Elastase secretion by stimulated macrophages. Characterization and regulation.

Thioglycolate-stimulated mouse peritoneal macrophages secrete a Proteinase which degrades insoluble elastin. There is little elastase activity in cell lysates but the bulk of the enzyme accumulates extracellularly during culture in serum-free medium. The secretion of elastase is sustained for over 12 days in culture and continued secretion of elastase requires protein synthesis. Unstimulated macrophages secrete very little elastase activity but can be triggered to secrete higher levels of this enzyme by phagocytosis and intracellular storage of latex particles. The macrophages elastase is a distinctive proteinase differing from the elastases of pancreas and granulocytes and is distinct from the other secreted proteinases of macrophages, namely, collagenase and plasminogen activator. The macrophages elastase is a serine proteinase and is inhibited by di-isopropyl phosphoro-fluoridate, ovoinhibitor, EDTA, dithiothretiol, and serum. Its activity is little affected by soybean trypsin inhibitor, turkey ovomucoid and chloromethyl ketones derived from tosyl lysine, tosyl phenylalanine, and acetyltetra alanine. Hydrolysis by macrophage elastase of chromogenic ester substrates for pancreatic elastase could not be detected. Elastase secretion by stimulated macrophages exceeds that by primary and established fibroblast cell strains. It is likely that elastase secretion by macrophages plays a major role in the pathogenesis of chronic destructive pulmonary diseases such as emphysema.

Secretion of a specific collagenase by stimulated macrophages.

Thioglycollate-stimulated mouse macrophages release a specific collagenase into their medium during in vitro culture. The macrophage collagenase has been characterized as a typical metal proteinase which catalyzes the cleavage of the native collagen molecule into three and one-quarter fragments. The extracellular accumulation and low activity in cell lysates suggest that collagenase is a secretion product of the stimulated macrophage. Prolonged secretion of the enzyme at a constant rate for more than 7 days in culture and its inhibition by cycloheximide provide evidence for biosynthesis in vitro. In contrast, secretion of collagenase is barely detectable from unstimulated macrophages which can, however, be stimulated to secret the enzyme by ingestion and intralysosomal storage of latex particles or dextran sulfate. Macrophages laden with latex, an undigestable particle, continue to release collagenase for at least 20 days. Several established mouse cell lines have also been examined for their capacity to secrete collagenase. Collagenase is one of a class of inducible neutral proteinases by which the activated macrophage can modify its extracellular environment.

Studies on purified rheumatoid synovial collagenase in vitro and in vivo.

Rheumatoid synovial collagenase obtained from culture medium can be separated by Sephadex gel filtration into two peaks of enzyme activity. These have been designated as fast-moving and slow-moving rheumatoid synovial collagenases on the basis of their electrophoretic mobility on polyacrylamide gels. The slow-moving rheumatoid synovial collagenase has been highly purified by affinity chromatography on collagen conjugated to Sepharose and used to prepare a monospecific anti-synovial collagenase antiserum. The antiserum against rheumatoid synovial collagenase has permitted the demonstration of immunoreactive collagenase in extracts of rheumatoid synovial tissue that have no detectable enzymatic activity. Collagenase has also been detected immunologically in enzymatically inactive culture medium from the first 24 hr of culture. Recovery of collagenase activity appears to be related to the chromatographic separation of the enzyme from serum antiproteases. The demonstration of collagenase in vivo in rheumatoid synovium adds further support for the concept that the enzyme is present in tissue at levels that are of significance in the pathogenesis of rheumatoid arthritis. In addition, rheumatoid synovial collagenase and human skin collagenase show complete immunologic identity when reacted with monospecific antiserum prepared against either of these purified enzymes, indicating that organ specificity between these two human collagenases is unlikely.

Collagenases in human synovial fluid.

