Tumor cell autocrine motility factor

Invasion of Rous sarcoma virus-transformed retinal cells: role of cell motility

Transformation of retinal neuro-epithelial cells by Rous sarcoma virus (RSV) leads to many alterations in cell phenotype, including changes in cell movement, cell-cell adhesion and protease secretion. To define and quantitate the alterations in cell movement, we analyzed video recordings of cultured cells using the computer-assisted Dynamic Morphology System (DMS). Control neuro-epithelial cells showed very low levels of translocation and membrane activity. After transformation, neuro-epithelial cells exhibited increased membrane activity, although directed cell translocation remained low. Developing retinas also contain a small proportion of Müller glial cells, which were purified by repeated passaging of control cultures. In contrast to neuro-epithelial cells, both control and RSV-transformed glial cells showed high levels of translocation and membrane activity. To analyze how different kinds of cell movement affect invasive behavior, we compared the ability of control and RSV-transformed cells to invade the chorio-allantoic membrane of developing chicken embryos. Control neuro-epithelial cells were not invasive. RSV-transformed neuro-epithelial cells, which showed low levels of translocation as revealed by DMS, were invasive. Similarly, RSV-transformed glial cells were invasive while control glial cells, which translocated, were not invasive. These results suggest that high levels of cell translocation are not necessary for invasion. In addition, the results suggest that elevated membrane activity in neuro-epithelial cells may be important for their invasion.

Histological and urinary reactivity of monoclonal antibody 1BE12 in bladder carcinoma. Purification of the antigen from urine

We have previously reported the production of monoclonal antibody (MAb) 1BE12, which recognizes a glycoprotein in breast-cancer cells. In the present work, 1BE12 reactivity was tested by immunohistochemistry in bladder carcinoma (92 cases) and in non-tumoral bladder samples (15 cases). In 71% of bladder tumors, more than 30% of cells were intensely stained by 1BE12. The percentage of reactive cells was higher in cancers invading the muscle than in more superficial tumors (p = 0.039). In non-tumoral bladder, immuno-staining, when present, was usually confined to the superficial layers with a low number of cells stained (less than 30%) in 13/15 cases. Slot blots, performed on urine samples from 43 bladder-cancer patients and 21 healthy controls, were quantified by densitometry scanning. We found higher optical density (OD) values in urine from muscle-invasive-cancer patients than in urine from more superficial tumors and healthy controls, with a significantly different distribution (p = 0.005). The urinary antigen was detected by immunoblotting with 1BE12 as high-molecular-weight species (greater than 150 kDa). The reactive glycoprotein could thus be purified by immunoaffinity and FPLC filtration from the perchloric-acid-soluble fraction of urine from patients with invasive bladder carcinoma. The availability of purified antigen will allow us to quantitate our assay, in order to evaluate its potential use as a prognostic indicator in bladder-cancer patients.

Purification, characterization and mechanism of action of scatter factor from human placenta

Scatter factor (SF) causes contiguous sheets of epithelium to spread and cells to separate from each other. SF also increases the velocity, area, and reduces the circularity of individual cells. These changes are mediated in part by alterations in protein synthesis, protein phosphorylation, cytoskeletal reorganization, and cell surface components. SF has been purified from the conditioned medium of ras transformed 3T3 cells and human placenta. Sequence information suggests that SF from 3T3 cells is closely related to hepatocyte growth factor. SF is a glycoprotein, but glycosylation is not necessary for its activity. Glycosylation of target cell proteins, however, is required for SF action.

Cell motility, a principal requirement for metastasis

In studying the role of motility in the metastasis of tumor cells, we have described an autocrine motility factor. This agent, which stimulates random motility, probably contributes to the initial dissociation of the cells from the primary tumor mass. Extracellular matrix components, via several different mechanisms, may facilitate the crossing of biological barriers by the cells prior to the entry into the circulation. In locating at new sites, the tumor cells may be induced to exit from the circulation in response to attractants such as IGFs that could emanate from the target organ. These same growth factors could then stimulate cellular proliferation for another metastatic cycle. It is quite probable that detection of AMF may provide a new tool in cancer diagnosis. The complete characterization of AMF may also yield valuable therapeutic approaches: design of low molecular size antagonists of the attractants and antibodies that might be effective therapeutically as well as diagnostically. It seems clear, in any event, that immobilizing the tumor cell may be a crucial step in inhibiting metastasis.

Molecular analysis of amoeboid chemotaxis: parallel observations in amoeboid phagocytes and metastatic tumor cells

Metastasis is a multistep process in which amoeboid chemotaxis plays a key role in the movement of tumor cells into and out of vessels. On a molecular level, much of what is known about amoeboid chemotaxis has been learned through work with Dictyostelium discoideum, a lower eukaryotic amoeboid phagocyte. One of the first and most crucial events to occur in the actin cytoskeleton following chemotactic stimulation is activation of actin nucleation. This is followed by incorporation of specific actin cross-linking proteins into the cytoskeleton, proteins which are implicated in the extension of pseudopods and filopods. Together, these events have been termed the Cortical Expansion Model for amoeboid chemotaxis. Detailed biochemical analysis has implicated a new actin-capping protein and has shown that one of the cross-linking proteins is Elongation Factor 1a, suggesting a link between chemotaxis and growth control. Preliminary data from parallel studies on neoplastic cells are presented.

Heterogeneity amongst fibroblasts in the production of migration stimulating factor (MSF): implications for cancer pathogenesis

Fetal skin fibroblasts migrate into 3D collagen gels to a significantly greater extent than do adult cells. This enhanced motility of fetal fibroblasts appears to result from the production of a "migration stimulating factor" (MSF) which is not made by their normal adult counterparts. Adult skin fibroblasts retain responsiveness to MSF and cells exposed to this factor achieve the elevated levels of migration characteristic of fetal cells. MSF has been purified to homogeneity, has an apparent molecular mass of 70 kD and has been further characterized in terms of a number of biochemical parameters. Studies concerned with the mechanism of action of MSF indicate that it stimulates the production of a high molecular weight class of hyaluronic acid (HA). Concurrent exposure of cells to Streptomyces hyaluronidase blocks the stimulation of adult fibroblast migration by MSF. In a related series of experiments, we have shown that TGF-beta inhibits the effects of MSF on both cell migration and HA production. Taken together, these data suggest that the stimulation of fibroblast migration by MSF is dependent upon (and may directly result from) a primary induction of HA synthesis. We have previously reported that skin fibroblasts obtained from patients with sporadic and familial breast cancer, as well as the unaffected first-degree relatives of familial breast cancer patients, commonly display a fetal-like migratory phenotype. Subsequent work has indicated that (a) these fetal-like cells also produce MSF, and (b) detectable levels of MSF are present in the serum of sporadic breast cancer patients both prior to and following surgical resection of the primary tumor mass. On the basis of these and related observations, we have put forward an hypothesis suggesting that the disruption in normal epithelial-mesenchymal interactions caused by the persistent production of MSF by fibroblasts in the adult may contribute directly to the pathogenesis of an epithelial cancer. The demonstration of aberrant fibroblasts in sporadic cancer patients (both in our own and independent studies) is not consistent with the "germ-line genetic lesion" model commonly invoked to account for the presence of such cells in patients with hereditary cancer syndromes.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of interferon-beta on the translocation rate and stationary time in human fibroblasts in culture

