malignant tissue. These results suggested that elevated expression of urokinase is a common feature of this malignancy. The mRNA half-lives of cell lines expressing high and low levels of urokinase were similar, indicating that elevated levels of mRNA for the plasminogen activator were not a consequence of a more stable transcript. No evidence of u-PA gene amplification was obtained by Southern blotting of DNA derived from the cell lines expressing high urokinase levels. Transfection of squamous-cell carcinoma cells, which express high levels of urokinase, with a construct bearing the chloramphenicol acetyl transferase gene driven by the full-length (2345 bp) urokinase promoter indicated activation of the urokinase promoter in trans. In conclusion, our results suggest that transcriptional activation of the urokinase gene, in squamous-cell carcinomas of the oral cavity, leads to elevated levels of urokinase mRNA/protein which, in turn, can promote the invasive phenotype.

Growth mechanisms and cancer progression

In the final stages of malignant progression, tumor cell growth mechanisms become self-contained, making the cells impervious to attempts at growth control by physicians or the host. Such tactics might work better in the early stages of metastasis, when these cells are still responsive to outside influences.

Cancer progression and growth: relationship of paracrine and autocrine growth mechanisms to organ preference of metastasis

The progression of cancer cells to highly malignant phenotypes that ultimately invade and metastasize to near and distant sites requires that metastatic cells respond to mitogenic signals in new microenvironments. The successful growth of metastases is due to their ability to respond to local paracrine growth factors and inhibitors and to produce and respond to autocrine growth factors. Solid tumors of the same histologic class, however, may respond differently to combinations of paracrine and autocrine growth signals at metastatic sites. At early stages of tumor dissemination there is a tendency for certain cancers to metastasize to and grow preferentially at particular sites, suggesting that paracrine growth mechanisms may dominate the growth signals processed by metastatic cells. In contrast, at later stages of progression where widespread dissemination of cancer occurs, autocrine growth mechanisms may dominate the positive growth signals processed by metastatic cells and the cells may fail to respond to negative growth signals. Ultimately progression of cancer cells to completely autonomous (acrine) growth states can occur, and metastatic cell proliferation may be completely independent of growth factors or inhibitors. This suggests that pharmacologic intervention using analogs of specific growth inhibitors or antagonists of growth factors, such as genetically altered growth factors, monoclonal antibodies, or other agents, to block growth signaling mechanisms may be useful only at stages of cancer progression before wide-spread metastasis of acrine malignant cells occurs.

Candidate metastasis-associated genes of the rat 13762NF mammary adenocarcinoma

Differential hybridization was used to isolate genes potentially involved in the process of metastasis. Ten complementary DNAs (cDNAs) that were differentially expressed between a highly metastatic (MTLn3) and a nonmetastatic (MTC.4) line of the rat 13762NF mammary adenocarcinoma were isolated and sequenced. Examination of the EMBL/GenBank database revealed that one of the genes had a high degree of homology (98.8%) to annexin I (also known as calpactin II). Quantitative analysis of Northern blot hybridizations showed that the annexin I-like sequence was expressed 4- to 7-fold higher in MTLn3 than in MTC.4 cells. Steady state mRNA levels were also low in MTLn2, a cell line of low metastatic potential closely related to MTLn3, but were not related to metastatic potential in colon adenocarcinoma or melanoma cells. Two of the cDNAs (designated 8.11 and 10.14) were found to be novel. The expression of 10.14 mRNA (3.2 kb) was 4-fold higher in MTLn3 than in MTC.4 cells. Sequencing of the 10.14 cDNA (2.2 kb) revealed a putative open reading frame of 583 amino acids that was also novel. Expression of 8.11 mRNA (> 7 kb) inversely correlated with metastatic potential. Another differentially transcribed gene was highly homologous to ERK2 (extracellular signal related kinase 2), a mitogen-activated protein kinase (MAPK). Northern analysis of ERK2 expression revealed 3-fold higher amounts of a 1.3 kb mRNA in MTLn3 than in MTC.4 cells. Higher levels of ERK2 mRNA were generally seen in the more metastatic human colon but not in melanoma cell lines. We also corroborated the work of Taniguchi (Nucl Acids Res 19:6949, 1991) by independently identifying EF-1 alpha as a putative metastasis-associated gene.

Computerized analysis of tumor cells flowing in a parallel plate chamber to determine their adhesion stabilization lag time

The importance of cell adhesion in a variety of physiological phenomena requires development of an understanding of the factors and molecular mechanisms underlying these behaviors. Cell adhesion is a multistep process involving primary receptor-ligand interactions followed by secondary events that may lead to the formation of focal contacts. Due to the lack of well-defined assays to study adhesion stabilization, little is known about this process, except that it may involve signaling events, receptor recruitment, and, as we have demonstrated, covalent peptide cross-linking by cell membrane-associated transglutaminase [Menter et al.: Cell Biophys. 18:123-143, 1992). To study the stabilization process we have developed a dynamic assay employing a parallel plate flow chamber coupled with video microscopy and digital image processing. Our studies utilize wheat germ agglutinin-selected human metastatic melanoma cell variants that exhibit differences in their experimental metastatic potential and expression of transglutaminase. Using this assay, quantifying cell-substrate stabilization was found to be quick, reliable, reproducible, and useful in evaluating agents that block this process.