An enzyme which degrades native collagen at neutral pH has been isolated from cultures of rheumatoid synovium in vitro, but little or no collagenolytic activity has been found in homogenates of fresh rheumatoid synovium. Similar to most other mammalian collagenases this synovial enzyme is readily inhibited by serum proteins. Proteins of synovial fluid are derived largely from serum and synovial fluid from noninflamed joints was found to inhibit synovial collagenase; the inhibitor was destroyed by trypsin, but not by hyaluronidase. Inhibitory activity was reduced in approximately one-half of the fluids from patients with rheumatoid arthritis. In a total of nine synovial fluids, collagenolytic activity was detectable. This activity was not present in constant amounts in synovial fluids aspirated at different times from the same patient and tended to vary inversely with the titer of inhibitory proteins. The collagenolytic activity in the synovial fluids from different patients was variably inhibited by serum proteins. Two distinct collagenases were detected in some rheumatoid synovial fluids and separated by gel filtration. One, labeled "B" enzyme, with an estimated molecular weight 20,000-25,000 resembled the collagenase obtained from synovial cultures. The other, labeled "A" enzyme degraded collagen fibrils as well as collagen in solution. Disc electrophoresis on acrylamide gels and electron microscopy of segment long spacing (SLS) aggregates of reaction products of the enzymes at 27 degrees C demonstrated that both "A" and "B" enzymes cleaved collagen molecules at a point three-quarters from the amino terminal end of the molecule. Thus collagen degradation in rheumatoid arthritis could result from the operation of these two collagenases.

Localization of collagenase in the growth plate of rachitic rats.

In the transition from proliferation to hypertrophic cell zones in the growth plate, there is an increase in chondrocyte volume and a corresponding decrease in collagen content to accommodate the enlarging cells. It is postulated that collagenase accounts for this collagen loss. To test this hypothesis, tibial growth plates were obtained from normal rats, rachitic rats deficient in vitamin D and phosphate, and rats after 48 and 72 h of healing from rickets. Collagenase was quantitated by a pellet assay based on the release of solubilized collagen from the endogenous insoluble collagen in the tissue homogenates. A fourfold greater collagen release and a concomitant sixfold greater hypertrophic cell volume were measured in rachitic growth plates compared with normal age-matched controls. During healing of rickets, collagenase activity and hypertrophic cell volume returned almost to control levels. Rachitic growth plates were dissected into the juxtaepiphyseal 1/3 and the juxtametaphyseal 2/3. The latter portion contained greater than 95% of the hypertrophic cells and 86% of the collagenase. The collagen-degrading activity was extracted from this region and was shown to be a true collagenase by its production of typical A fragments of tropocollagen produced by collagenase action. The enzyme was activated by aminophenylmercuric acetate and trypsin and was inhibited by EDTA, 1,10-phenanthroline, and a tissue inhibitor of metalloproteinases from human articular cartilage. Inhibitors of aspartic, cysteine, and serine proteases had no effect. Micropuncture fluids aspirated from rachitic cartilage contained latent collagenase activity, indicating an extracellular localization. Negative tests for hemoglobin in the rachitic cartilage samples indicated that there was no contamination by capillaries and that this was not a source of collagenase. It is concluded that extracellular collagenase accounts for the loss of cartilage matrix in the hypertrophic zone, and that this process may be distinct from that of capillary invasion.

12-o-Tetradecanoyl-phorbol-13-acetate-differentiated U937 cells express a macrophage-like profile of neutral proteinases. High levels of secreted collagenase and collagenase inhibitor accompany low levels of intracellular elastase and cathepsin G.