The rate of translocation and the percent of the time that cells are stationary have been measured by computer-assisted time-lapse cinemicrography in over 1,000 freshly planted human foreskin fibroblasts (FS-4 cell strain) for periods of up to a week and the effects of interferon-beta (IFN-beta) on these parameters have been determined. Cells were planted at 2.5 X 10(3) cells/cm2 in Eagle's minimal essential medium (MEM) with 10% fetal bovine serum (FBS). Frames were taken every 2 or 4 minutes and data were collected on both cell location and cell division as a function of time. After planting FS-4 cells require approximately 48 hr to reach maximum motility both with respect to the translocation rate when moving and percent time cells are moving. Recombinant human INF-beta (800 mu/ml) caused a marked increase in the fraction of time cells were stationary and a decrease of lesser magnitude in the translocation rate, as quantitated during the period during which the stationary fraction for control cells was at a minimum. IFN-beta also decreased the rate of cell proliferation, without any evidence of degeneration or death of cells. Our results contribute new evidence that the fraction of time cells spend moving directionally is an important determinant of their locomotory behavior and that this determinant is responsive to modulation by cytokines.

The role of E-cadherin and scatter factor in tumor invasion and cell motility

The acquisition of invasive properties by transformed epithelial cells constitutes an essential step in the progression of carcinomas. We have defined 2 types of interferences leading to enhanced motility and invasiveness of epithelial cells: (i) disturbances of intercellular adhesion, and (ii) treatment with "scatter factor", a secretory protein of mesenchymal cells. Invasive properties (invasion of collagen gels or embryonal heart tissue) are acquired by epithelial cells in vitro when intercellular adhesion is inhibited by antibodies that are specific for the cell-cell adhesion molecule E-cadherin. Furthermore, we found that differentiated human carcinoma cell lines are noninvasive and express E-cadherin, whereas dedifferentiated carcinoma lines are invasive and have lost E-cadherin expression. Invasiveness of these latter cells could be prevented by transfection with E-cadherin cDNA and was again induced by treatment of the transfected cells with anti-E-cadherin antibodies. A correlation between the degree of tumor differentiation and the amount of E-cadherin expression was also visualized on frozen sections of ovarian carcinomas, lobular breast carcinomas, and squamous carcinomas of head and neck. Thus, loss of E-cadherin appears to be a critical step in the establishment of an invasive, i.e. fully malignant phenotype. Scatter factor, which is also capable of dissociating epithelial cell colonies in vitro, was isolated from conditional medium of human fibroblasts; it is a 92,000 mol.wt glycoprotein, which is proteolytically cleaved into 62,000 and 34/32,000 mol.wt subunits. The purified glycoprotein induces invasion of MDCK cells into collagen matrices, and induces or enhances the invasive properties of various human carcinoma cell lines. Sequencing of tryptic peptides of scatter factor revealed strong similarity with hepatocyte growth factor. Furthermore, both factors exhibit identical activities, i.e. scatter factor stimulates DNA synthesis of primary hepatocytes and hepatocyte growth factor dissociates and increases the motility of various epithelial cells. Thus scatter factor and hepatocyte growth factor represent identical or closely similar proteins.

Tumor cell autocrine motility factor receptor

The ability to locomote and migrate is fundamental to the acquisition of invasive and metastatic properties by tumor cells. Autocrine motility factor (AMF) is a cytokine produced by various tumor cells which stimulates their in vitro motility and in vivo lung-colonizing ability. AMF stimulates cell motility via a receptor-mediated signalling pathway. Signal transduction following binding of AMF to its receptor, a cell surface glycoprotein of 78 kD (gp78), is mediated by a pertussis toxin sensitive G protein, inositol phosphate production and the phosphorylation of gp78. AMF induces gp78 internalization to intracellular tubulovesicles and transport to the leading edge stimulating pseudopodial protrusion and cell motility.

Chemotactic activity present in liver extracellular matrix

A selective pattern of metastasis, not accountable by a simple mechanical trapping mechanism, is exhibited by many primary tumors and appears to be controlled by properties of both the tumor cell and the host organ. This organotropism may be regulated, in part, by the migration of an invading tumor cell toward chemotactic factors present in the extracellular matrix which may be released as a result of proteolytic digestion. To test this hypothesis we have examined 4 M guanidine extracts of liver extracellular matrix, prepared by high salt extraction, for organ-specific chemotactic activity. The murine cell lines B16-L4b and M5076, which preferentially metastasize to the liver in an experimental metastasis model, demonstrated preferential motility toward the liver matrix extract while the lung-colonizing lines B16, B16-F10 and B16-BL6 did not. The liver specific chemotactic activity eluted as four fractions of Mr much less than 250,000, Mr approximately 245,000, Mr approximately 120,000 and Mr approximately 30,000 by gel filtration chromatography.

Expression of transfected transforming growth factor alpha induces a motile fibroblast-like phenotype with extracellular matrix-degrading potential in a rat bladder carcinoma cell line

Acquisition of cell motility is often correlated with the malignant progression of a transformed cell. To investigate some of the mechanisms involved in the development of a migratory state, we transfected the NBTII rat carcinoma cell line, which forms stationary epithelial clusters in culture, with the gene encoding human transforming growth factor alpha (TGF alpha). Expression of TGF alpha in NBTII cells resulted in cells of motile and vimentin-positive phenotype with internalized desmosomal components, analogous to the treatment of cells with exogenous TGF alpha. The clones expressed a 5.2-kb TGF alpha message and synthesized an 18-kDa form of TGF alpha. Supernatants of TGF alpha-producing clones induced the internalization of desmosomal components, the production of vimentin, and increased motility in untransfected epithelial NBTII cells, indicating that the factor produced by the clones was in a biologically active form. TGF alpha-producing clones secreted significant levels of a 95-kDa gelatinolytic metal-loproteinase, virtually absent in untransfected cell supernatants. In contrast, levels of inhibitors of metalloproteinases and of a plasminogen activator were similar in untransfected and TGF alpha-transfected NBTII cells. These results suggest that expression of TGF alpha in an epithelial tumor cell results in the development of a motile, fibroblast-like phenotype with matrix-degrading potential, which could result in a more aggressive tumor in vivo.