Expression of annexins on the surfaces of non-metastatic and metastatic human and rodent tumor cells

Annexins are a large group of calcium-dependent cytoskeletal- and membrane-associated proteins whose properties include cytoskeleton and phospholipid binding and mitotic signal transduction. Although annexin-like molecules have been reported on the external plasma membranes of certain cells, in general they are considered to be cytoplasmic proteins. We report here the heterogenous expression of certain annexins (I-VI) on the external cell surfaces of non-metastatic and metastatic murine (RAW117 large-cell lymphoma), rat (13762NF mammary adenocarcinoma) and some human (KM12 and HT29 colorectal carcinoma) cell lines but not on some other cell lines such as human (A375 and MeWo) and mouse (B16) melanoma. The implication of annexin cell surface expression in the metastatic process is discussed with respect to tumor cell adhesion.

Mechanisms of c-erbB2/neu oncogene-induced metastasis and repression of metastatic properties by adenovirus 5 E1A gene products

c-erbB2/neu is a transforming oncogene that encodes a 185-kDa transmembrane glycoprotein. In many but not all studies, amplification and/or overexpression of the human c-erbB2/neu oncogene has been correlated with poor prognosis and the number of lymph node metastases in node-positive breast cancer patients. We have shown that expression of the activated rat c-erbB2/neu oncogene in mouse embryo fibroblast 3T3 cells is sufficient to induce experimental metastases in nude mice. Important steps in the metastatic event are tumor cell adhesion to endothelial cells and invasion of basement membranes. Therefore, we further examined the ability of c-erbB2/neu oncogene-transformed 3T3 cells to adhere to microvessel endothelial cells and secrete basement membrane-degradative enzymes. The c-erbB2/neu oncogene-transformed 3T3 cells were shown to be more adherent and have higher gelatinase activities. Since we had previously shown that the adenovirus 5 E1A gene product can suppress c-erbB2/neu-induced transformation of 3T3 cells, we examined the possibility that E1A can abrogate the metastatic properties of c-erbB2/neu-transformed 3T3 cells. We found that introduction of the E1A gene into c-erbB2/neu-transformed 3T3 cells reduced the formation of experimental metastatic tumors and inhibited metastasis-associated properties, such as adhesion to microvessel endothelial cells, migration through a layer of reconstituted basement membrane (Matrigel) and secretion of basement membrane-degradative enzymes. The results indicate that the mechanism by which the c-erbB2/neu gene induces higher metastatic potential is to promote adhesion and invasion steps of the metastatic cascade. The E1A gene, which functions by inhibiting these steps, is thus a suppressor gene for c-erbB2/neu-induced experimental metastasis.

Nucleoproteins derived from subnuclear RNA polymerase complexes of metastatic large-cell lymphoma cells possess transcription activities and regulatory properties in vitro

Intact nuclei derived from poorly or highly liver-metastatic murine large-cell lymphoma cell line RAW117 were digested to discrete subchromatin deoxyribonucleoprotein/ribonucleoprotein (DNP/RNP) complexes with Msp-I. The DNP/RNP complexes were composed of DNP/RNPs which were derived from the DNP/RNP complexes by incubation in the presence or absence of DNase-I and subsequent isolation by two-dimensional [isoelectric focusing/sodium dodecylsulfate (SDS)] polyacrylamide gel electrophoresis (PAGE), electroelution from the gel, and removal of SDS. Approximately 450 DNP/RNPs in the two-dimensional gels corresponding to discrete spots or in some cases streaks were analyzed for the presence of v-abl, p53, c-neu, c-H-ras, beta-casein, 18s rDNA, and mu-chain immunoglobulin genes using a hybridization technique. Ten DNP/RNP complexes contained tightly associated p53 DNA, whereas six contained c- or v-abl, four contained mu-chain gene, two contained c-H-ras, one contained dot-blot beta-casein, two contained 18s rDNA, and c-neu was found in one of the DNP/RNPs. The DNP/RNPs were also analyzed for in vitro RNA polymerase and primase activities. To assess the potential transcription abilities of the isolated DNP/RNPs, individual DNP/RNPs or DNP/RNP mixtures (reconstituted after SDS-PAGE separation) were examined for RNA polymerase initiation and synthesis. When RNA products were formed, these were purified by extracellulose chromatography and used as back-hybridization probes for the genes of interest. The RNA products were also analyzed by RNA gel electrophoresis. RNA formation was inhibitable by actinomycin D, and the RNAs formed ranged in size from approximately 80 kbp to approximately 1 kbp. By mixing various DNP/RNP complexes together, different patterns of RNA synthesis were found. For example, one DNP/RNP of M(r) approximately 140,000, isoelectric point (pl) approximately 5.8 synthesized a high molecular weight RNA in vitro that hybridized with beta-casein cDNA, but beta-casein is not expressed in RAW117 cells, suggesting that the silencing of the beta-casein gene was negated by isolation of the DNP/RNP. Mixing this DNP/RNP with two other specific DNP/RNPs again inhibited the synthesis of beta-casein RNA, suggesting that interactions between DNP/RNP complexes can result in differential RNA expression or regulation of RNA polymerases in vitro.