Human monocytic tumor cells of the U937 cell line contain substantial quantities of two neutrophil neutral proteinases, elastase and cathepsin G, raising the question of whether their presence reflects an expression of transformation or whether normal monocytes undergo a developmental stage in which they produce certain neutrophil proteinases. To address this issue, we examined U937 cells for production of collagenase, since human alveolar macrophages release fibroblast-like collagenase, an enzyme that is distinct from neutrophil collagenase. Using an immunoassay that utilized antibody to skin fibroblast collagenase, we found that U937 cells secreted barely detectable quantities of enzyme, 10-12 ng/10(6) cells per 24 h, under basal conditions. Upon incubation with 10 nM 12-o-tetradecanoyl-phorbol-13-acetate (TPA), however, collagenase release increased 200-fold, comparable to the amount secreted by phorbol-stimulated human fibroblasts. Metabolic labeling and immunoprecipitation confirmed the enhanced synthesis of U937 cell collagenase upon TPA exposure. This enzyme activity further resembled fibroblast collagenase and differed from neutrophil collagenase by exhibiting preferential cleavage of monomeric type III collagen relative to type I. As previously observed with human alveolar macrophages, U937 cells also released a protein identical to the collagenase inhibitor produced by human skin fibroblasts, a molecule not associated with neutrophils. Release of this inhibitor increased 10-fold with TPA exposure. In contrast to collagenase and collagense inhibitor, TPA-treated U937 cells contained only 10-15% as much elastase and cathepsin G activities as control cells. Thus, TPA-induced differentiation modified the presence of these enzymes in the direction of their content in normal monocytes. Since the neutral proteinase profile of undifferentiated U937 cells resembles that of neutrophils and changes markedly after cellular differentiation to one that is characteristic of monocytes, these data suggest that neutrophilic proteinases may be produced by normal monocytes during the early stages of their differentiation.

Coexpression of vimentin and keratins by human melanoma tumor cells: correlation with invasive and metastatic potential.

BACKGROUND: Several protein markers, including vimentin, have been used to diagnose human melanoma. Because melanoma often has metastasized by the time of diagnosis, early markers prognostic for metastatic potential need to be identified. Commonly, vimentin is found in mesenchymal cells, and keratins are present in epithelial cells, but recent studies report coexpression of vimentin and keratin(s) in epithelial and nonepithelial neoplasms, including some melanomas. PURPOSE: Our purpose was to determine whether coexpression of vimentin and keratin(s) is correlated with tumor cell invasion and metastatic behavior. METHODS: We evaluated nine human melanoma cell lines expressing vimentin and other markers of aggressive tumor behavior (HMB-45, S-100, HLA-ABC class I and HLA-DR class II histocompatibility antigens, and K8 and K18 keratins). Levels of K8 and K18 keratins were determined in the highly metastatic C8161 cell line, the poorly metastatic A375P line, and the moderately metastatic A375M line. To determine whether the presence of keratin affects migratory ability, we altered the conformational structure of keratin filaments in C8161 cells by transfection with a mutant K18 complementary DNA. We also determined messenger RNA levels of human type IV collagenase, an enzyme marker for invasion and metastasis. RESULTS: In A375P cells, two-dimensional electrophoresis with Coomassie-stained gels, immunoblotting, and immunofluorescence staining showed no detectable levels of K8 or K18. A375M cells showed low levels of K8 and K18 by Western and Northern blotting, with a distinctive fluorescent subpopulation of cells. In comparison, K8 and K18 levels in C8161 cells were high in all cells. Type IV collagenase messenger RNA levels were lowest in A375P cells and highest in C8161 cells, correlating with invasive ability in vitro and metastatic potential in athymic nude mice. The transfectant clones C1070-10 and C1070-14 derived from the C8161 parent line showed dramatic morphological changes, disrupted keratin filaments, and decreased invasive and metastatic potential directly correlated with a reduction in migratory activity. CONCLUSION: These findings show a correlation between the coexpression of vimentin with K8 and K18 keratins and the invasive and metastatic behavior of three representative human melanoma cell lines.

Expression of collagenase IV (basement membrane collagenase) activity in murine tumor cell hybrids that differ in metastatic potential.