Motility factor produced by malignant glioma cells: role in tumor invasion

To better understand the cellular mechanism of tumor invasion, the production of a cell motility-stimulating factor by malignant glioma cells was studied in vitro. Serum-free conditioned media from cultures of rat C6 and human T98G cell lines contained a factor that stimulated the locomotion of the producer cells. This factor was termed the "glioma-derived motility factor." The glioma-derived motility factor is a heat-labile protein with a molecular weight greater than 10 kD and has relative stability to acid. The factor showed not only chemotactic activity but also chemokinetic (stimulated random locomotion) activity in the two types of glioma cells studied. Although glioma-derived motility factors in conditioned media obtained from two different cell origins are likely to be the same, chemokinetic migration of T98G cells to their conditioned medium was much stronger than that of C6 cells to theirs. Coincubation of cells with cytochalasin B, which disrupts the assembly of cellular actin microfilaments, almost completely inhibited the cell migration stimulated by glioma-derived motility factor. Cytochalasin B also induced marked alterations in cell morphology, including cell retraction and arborization, while the drug did not affect cell attachment to culture dishes. These results indicate that glioma cells produce a motility factor which may play a role particularly when tumor cells are detached and migrate away from the original tumor mass, thus promoting tumor invasion. Also, glioma cell migration stimulated by the motility factor requires the normal organization of cytoskeletons such as actin microfilaments.

Scatter factor: molecular characteristics and effect on the invasiveness of epithelial cells

The generation of invasiveness in transformed cells represents an essential step of tumor progression. We have previously shown that MDCK epithelial cells, which are deprived of intracellular adhesion by the addition of anti-Arc-1/uvomorulin antibodies, become invasive for collagen gels and embryonal heart tissue (Behrens, J., M. M. Mareel, F. M. Van Roy, and W. Birchmeier. 1989. J. Cell Biol. 108: 2435-2447.). Here we examined whether invasiveness is also induced by scatter factor, which is known to dissociate epithelial cells (Stoker, M., E. Gherardi, M. Perryman, and J. Gray. 1987. Nature (Lond.). 327:239-242.). Scatter factor was purified to homogeneity from conditioned medium of human fibroblasts by heparin-Sepharose chromatography, followed by cation exchange chromatography, gel filtration, or preparative SDS gel electrophoresis. We found that scatter factor represents a 92,000 mol wt glycoprotein which, apparently, is converted by limited proteolysis into disulfide-linked 62,000 and 34/32,000 mol wt subunits. Reversed phase HPLC and sequence analysis of tryptic peptides confirmed the suggested molecular structure, and revealed further that scatter factor exhibits sequence similarities to hepatocyte growth factor and to plasminogen. Purified scatter factor in fact induces the invasiveness into collagen matrices of MDCK epithelial cells, and induces or promotes the invasiveness of a number of human carcinoma cell lines. Apparently, the effect on the human cells depends on their respective degree of differentiation, i.e., cell lines with a less pronounced epithelial phenotype were more susceptible to the factor. Scatter factor does not seem to influence synthesis, steady-state level, and phosphorylation of the cell adhesion molecule Arc-1/uvomorulin. Thus, scatter factor represents a clearly defined molecular species which induces, in vitro, the progression of epithelial cells to a more motile, i.e., invasive phenotype.

Tumor progression- and metastasis-associated proteins identified using a model of locally recurrent rat mammary adenocarcinomas

A recently established model for local breast cancer recurrence using the 13762NF rat mammary adenocarcinoma was used to evaluate biologic and biochemical properties related to clinical outcome for this class of tumors. Sublines isolated from local tumor regrowths following surgical resection differed from each other and from the 'parental' cell lines for multiple phenotypes, including metastatic propensity. Local recurrence- and primary tumor-derived sublines were examined by two-dimensional polyacrylamide gel electrophoresis (2D-PAGE), lectin binding to electrophoretically separated proteins, and lactoperoxidase-catalyzed cell surface iodination; and differential protein patterns were compared to tumor progression and metastatic potential. 2D-PAGE revealed several quantitatively different spots which correlated with lung colonization potential. In particular, quantities of an apparently unique, non-cell-surface protein, P50.9 (Mr approximately 50,900, pI approximately 7.3) correlated inversely with metastatic propensity, suggesting that it may be associated with, among other possibilities, the negative regulation of the metastatic phenotype. P50.9 was unrelated to four similarly sized metastasis-associated proteins--tumor autocrine motility factor; the rat analog of tumor suppressor, p53; rat cytokeratin 14 or procathepsin D--as determined by amino acid analysis. A major wheat germ agglutinin binding sialoglycoprotein, gp93 (Mr approximately 93,000), was present in smaller amounts as cells were passaged in vivo and re-established as in vitro cultures [MTF7 greater than 'primary' tumor-derived lines (sc1, sc3) much greater than local recurrence-derived lines (LR1, LR1a, LR3, LR4, LR5, LR6)]. Besides cell surface glycoprotein losses, two of six local recurrence-derived sublines expressed a wheat germ agglutinin-binding sialoglycoprotein, gp110 (Mr approximately 110,000), previously undetected on any of the other cell lines including the parental populations. gp110 was found in LR3 and LR6 which were relatively highly metastatic; however, correlation with metastatic potential failed because gp110 was not present on the metastatic parental cell line, MTF7. These results demonstrate specific quantitative and qualitative protein differences associated with the selection of locally recurrent mammary tumors.

Chemotaxis by a CNS macrophage, the microglia

Microglia demonstrate many characteristics similar to those seen in monocytes and tissue-specific macrophages, including phagocytosis, production of oxygen radicals, and growth factors and expression of MHC antigens. We have examined the ability of microglia, cultured from the cerebral cortices of neonatal rats, to demonstrate another important functional characteristic of monocytic-derived cells, that is, chemotaxis. Our results show that cultured rat microglia demonstrate chemotaxis to complement dependent chemoattractants such as recombinant C5a, zymosan activated serum, and to rat serum as well as to transforming growth factor-beta, a chemoattractant produced by platelets. Microglia fail to migrate to bacterial dependent chemoattractants such as the N-formyl peptides. The failure to respond is not dependent on maturational state of the microglia. Treatment with DMSO or casein, agents known to induce morphological and functional changes in cultured microglia reminescent of a "resting" and an "activated" macrophage, respectively, do not alter the response to fMet-Leu-Phe. In addition, the chemotactic response to serum in DMSO or casein-treated cells is the same as the response seen in untreated day 10 cultured microglia or untreated age-matched controls. The ability of microglia to migrate in response to inflammatory mediators suggests that these cells can move to sites of injury, thereby enabling them to participate in an inflammatory response.

Cell-matrix interactions during tumor invasion

This manuscript reviews the molecular aspects of tumor cell invasion of extracellular matrix. The changes in cell:substrate and cell:cell receptors that characterize motile cells are discussed for their importance not only in mediating invasive cell behavior, but also as diagnostic markers for invasive potential. Autocrine motility and scatter factors probably have key roles in initiating migratory behavior, while specific and non-specific extracellular matrix alterations can facilitate cell locomotion. The manuscript reviews reported changes, such as induction of cell motility, matrix degrading enzymes, and invasive/metastatic potential, which can follow transfection with ras oncogenes, and details the key roles of metalloproteinases, heparanase, and plasminogen activator in matrix degradation. Enzymatic inhibitors of initial steps in extracellular matrix degradation, such as rTIMP, and synthetic blockers of adhesive steps in tumor cell invasion represent types of reagent with potential as anti-metastatic agents. Their potential usefulness may be increased if they can be incorporated into a novel, long-term, non-traditional delivery system.

Heterogeneity of the motility responses in malignant tumor cells: a biological basis for the diversity and homing of metastatic cells

Tumor metastasis requires highly motile cells that can respond to appropriate stimuli. A2058 human melanoma cells were shown previously to secrete a highly potent autocrine motility factor (AMF) that stimulates chemokinetic movement. We have shown that the insulin polypeptides (IPs; insulin-like growth factors I and II [IGF-I, -II] and insulin) stimulated A2058 cell chemotaxis and chemokinesis. We now report that the IPs and AMF stimulate locomotion in other human malignant cell lines. Insulin (100 nM) induced motility of up to 50% of the magnitude of the AMF response in human carcinoma lines MDA-231 (breast), T24 (bladder), and OVCAR3 (ovarian). The tumorigenic and metastatic 5R Haras-transfected rat embryo fibroblast cell line responded to insulin with both chemotaxis and chemokinesis and was 100% of that seen for AMF. The ED50 for IGF-I in the carcinoma cell lines was in the order of I nM, but the magnitude of the responses at this concentration was 40% of the AMF-stimulated response, with the exception of the A2058 cells, which were maximally stimulated at I nM. IGF-II induced maximal motility of 75 to 130% of the AMF-stimulated response in the carcinoma lines with ED50 of less than or equal to 10 nM. IGF-II-stimulated motility in the carcinoma lines was predominantly chemotactic by modified checkerboard analysis. Cell pretreatment with pertussis toxin inhibited 90-100% of AMF-induced motility, whereas migration to the IPs was not pertussis toxinsusceptible. In growth studies, IGF-I induced mitogenesis up to 140% of basal media control growth. In general, maximal growth stimulation was seen at 100 nM IGF-I, and optimal migration was seen at 10 nM IGF-I. The IGFs are secreted by normal stroma in a number of organs that are common sites for primary and metastatic disease. Therefore, we suggest that IPs may be important homing and mitogenic signals for tumor cells in the process of invasion and metastasis and that the differential motility stimulation and respective mechanisms of action by these physiologically important agents may underlie the diversity of the metastatic process.

The invasive phenotypes

The expression of the invasive (I+ or I-) phenotypes determines cancer metastasis (M+ or M- phenotype). The invasive (I+ or I-) phenotypes can be divided according to time and site of expression into subphenotypes, which can be assessed separately. At various sites along the metastatic pathway the expression of the I phenotypes can be accompanied by the presence of uncontrolled growth (G+ phenotype) or its absence (G- phenotype). Various combinations of the I and G phenotypes determine the behaviour of metazoan or parasitic cells under normal, pathological non-neoplastic and neoplastic conditions. Although the G+I+M+ combination correlates with full malignancy, the sequence of events leading to the acquisition of these phenotypes during tumor development is not clear. Conditional invasion in experimental systems indicates that a tumor may be invasive and metastatic when part of its population temporarily expresses the I+ phenotype. These experiments further stress the importance of the tumor-host ecosystem for the regulation of the I phenotypes. As distinct from some parasites, the invasive morphotype of vertebrate cells cannot be simply identified. Nevertheless, within the tumor-host ecosystem morphological correlates of the activities of invasive cells may be recognized. They reflect one or more of the I+ functions, namely: motility; loss of homotypic cell-cell adhesion; establishment of alternative cell-substrate and heterotypic cell-cell adhesion; breakdown of extracellular matrices. These functions are not exclusive for I+ tumor cells, and neither are the molecular markers investigated so far. Oncogene activation leads mainly to G+ expression, and in this way serves as a signal amplifier for the I and M phenotypes. Attractive candidate molecular markers of I phenotypes are: regulators of hydrolase activities; cell-cell adhesion molecules; cell surface receptors. From data presently available, we hypothesize that invasion depends upon the balance between and I+ and an I- pathway, with both pathways being sensitive to stimulation inhibition.

Cellular interactions in metastasis

The metastatic cascade is a sequence of events that must be completed for metastases to be established. The realization that tumors are heterogeneous, consisting of many different subpopulations differing in many characteristics, and the belief that there are selective events in the metastatic process have led several laboratories to isolate and characterize variants with both high and low metastatic potential. Typically, the highly metastatic variants have been able to form distant metastases when implanted into the subcutis. Such lines have been popular for studies of metastatic mechanisms and anti-metastatic therapy, but they may be atypical examples, and thus not the best experimental models. Recent studies indicate that normal tissue influences metastasis such that many tumors metastasize only if placed in the orthotopic site. Furthermore, some cells that do not metastasize individually are able to do so in conjunction with other variant subpopulations. Thus, mixtures of tumor cells in the tissue of origin can express a more malignant character. We review possible mechanisms for such influential interactions, as well as the role of cellular interactions in generating heterogeneity and stabilizing tumor characteristics.

Influence of the angiotensin system on endothelial and smooth muscle cell migration

The blood vessel wall's response to injury is an important determinant of luminal size and vessel function. The physiologic migration of endothelial cells from the edges of a wound and the pathophysiologic migration of medial smooth muscle cells into the intima are two important components of the vessel wall's response to injury. The influence of the angiotensin system on endothelial and smooth muscle cell migration have not been examined. In the present study, the influence of angiotensin system components on bovine aortic endothelial cell (BAEC) and bovine aortic smooth muscle cell (BASMC) migration after release of cultured cell monolayers from contact inhibition was determined. The angiotensin-converting enzyme (ACE) inhibitor lisinopril increased BAEC migration 41% +/- 3% (P less than 0.001), as did the specific angiotensin II antagonist sar1, ile8-angiotensin II (SAR) (41% +/- 3% (P less than 0.001). Exogenous angiotensin I and angiotensin II did not affect BAEC migration. Exogenous angiotensin II abolished the effect of lisinopril on BAEC migration. Lisinopril increased cell-associated u-plasminogen activator (u-PA) 23% +/- 3% (P less than 0.001) in migrating BAEC and angiotensin II abolished this increase. SAR increased u-PA 33% +/- 0% (P less than 0.001). In contrast, these agents had the opposite effect on smooth muscle cells. Angiotensin II increased smooth muscle cell migration 40% +/- 3% (P less than 0.001), and this effect was abolished by SAR. Angiotensin II also increased cell-associated u-PA 83% +/- 7% (P less than 0.001) in migrating BASMC. The increase in BAEC migration with inhibition of endothelial cell angiotensin II stimulation, either with lisinopril or SAR, also was associated with an increase in cell-associated u-PA. These results indicate that lisinopril interrupts an autocrine pathway in endothelial cells, in which endothelial cell-derived angiotensin I is converted to angiotensin II by ACE, and imply that angiotensin-converting enzyme inhibitors in vivo would act to reduce vessel wall injury by directly increasing the rate of endothelial cell wound closure; by increasing the antithrombotic tendency of the endothelium via enhanced u-PA; and indirectly, by decreasing production of angiotensin II and thereby the rate of smooth muscle cell migration into the intima.