Expression of a basement membrane collagen-degrading metalloprotease activity (collagenase IV) was studied in a series of murine cell hybrids derived from fusions between highly metastatic cells (B16-F10RR) or moderately metastatic cells (UV-2237RR) and tumorigenic cells (K-1735 clone 16) or normal cells [peritoneal macrophages (PEC) or C3H mouse embryo fibroblasts (C3H-F)]. The collagenase IV activity of the parent cells and the hybrids was assayed in vitro and compared to the metastatic propensity of the same cells evaluated in both syngeneic (C57BL/6 X C3H/HeN)F1 mice and BALB/c nude mice. The level of collagenase IV activity secreted by the parent lines correlated with their metastatic capacity. The highly metastatic B16-F10RR line secreted the highest enzyme activity, whereas the tumorigenic but nonmetastatic K-1735 clone 16 and the normal parents PEC and C3H-F secreted the lowest enzyme activity. The enzyme activity was completely inhibited with EDTA. The hybrid derived from fusion of cells from two metastatic cell lines as well as hybrids derived from a metastatic and a nonmetastatic tumor cell line expressed higher levels of collagenase IV activity than either parent, and this expression was associated with a high ability to produce metastases in both nude and syngeneic mice. Fusion of metastatic cells with normal cells produced hybrid cells that exhibited suppression of both collagenase IV activity and metastatic capacity. Collagenase IV activity and metastatic propensity can, therefore, be altered by somatic cell hybridization; in the series of hybrids examined in these experiments the expression of type IV collagen-degrading metalloprotease activity and the metastatic ability were closely correlated, which suggests that collagenase IV activity and other properties required for metastasis are genetically linked.

Collagenolytic activity of rabbit V2 carcinoma implanted in the nude mouse.

The relative contribution of host cells and tumor cells to the production of collagenase and its regulation during tumorigenesis were studied with the use of a heterologous rabbit tumor-nude mouse host system. The V2 carcinoma, a malignant neoplasm of the New Zealand White rabbit, behaved as a nonmetastasizing, noninvasive tumor when implanted and grown in the inbred Swiss albino nude mouse. The extracts from both tumors contained similar levels of collagenase. Tumor explants also released enzyme into culture medium in both cases, but the rabbit tumor produced approximately 10 times more collagenase than the nude mouse. Freeze-thawing of the explants or treatment with cycloheximide markedly inhibited the appearance of enzyme in the medium from the rabbit tumor but not from the nude mouse tumor. The relative proportions of mouse- and rabbit-derived collagenase in the nude mouse tumor extracts and culture medium were determined with the use of antibodies specific for rabbit V2 tumor and mouse bone collagenases. Approximately 70% of the nude mouse tumor enzyme was derived from the rabbit tumor, and approximately 30% was derived from the mouse host. These findings indicate that the former might represent stored enzyme carried over during tumor transplantation into the nude mouse, whereas the latter might have originated from stimulation of host cells during tumorigenesis.

An animal model for colon cancer metastasis: establishment and characterization of murine cell lines with enhanced liver-metastasizing ability.

A detailed understanding of the pathogenesis of colon cancer metastasis has been hindered by the lack of appropriate animal models which accurately reflect events in this complex process. An animal model for colon cancer metastasis is described in which spontaneously metastasizing colonic tumors are formed after injection of murine colon cancer cells into the cecal wall of BALB/c mice. Using this model, tumor cells with different liver-metastasizing potential were selected and shown to possess several properties known to be associated with other metastatic cell lines. The ability of tumor cells to invade a reconstituted basement membrane and to secrete type IV collagenase was directly proportional to their metastatic ability. In addition, liver-metastasizing cells preferentially migrated toward liver extracts in a Boyden chamber assay, as compared to extracts of brain or lung, and adhered rapidly to highly purified hepatic sinusoidal endothelial cells versus hepatic parenchymal cells in vitro. This model may thus be useful for studying many aspects of the pathogenesis of colon cancer metastasis.

Macrophage and lymphocyte potentiation of syngeneic tumor cell and host fibroblast collagenolytic activity in rats.