Human placenta contains an epithelial scatter protein

Scatter factor (SF) is a protein produced by cultured fibroblasts which causes epithelia to "scatter" into isolated cells. We found significant scatter activity in vivo in second trimester (but not term) human amniotic fluid and in human placenta. Placental SF was purified 500,000-fold and identified as a protein with Mr 78 kd. Factor scattered Madin-Darby canine kidney and human squamous carcinoma cells at 15 pM. Amino acid sequences from tryptic peptides did not match any known protein. Human placental fibroblasts produced high titers of scatter activity. SF may be involved in development and may enhance carcinoma invasion.

Signal transduction for chemotaxis and haptotaxis by matrix molecules in tumor cells

Transduction of signals initiating motility by extracellular matrix (ECM) molecules differed depending on the type of matrix molecule and whether the ligand was in solution or bound to a substratum. Laminin, fibronectin, and type IV collagen stimulated both chemotaxis and haptotaxis of the A2058 human melanoma cell line. Peak chemotactic responses were reached at 50-200 nM for laminin, 50-100 nM for fibronectin, and 200-370 nM for type IV collagen. Checkerboard analysis of each attractant in solution demonstrated a predominantly directional (chemotactic) response, with a minor chemokinetic component. The cells also migrated in a concentration-dependent manner to insoluble step gradients of substratum-bound attractant (haptotaxis). The haptotactic responses reached maximal levels at coating concentrations of 20 nM for laminin and type IV collagen, and from 30 to 45 nM for fibronectin. Pretreatment of cells with the protein synthesis inhibitor, cycloheximide (5 micrograms/ml), resulted in a 5-30% inhibition of both chemotactic and haptotactic responses to each matrix protein, indicating that de novo protein synthesis was not required for a significant motility response. Pretreatment of cells with 50-500 micrograms/ml of synthetic peptides containing the fibronectin cell-recognition sequence GRGDS resulted in a concentration-dependent inhibition of fibronectin-mediated chemotaxis and haptotaxis (70-80% inhibition compared to control motility); negative control peptide GRGES had only a minimal effect. Neither GRGDS nor GRGES significantly inhibited motility to laminin or type IV collagen. Therefore, these results support a role for the RGD-directed integrin receptor in both types of motility response to fibronectin. After pretreatment with pertussis toxin (PT), chemotactic responses to laminin, fibronectin, and type IV collagen were distinctly different. Chemotaxis to laminin was intermediate in sensitivity; chemotaxis to fibronectin was completely insensitive; and chemotaxis to type IV collagen was profoundly inhibited by PT. In marked contrast to the inhibition of chemotaxis, the hepatotactic responses to all three ligands were unaffected by any of the tested concentrations of PT. High concentrations of cholera toxin (CT; 10 micrograms/ml) or the cAMP analogue, 8-Br-cAMP (0.5 mM), did not significantly affect chemotactic or haptotactic motility to any of the attractant proteins, ruling out the involvement of cAMP in the biochemical pathway initiating motility in these cells. The sensitivity of chemotaxis induced by laminin and type IV collagen, but not fibronectin, to PT indicates the involvement of a PT-sensitive G protein in transduction of the signals initiating motility to soluble laminin and type IV collagen.(ABSTRACT TRUNCATED AT 400 WORDS)

Human trophoblast-extracellular matrix (ECM) interactions in vitro: ECM thickness modulates morphology and proteolytic activity

Trophoblast invasion of the uterine extracellular matrix, a critical process for human implantation and uteroplacental vascular development, is a striking example of controlled invasiveness. To examine cellular behavior relevant to this process, human trophoblasts were cultured on (i) Millicell filters prelayered with Matrigel and (ii) coverslips precoated with a gentle slope of Matrigel (Matribeach). Histologic sections of the Millicell system demonstrated significant invasion. However, on Matribeach the cells exhibited markedly different characteristics depending on the thickness of the Matrigel. On zone 1 (1-4 microns thick), flat aggregates and syncytia were seen. In contrast, cells on zone 2 (4-14 microns) formed rounded aggregates with intercellular processes. In this zone, prominent degradation of pericellular Matrigel proteins was assessed by both light microscopy and scanning electron microscopy. Treatment with 8-bromo-cAMP inhibited this proteolytic process. On zone 3 (14-60 microns), unicellular trophoblasts or small aggregates caused minimal matrix degradation. JEG-3 human choriocarcinoma cells exhibited similar morphologic and degradative properties on Matribeach, but zone 2 proteolysis was not affected by 8-bromo-cAMP. Our results suggest that extracellular matrix thickness has profound effects on cellular morphology and proteolytic activity. Furthermore, while both normal and malignant human trophoblasts can degrade extracellular matrix proteins, only normal trophoblast extracellular matrix degradation is inhibited by 8-bromo-cAMP.

Induction of distinct phenotypes in clonal and variant GH4 pituitary cells

GH cells are a widely used cell strain for the investigation of mechanisms regulating hormone release and synthesis. This report identifies two inducible phenotypes of the GH4 clone (epithelioid and motile) which may extend studies of this well-characterized cell line to different stages of pituitary cell development. GH4C1 cells treated in suspension with epidermal growth factor plus tetradecanoylphorbol acetate aggregate to form large epithelioid colonies with extensive cell-to-cell and cell-to-substratum adhesion. These cells cease replicating within 48 h, increase 50% in cell volume, and synthesize 40-fold more prolactin. A GH4C1 variant with enhanced substratum adhesion and little or no cell-to-cell adhesion (GH4S1), responds differently to this treatment. These cells cease replicating immediately, show increased cell separation, develop leading lamellae, and display locomotory activity. Each phenotype coexists in mixed cultures of GH4C1 and GH4S1 cells. This indicates that the different inducible response of the variant does not result from autocrine secretion. A molecular basis for cell-to-cell adhesion in GH4 cells was investigated. GH4C1, but not the variant cells, express a 180 kDa immunoreactive protein indistinguishable from an isoform of the neural cell adhesion molecule. Therefore the absence of cell-to-cell adhesion and inability to develop extensive cell-to-cell adhesion characteristic of the epithelioid phenotype may result from altered expression of the neural cell adhesion molecule. These findings are important because they have defined an in vitro approach to investigate genetic and cellular changes associated with the development and progression of pituitary cell phenotype.

Acidic fibroblast growth factor is a modulator of epithelial plasticity in a rat bladder carcinoma cell line

During normal embryogenesis and neoplastic transformation epithelia change their state of differentiation and degree of cohesiveness. It is thus essential to identify the signals modulating these transitions. We report here that acidic fibroblast growth factor (FGF) induces cells derived from a rat bladder carcinoma to lose their epithelial character and to acquire some properties typical of mesenchymal cells. The structurally related basic FGF did not have such an effect; both factors, however, had a mitogenic activity for these cells. Two distinct populations of receptors for acidic FGF and basic FGF were distinguished by their ligand-binding characteristics. The observations that both acidic and basic FGFs had a mitogenic effect on NBT-II cells and that only acidic FGF caused cell dissociation and dispersion strongly suggest that these two biological activities could be medicated through distinct signaling pathways.

Activating missense mutations in Ha-ras-1 genes in a malignant subset of bladder lesions induced by N-butyl-N-(4-hydroxybutyl)nitrosamine or N-[4-(5-nitro-2-furanyl)-2-thiazolyl]formamide

Urothelial cell cultures generated from urinary bladders from a series of N-butyl-N-(4-hydroxybutyl)nitrosamine (BBN)- or N-[4-(5-nitro-2-furanyl)-2-thiazolyl]formamide (FANFT)-treated Fischer 344 rats were examined for activating missense mutations in Ha-ras-1 genes. Our overall objective was to identify oncogene-activating mutations in this system and to determine what altered biological properties correlate with such genetic changes. The urinary bladders from the treated animals showed a spectrum of histopathologies, from simple hyperplasia to transitional cell carcinoma (TCC). Using restriction analysis, oligonucleotide hybridization, and DNA sequencing, we found that approximately 20% (3/14) of the bladder cell cultures had acquired oncogenic single-base substitutions in codon 61 of Ha-ras-1 genes (CAA----AAA or CGA). The donor bladder lesions for these three cultures, which also harbored the same ras-activating mutations, were all classified as stage A or B TCCs. However, four other TCCs also arising in this series were found to have normal Ha-ras genes. Whereas approximately half of the bladder cultures derived from the carcinogen-treated rats were nontumorigenic in athymic mice, the three cultures containing ras oncogenes were all highly tumorigenic (forming tumors within 5 wk of injection into athymic mice). These cultures also displayed a high degree of anchorage-independent growth and NIH 3T3-transforming activity in gene transfer assays. The nontumorigenic cultures were derived from bladder lesions that included three hyperplasias and three stage A TCCs. We conclude that ras-activating missense mutations were present in a malignant subset of bladder lesions induced by BBN or FANFT, but most of the lesions in this system appeared to involve genetic alterations elsewhere. Thus other oncogenes besides activated Ha-ras may apparently be associated with the same bladder histopathologies and transformation markers.

Protein factors which regulate cell motility

Cell motility (i.e., movement) is an essential component of normal development, inflammation, tissue repair, angiogenesis, and tumor invasion. Various molecules can affect the motility and positioning of mammalian cells, including peptide growth factors, (e.g., EGF, PDGF, TGF-beta), substrate-adhesion molecules (e.g., fibronectin, laminin), cell adhesion molecules (CAMs), and metalloproteinases. Recent studies have demonstrated a group of motility-stimulating proteins which do not appear to fit into any of the above categories. Examples include: 1) scatter factor (SF), a mesenchymal cell-derived protein which causes contiguous sheets of epithelium to separate into individual cells and stimulates the migration of epithelial as well as vascular endothelial cells; 2) autocrine motility factor (AMF), a tumor cell-derived protein which stimulates migration of the producer cells; and 3) migration-stimulating factor (MSF), a protein produced by fetal and cancer patient fibroblasts which stimulates penetration of three-dimensional collagen gels by non-producing adult fibroblasts. SF, AMF, and MSF are soluble and heat labile proteins with Mr of 77, 55, and 70 kd by SDS-PAGE, respectively, and may be members of a new class of cell-specific regulators of motility. Their physiologic functions have not been established, but available data suggest that they may be involved in fetal development and/or tissue repair.

Interleukin 6 decreases cell-cell association and increases motility of ductal breast carcinoma cells

Treatment of transformed breast duct epithelial cells with IL-6 produces a unique cellular phenotype characterized by diminished proliferation and increased motility. Human ductal carcinoma cells (T-47D and ZR-75-1 lines) are typically epithelioid in shape and form compact colonies in culture. Time-lapse cinemicrography shows that some untreated cells can transiently become fusiform or stellate in shape and separate from each other within a colony, but they usually rejoin their neighbors. While IL-6 suppresses the proliferation of these carcinoma cells, the IL-6-treated cells generally become stellate or fusiform and show increased motility. These changes persist as long as the cells are exposed to IL-6. This results in the dispersal of cells within colonies. The effects on cell growth, shape, and motility are reversible upon removal of IL-6. IL-6-treated T-47D cells display diminished adherens-type cell junctions, as indicated by markedly decreased vinculin-containing adhesions and intercellular desmosomal attachments. The effects on ZR-75-1 cell shape, colony number, and DNA synthesis are dependent on IL-6 concentration in the range from 0.15 to 15 ng/ml. Higher concentrations are required in T-47D cells for equivalent effects. Anti-IL-6 immune serum blocks IL-6 action. IL-6 represents a well-characterized molecule that regulates both the proliferation and junction-forming ability of breast ductal carcinoma cells.

Membrane fluidity affects tumor-cell motility, invasion and lung-colonizing potential

Membrane fluidity, determined by steady-state fluorescence polarization measurements, was correlated with metastatic capacity of murine tumor-cell lines. A correlation was observed in cell lines with different metastatic potential, and was confirmed when their lung-colonizing ability was modulated by alteration of either the membrane lipid composition or the culture conditions. Two cellular functions, motility and basement membrane invasion, were affected by the membrane lipid composition, and might explain the role of membrane fluidity observed in cancer metastasis.

Inhibition of in vitro tumor cell invasion by transmethylation inhibitors

Three inhibitors of S-adenosylmethionine-mediated transmethylation, 5'-methylthioadenosine (MTA), 2'-deoxyadenosine and sinefungin, inhibited in vitro invasion by a highly invasive clone (Cl-30) of rat ascites hepatoma cells, AH 130 (AH cells). Difluoromethylthioadenosine (DFMTA), a non-metabolizable derivative of MTA, also caused strong inhibition of invasion at concentrations that did not suppress the growth of the tumor cells. Cl-30 cells precultured in methionine-depleted medium showed decreased invasiveness. DFMTA was also effective on the invasion by fibrosarcoma, B16 melanoma and human lung carcinoma cell lines.