The collagenolytic responses of normal rat skin fibroblasts (NRS-F) and rat mammary MTLn3 tumor-derived fibroblasts (Ln3-F) were examined following exposure to rat macrophage (M phi-CM)- and lymphocyte (LYM-CM)-conditioned culture medium and/or tumor cell-conditioned medium. Alveolar, intratumoral, and peritoneal macrophages were prepared from mammary adenocarcinoma-bearing rats, as were the peritoneal lymphocytes. Incubation of the two fibroblast populations with LYM-CM produced a 10- and 7-fold stimulation of collagenolytic activity by NRS-F and Ln3-F cells, respectively. Similarly, exposure of NRS-F and Ln3-F fibroblasts to peritoneal M phi-CM produced a 7- and 4-fold increase in the expression of collagenolytic activity, respectively. Conditioned medium from MTLn2 tumor cells also stimulated the collagenolytic expression of both fibroblast populations. Incubation of tumor-associated Ln3-F or NRS-F fibroblasts with MTLn2 tumor cell-conditioned medium enhanced fibroblast collagenolytic activity approximately 20 and 17 times, respectively. When M phi-CM and LYM-CM were further "conditioned" by a subsequent incubation with MTLn2 tumor cells, each stimulated the expression of collagenolytic activity by both fibroblast populations and this was especially pronounced (120-fold increase) in the response of Ln3-F to LYM-CM further conditioned by MTLn2 tumor cells. The conditioned media derived from M phi, LYM, and MTLn2 tumor cells with or without trypsin activation contained low levels of interstitial-type collagenolytic activity which made no significant contribution to the collagenolytic activity of the stimulated fibroblasts. Some collagenase inhibitory activity, however, was detected in the M phi-CM, suggesting that the actual stimulation of collagenolysis by host fibroblasts is underestimated. We conclude that macrophages, lymphocytes, and tumor cells all have the potential to produce stimulatory factor(s) which enhance the collagenolytic activity of normal fibroblast populations. This study provides further evidence of the multifactorial control of collagenase production and supports the concept that host cell-tumor cell interactions can enhance the expression of collagenolytic enzymes.

Inhibition by retinoic acid of type IV collagenolysis and invasion through reconstituted basement membrane by metastatic rat mammary adenocarcinoma cells.

The activity of type IV collagenase, which enables tumor cells to degrade collagen type IV found in the subendothelial basement membrane, has been correlated with the metastatic potential in several tumor types, including the rat 13762NF mammary adenocarcinoma cell line and its clones. In this study, we examined whether all-trans-retinoic acid (all-trans-RA) and other retinoids, which exhibit antitumor activity in vitro and in vivo, affect the collagenolytic activity of metastatic rat 13762NF mammary adenocarcinoma cells. Cells of the highly metastatic lung-colonizing clone MTF7.T35.3, derived from the 13762NF cell line, were treated for 3 days with 0.1, 1, or 10 microM all-trans-RA, harvested, and seeded on [3H]proline-labeled extracellular matrix deposited by cultured rat lung endothelial cells or on a film of purified [3H]proline-labeled type IV collagen. The amount of radioactivity released into the medium during the subsequent 24 to 72 h was measured, and it was found that all-trans-RA treatment inhibited degradation of extracellular matrix and type IV collagen by 50 to 60%. This effect was observed whether the cells had been treated with all-trans-RA in serum-free medium or in medium supplemented with heat-inactivated or acid-treated fetal bovine serum. The growth of the cells was not inhibited under these conditions, except after treatment with 10 microM all-trans-RA in serum-free medium. The reduction in collagenolytic activity was observed in viable cells as well as in conditioned medium. A 24-h exposure of cells to all-trans-RA was sufficient to cause a 30% decrease in the collagenolytic activity, and this inhibitory effect was reversible. The direct addition of all-trans-RA to conditioned medium had no effect on secreted collagenase activity. The apparent molecular weights of the collagenolytic enzymes were determined by electrophoresis of cell extracts and concentrated conditioned medium in type IV collagen-embedded polyacrylamide gels followed by renaturation and activation of the enzymes within the gels. Two major type IV collagenolytic metalloproteinases exhibiting molecular weights of 64,000 and 88,000, respectively, were detected by this method. These two enzymes were also found to have specificity for gelatin. The Mr 64,000 enzyme could be extracted from viable cells (presumably from the cell membrane) by 2% 1-butanol. Treatment with all-trans-RA decreased the level of these enzymes in the cellular, cell membrane, and conditioned medium compartments.(ABSTRACT TRUNCATED AT 400 WORDS)