Purification of scatter factor, a fibroblast-derived basic protein that modulates epithelial interactions and movement

Scatter factor is a fibroblast-derived protein that causes separation of contiguous epithelial cells and increased local mobility of unanchored cells. Highly purified scatter factor has been obtained by a combination of ion-exchange and reverse-phase chromatography from serum-free medium conditioned by a ras-transformed clone (D4) of mouse NIH 3T3 fibroblasts. Under nonreducing conditions scatter factor has a pI of approximately 9.5 and migrates in SDS/polyacrylamide gels as a single band at approximately 62 kDa from which epithelial scatter activity can be recovered. Treatment with reducing agents destroys biological activity and is associated with the appearance of two major bands at approximately 57 and approximately 30 kDa. Whether both the 57-kDa and 30-kDa polypeptides are required for biological activity remains to be established. All the activities observed in crude medium conditioned by cells producing scatter factor are retained by highly purified preparations of scatter factor. These include (i) increased local movement, modulation of morphology, and inhibition of junction formation by single epithelial cells and (ii) disruption of epithelial interactions and cell scattering from preformed epithelial sheets. These changes occur with picomolar concentrations of purified scatter factor and without an effect on cell growth.

The in vitro invasiveness and interactions with laminin of K-1735 melanoma cells. Evidence for different laminin-binding affinities in high and low metastatic variants

The invasive and metastatic characteristics of cloned cells derived from the K-1735 murine melanoma were investigated. Cell lines which are highly metastatic in mice were found to be invasive in vitro, and to show an enhanced attachment to, spreading on and migration toward laminin. As attachment, spreading and directional migration are thought to be receptor-mediated events, the binding of laminin to these cells was studied. Biotinylated laminin was used to evaluate receptor binding by fluorescence activated cell sorting (FACS) and this method was compared with that in which the binding of radioactive laminin is measured. Both studies revealed that metastatic K-1735 cells (a) have more receptors for laminin compared with non-metastatic cells and (b) exhibit a second population of low-affinity binding sites not present on the non-metastatic cells. The differences in receptor number and type may account for the greater interaction of metastatic cells with laminin and their invasive phenotype.

Effect of scatter factor on motility of epithelial cells and fibroblasts

The scatter factor is a protein released by fibroblasts that causes dispersal of epithelial cell colonies and disruption of intercellular junctions, as well as an alteration of morphology with ruffling and rapid extension and movement of pseudopodia. To find out if the scatter factor has a direct effect on cell migration, the Boyden chamber assay was used to determine the effect of partially purified factor on the migration of cells through 8 microns pore size filters. The results showed that the mobility of Madin-Darby canine kidney (MDCK) cells was stimulated, and usually maximal at 100 ng per ml, which is equivalent to 100 to 200 units of activity in the standard assay based on the morphology and arrangement of cells. The migration was due to chemotaxis and chemokinesis. A keratinocyte cell line was also sensitive as were, to a lesser extent, BSCl monkey kidney cells. The motility of freshly isolated fibroblasts and fibroblast cell lines, however, was not significantly affected. The results confirm the cell specificity and paracrine role of the scatter factor and show that this fibroblast-derived molecule can directly stimulate the movement of epithelial cells.

Purification of the migration stimulating factor produced by fetal and breast cancer patient fibroblasts

We have previously shown that (i) human skin fibroblasts of fetal and adult origin display distinctive migratory phenotypes, (ii) this difference in cell behavior results from the production of a soluble "migration stimulating factor" (MSF) by fetal cells, and (iii) skin fibroblasts from breast cancer patients commonly resemble fetal fibroblasts both in migratory phenotype and in production of MSF. Data are now presented indicating that MSF present in the conditioned medium of fetal and cancer patient fibroblasts is precipitated at 10% saturation ammonium sulfate and binds to heparin and cation-exchange resins. Based on this information, we have devised a scheme for the purification of MSF involving the sequential application of ammonium sulfate precipitation, heparin affinity, gel filtration, and reverse-phase chromatography. Purified MSF has an estimated molecular mass of 70 kDa; amino acid analysis reveals a relatively high level of proline (13.34 residues per 100). Our results further suggest that skin fibroblasts from breast cancer patients produce an additional factor with migration stimulating activity; this factor is precipitated at higher concentrations of ammonium sulfate and binds to anion-exchange resins. We have previously discussed the possible direct involvement of fetal-like fibroblasts in cancer pathogenesis. The availability of MSF obtained from cancer patient fibroblasts provides a potential means with which to examine the complex cellular interactions contributing to this process as well as develop a screening regime for identifying individuals at elevated risk of developing cancer.

Use of the Membrane Invasion Culture System (MICS) as a screen for anti-invasive agents

The Membrane Invasion Culture System (MICS) assay was adapted for relatively rapid screening of compounds and used to identify anti-invasive drugs that inhibit human and murine tumor cell migration through a reconstituted basement membrane in vitro. Cell lines demonstrating low and high invasive and metastatic potentials were tested with all compounds for tumoricidal effects prior to evaluation in MICS at non-cytotoxic doses. The effect on invasive potential in the MICS assay was determined in 3 categories: (1) 48 hr drug pre-treatment prior to seeding in the MICS (exceptions: 90 min pre-treatment with pertussis toxin and, for some studies, continuous exposure for 2-7 days); (2) peptide or prostaglandins 2 hr after seeding and attachment to the membranes in MICS followed by continuous exposure; and (3) cells receiving neither drug nor peptide treatment and serving as controls in each MICS chamber. Since invasion involves cellular motility and deformability, some cytoskeleton disrupting agents were selected. Of these, vincristine, colcemid and colchicine inhibited invasion but taxol did not. Pre-treatment with cAMP agonists produced conflicting results: dibutyryl cAMP and 8-(4-chloro-phenylthio) cAMP resulted in 50% and 38% reduction in invasion, respectively, whereas 8-bromo cAMP stimulated invasive potential by 30%. Forskolin and cholera toxin both significantly reduced invasiveness. Pre-treatment with 5-azacytidine and araC, to consider the role of methylation and proliferations decreased invasive ability. Anti-metastatic drugs such as gamma-interferon and razoxane inhibited invasive potential but to varying degrees. Treatment of cells with prostaglandins E2, F2 alpha, A2, and D2 were ineffectual; however, indomethacin mildly inhibits invasion (less than 30%).(ABSTRACT TRUNCATED AT 250 WORDS)