Collagenase and elastase production by mouse mammary adenocarcinoma primary cultures and cloned cells.

We have shown previously that an increase in tumor invasion and metastases occurred concurrently with a decrease in collagen content of the extracellular matrix surrounding the C3H mouse mammary adenocarcinoma borne by C3H/HeJ mice. In this paper we report the production of collagenase and elastase activities by the primary tumor cultures and three types of cloned C3H mouse mammary adenocarcinoma cell cultures. The primary tumor cell cultures and tumor-associated stromal cultures produced large amounts of collagenase and elastase activities. On the other hand, the primary tumor capsule cultures produced little or no collagenase and elastase activities even though they produced type I collagen. The production of proteases by the primary tumor cultures decreased along with time and with an alteration in the morphology of cell populations and/or passage of the cultures. The three clones of tumor cell cultures produced variable amounts of collagenase in response to induction by phorbol myristate acetate, an agent that stimulates maximal collagenase production. In contrast, all three cloned cultures elaborated significant amounts of elastase that degraded insoluble ligamental elastin, and most of the elastase production was increased further in response to induction by phorbol myristate acetate. Each cloned cell population exhibited differences in their production of collagenase and elastase in parallel with their difference in growth kinetics, yet these cells still possess the distinctive properties of the tumor. However, a unit amount of collagenase produced by each of the cloned cultures, with or without induction by phorbol myristate acetate, was less than that of the primary tumor cultures. Results suggest that some cell types or combination of cell types in the heterogeneous cell population of the tumor and/or their products appear to be responsible for the increased production of collagenase and elastase activities and for the invasiveness of a malignant tumor.

Effects of vitamin A and dexamethasone on collagen degradation in mouse mammary adenocarcinoma.

Collagenases and other neutral proteases in tumors may facilitate tumor extension, invasion, and subsequent metastasis. We report the effects of vitamin A and dexamethasone, known inhibitors of collagenase production in vitro, on the collagen metabolism of mouse mammary adenocarcinoma and its capsule, borne by C3H/HeJ mice. The weight of the capsule was about 4% of the tumor, yet the total collagen content of the capsule was about 10-fold greater than that of the tumor tissue; tumor cells had no detectable collagen. With tumor growth, the collagenase and other neutral protease activities were increased in the tumor tissue; a negative correlation existed between collagenase activity and collagen content of the capsule. The protease activities of the tumor borne by vitamin A-treated hosts were about 50% lower than those of the controls; this coincided with a slight increase in the collagen content of the capsule. In contrast, the collagen content of the capsule borne by dexamethasone-treated hosts was 50% less than that of the controls; the protease activities were similar to the controls and occurred with tumor invasion and metastasis. Results suggest that the collagen metabolism of the capsule may be an indicator of proteolytic events within the tumor and the metastatic potential of the tumor that, in turn, suggests the possibility of preventing metastasis by inhibiting the production of collagenases and other neutral proteases, thereby localizing the tumor cells within the capsule. Vitamin A could be used for that purpose.

Blocking of collagenase secretion by estramustine during in vitro tumor cell invasion.

The effects of the antitumorigenic drug estramustine on tumor cell membrane penetration (invasion) were investigated in vitro by utilizing a synthetic basement membrane system (a modified Boyden chamber). Tumor cells were plated on a "partition barrier," consisting of a porous filter (8-micron pores) which was coated with a reconstituted basement membrane matrix (Matrigel), and induced to migrate across the barrier with conditioned medium obtained from 9DU 145 human prostatic tumor cells (passage 9). Quantitative radiolabeling studies demonstrated that specially isolated lines (isolated by several passages through the Matrigel) of DU 145 cells, A2058 melanoma, and B16-F10 melanoma cells were highly invasive such that 15 to 20% migrated across a 1-mm-thick Matrigel layer within 5 h at 37 degrees C. NIH-3T3 cells, mouse fibroblasts, and 20DU 145 cells (passage 20) exhibited little or no membrane invasive behavior. Micromolar concentrations of estramustine (30 to 120 microM) inhibited invasion by the invasive cell lines in a dosage-dependent fashion. Quantitative enzymatic assays and radioimmune assays demonstrated that estramustine inhibited membrane invasion by blocking type IV collagenase secretion. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blots confirmed that 30 to 60 microM estramustine blocked secretion of a Mr 105,000 collagenase protein. Indirect studies showed that a collagenase antibody raised against the Mr 105,000 protein and inhibitors of proteinase activity, including a metalloproteinase inhibitor, and 1,10-phenanthroline, blocked invasion. Because the antibodies inhibited type IV collagenase digestion of 3H-mouse type IV collagen, and invasion simultaneously, it is proposed that collagenolytic activity is involved in invasion. These data demonstrate that estramustine blocks proteinase secretion, and suggest that estramustine may be a useful therapeutic drug for the prevention of metastasis.

Influence of organ environment on the growth, selection, and metastasis of human colon carcinoma cells in nude mice.

The purpose of these studies was to determine whether the biological and metastatic behaviors of tumor cells isolated from fresh surgical specimens of human colon carcinomas are influenced by the isolation method and the organ site of implantation and growth in nude mice. Three surgical specimens were obtained from three different patients. Two tumors were primary human colorectal carcinomas (HCC) classified as Dukes' B2 (KM12) and Dukes' D stages (KM20), and the third was from a liver metastasis (KM23). The tumors were enzymatically dissociated, and viable cells were implanted into the subcutis or spleen of different nude mice or were established in culture. Tumors developed in both sites of implantation, but hepatic metastases were found only in those nude mice that received splenic implantations of HCC cells. Cells from Dukes' D stage tumors produced more hepatic disease than cells from the Dukes' B tumor. Cells of the parental KM12C (culture) were injected into the spleen or cecum of nude mice to produce experimental and spontaneous hepatic metastases, respectively. HCC lesions were harvested from livers of nude mice and established as individual cell lines in culture. This procedure yielded cell lines KM12SM (spontaneous metastasis) and KM12L1 (experimental metastasis). The selection cycle for cells implanted into the spleen was repeated three more times to produce the cell line designated KM12L4. Cells of the parental KM12C and the three selected variants were injected into nude mice by different routes: i.v., s.c. into the cecum, and into the spleen. Subsequent to implantation into the spleen, all cell lines were shown to be tumorigenic. Cells from the selected KM12L4 and KM12SM lines produced a significantly higher number of experimental liver metastases than the parental cells. Moreover, subsequent to the injection into the cecum, cells of the once-selected KM12SM (for spontaneous metastasis) produced a higher incidence of spontaneous liver metastasis than all other lines. The human origin of all the lines was confirmed by isoenzyme and karyotype analyses. The two highly metastatic lines (KM12L4 and KM12SM) were tetraploid and produced elevated levels of type IV collagenolytic activity. Collectively, the results demonstrate that the orthotopic implantation of HCC cells into the appropriate organ environment can be used for efficient isolation and for study of metastatic subpopulations of cells from human colon carcinoma.

Cloning and characterization of human tumor cell interstitial collagenase.