Smooth muscle releases an epithelial cell scatter factor which binds to heparin

We report that cultured bovine calf aorta and human adult iliac artery smooth muscle cells release a soluble factor which causes spreading and separation of cells in normally tight, cohesive epithelial colonies, similar to the morphologic changes induced by the fibroblast-derived scatter factor (SF). Smooth muscle-derived SF was heat sensitive, trypsin labile, and nondialyzable, consistent with a protein (or proteins). Its effects on epithelium were not mimicked by a variety of proteolytic enzymes, growth factors, or hormones, and were not blocked by antiproteases or by antibodies to fibronectin and basic fibroblast growth factor. Epithelial cell proliferation was unaffected or only mildly stimulated by partially purified SF at concentrations that produced cell scattering. Both smooth muscle- and MRC5 human embryo fibroblast-derived SFs could be partially purified with similar elution patterns on a number of different chromatographic columns, including DEAE-agarose, heparin-sepharose, Bio-Rex 70, concanavalin A-sepharose, and MonoQ. SF from both sources bound tightly to heparin-sepharose, requiring 1.3 to 1.4 M NaCl for elution. The morphologically obvious cell scattering effect was markedly inhibited by soluble heparin at concentrations down to 5 micrograms/ml, and this inhibition was prevented by protamine. These data suggest that vascular smooth muscle cells produce an epithelial cell scattering factor with properties similar to the fibroblast-produced factor, including a high affinity for heparin. Such factors are potentially important because they may represent a new class of proteins that primarily regulate cell mobility rather than growth and differentiation.

Chemotaxis of cells isolated from periodontal tissues to different biological response modifiers

Directed migration of many different cell types is necessary for uneventful wound healing to occur. From clinical periodontal regeneration procedures, it is commonly believed that periodontal ligament cells will be of critical importance in obtaining a new connective tissue attachment. Here we present data which indicate that extracellular matrix components (fibronectin) and polypeptide growth factors (FGF, TGF-a, and TGF-β) modulate the ability of periodontal ligament cells to express directed migration. These data indicate a potential role for matrix components and growth factors in clinical periodontal regenerative procedures.

Differential organ tissue adhesion, invasion, and growth properties of metastatic rat mammary adenocarcinoma cells

Metastatic lines and clones of the rat 13762NF mammary adenocarcinoma have been established that show reproducible spontaneous metastasis from the mammary fat pad to regional lymph node and lung. Poorly (MTC) and highly (MTLn3) metastatic cloned lines derived from tumor growing in the mammary fat pad (MTC) and its spontaneous lung metastasis (MTLn3) were tested in vitro for their abilities to attach to and invade into syngeneic organ tissue and to survive and grow in medium conditioned by target and nontarget syngeneic organ tissues. The highly metastatic MTLn3 cells adhered to and invaded target lung tissue at significantly higher rates than the MTC cells, and bound to and invaded other organ tissues although at lower rates than lung tissue. Similarly, the MTLn3 cells showed significantly higher growth stimulation by lung-conditioned medium than medium conditioned by other tissues. Poorly metastatic MTC cells were not significantly stimulated by any of the organ-conditioned media. The results are consistent with previous proposals that explain preferential organ metastasis in terms of 'seed and soil', and further suggest that metastasis of mammary tumors to specific organ secondary sites is mediated by specific properties, such as those involved in tumor-cell organ-cell adhesion, invasion, and growth.

Growth and metastasis of hypermotile, hyperinvasive cancer cells selected in vitro by rapid locomotion under various conditions

Cancer cells selected from a cultured murine fibrosarcoma by rapid migration through micropore membranes moved considerably faster through such membranes and invaded biological tissues much more efficiently than did the unselected parent cells. The present data show that populations of cells selected by unstimulated migration or by haptotaxis to laminin moved not only faster, but also in larger numbers than the parent cells. However, the selected cells were far less efficient than the parent cells in forming spontaneous lung metastases in syngeneic mice, although all cell lines were 100 per cent tumorigenic. Analysis of paired data within each group showed no relationship between the primary tumor size at any observation time and the number of lung metastases finally formed. Therefore, although the parent cell line produced primary tumors growing slightly more rapidly than did the various lines of hypermotile cells, this was probably not the main cause of the difference in spontaneous metastasis formation between the groups. Lung colonization experiments performed by intravenous injection of cells could not explain the spontaneous metastasis results. In vitro, the cells selected by rapid haptotaxis to laminin grew considerably better than the other cells in 0.1 per cent fetal bovine serum, but there were no, or only minor, differences in higher serum concentrations. Combined, these results indicate that small subpopulations of cells selected by extreme efficiency in one step of the metastasis process may be so specialized that they perform poorly in other steps. Therefore, the results do not disprove the concept that tumor cell migration plays an important part in metastasis.

Organ specificity of tumor metastasis: role of preferential adhesion, invasion and growth of malignant cells at specific secondary sites

The locations of distant secondary tumors in many clinical cancers and animal tumors are nonrandom, and their distributions cannot be explained by simple anatomical or mechanical hypotheses based on the simple lodgment or trapping of tumor cell emboli in the first capillary bed encountered. Evidence from certain experimental tumor systems supports Paget's 'seed and soil' hypothesis on the nonrandom distributions of metastases, in which the unique properties of particular tumor cells ('seeds') and the different characteristics of each organ microenvironment ('soil') collectively determine the organ preference of metastasis. Experimentally, differential tumor cell adhesion to organ-derived microvessel endothelial cells and organ parenchymal cells, differential invasion of basement membranes and organ tissues, and differential responses to organ-derived growth-stimulatory and -inhibitory factors all appear to be important determinants in explaining the organ preference of metastasis. Each tumor system may achieve organ specificity because of its own unique set of multiple metastasis-associated properties and responses to host microenvironments. As neoplasms progress to more highly malignant states multisite metastases are more likely and organ-specific metastases may be masked or circumvented owing to stochastic events, tumor cell diversification, host selection processes, and increased production of tumor autocrine molecules that may modulate adhesion, invasion, growth, and other properties important in metastasis. The importance of each of these properties, however, appears to vary considerably among different metastatic tumor systems. These and other tumor cell and host properties may eventually be used to predict and explain the unique metastatic distributions of certain human malignancies.

Gene products which play a role in cancer invasion and metastasis

Invasion requires a number of distinct tumor cell interactions with host tissue, beginning with attachment to the matrix, followed by hydrolysis of matrix material and locomotion. Gene products which may be involved in these steps are discussed here. Laminin receptors and integrins have roles in the adhesion phase, while certain collagenases are prominent among the matrix-degrading enzymes. Autocrine motility factors, distinct from growth factors, appear to be involved in tumor cell locomotion. Finally, certain oncogenes, particularly of the ras family, are closely related with metastatic potential. A detailed understanding of the molecular biology of invasion and metastasis could ultimately lead to specific means of interfering with or even reversing these malignant processes.