A full-length complementary DNA (cDNA) for interstitial collagenase was isolated from an A2058 melanoma cDNA library using the pCD-X Okayama-Berg vector. The tumor interstitial collagenase cDNA was sequenced and compared to the published sequences for human fibroblast collagenase. The sequence for the tumor collagenase has two DNA base pairs which differ from the sequence of normal fibroblast collagenase. Restriction enzyme digestion of a specific DNA fragment produced by polymerase chain reaction amplification of genomic DNA from human placenta resolves a discrepancy in the previously reported DNA and amino acid sequences for the fibroblast collagenase. A high level of expression of interstitial collagenase message was found in human A2058 melanoma cells by Northern blot analysis, and this level was slightly increased by phorbol ester (phorbol myristate acetate) stimulation. Interstitial collagenase mRNA expression was significantly decreased by treatment with either transforming growth factor-beta 1 or retinoic acid in A2058 melanoma cells. A high level of the collagenase protein secreted into conditioned media was identified by Western blotting. As shown by gelatin zymogram analysis interstitial collagenase was one of at least two metalloproteinases secreted by this same cell line. Thus, human melanoma cells can directly produce interstitial collagenase without a requirement for host cell interaction.

Connective tissue degradation by invasive rat bladder carcinomas: action of nonspecific proteinases on collagenous matrices.

The invasive RBTCC-8 rat bladder carcinoma cell line (passage number, greater than 100) and its derivates, the RBTCC-8 tumor isografts and the 1-RBTCC-8 daughter cell line (fourth passage), express proteolytic activities of broad substrate specificity, which allow them to efficiently degrade extracellular (collagenous) matrices. Cell-associated, collagenolytic activity is evidenced by the release of hydroxyproline from collagen substrates of types I and IV, by visualizing the low-molecular-weight collagen breakdown products on sodium dodecyl sulfate-polyacrylamide gels, and by the depth of invasion into extracellular matrices in our bone invasion assays. Fractionated by diethylaminoethyl column chromatography, the major collagenolytic activities against collagens of types I and IV coelute in a relatively narrow peak within a NaCl gradient. The pooled collagenolytic diethylaminoethyl fractions contain: (a) two chymotrypsin-like, catheptic activities; (b) activity against a synthetic elastase substrate; (c) gelatinase activity; and (d) caseinolytic activity. Despite efficient collagenolysis, a vertebrate-type collagenase cannot be detected in any of our tumor samples, even after trypsin activation of the tumor cell extracts. The mechanism of action of these nonspecific proteinases is thought to be that of collagen "crosslinkases." The neutral proteinase activities are highest in RBTCC-8 tumor isografts, intermediate in the fourth passage 1-RBTCC-8 carcinoma cell line, and lowest in the RBTCC-8 carcinoma cell line of high passage number. The levels of these nonspecific enzyme activities are well correlated with the depth of invasion into bony matrices, as shown by our invasion assays.

Growth of rat mammary adenocarcinoma cells in semisolid clonogenic medium not correlated with spontaneous metastatic behavior: heterogeneity in the metastatic, antigenic, enzymatic, and drug sensitivity properties of cells from different sized colonies.

Using rat 13762NF mammary tumor cell clones of varying spontaneous metastatic potentials and biochemical properties and known phenotypic stabilities we studied the relationship between cell colony growth in a clonogenic assay and the biological and biochemical properties of cells derived from different cell colonies. The spontaneous metastatic potential of in vivo or in vitro grown 13762NF tumor cells was not related to their in vitro cloning efficiencies; cells of both low and high metastatic potential formed colonies of various sizes and shapes during 14 days of growth in 0.3% or 0.6% semisolid agarose. A highly metastatic cell clone of relatively low growth potential in agarose was examined further. Individual tumor cell colonies derived from this cell clone were removed from agarose and their properties determined. Cells from small (less than 100-microns-diameter) or large (greater than 500-microns-diameter) agarose colonies had similar self-renewal capacities in agarose and formed variously sized cell colonies when replated in agarose medium. Metastatic potential, drug sensitivity parameters, and expression of a high Mr mucin-like glycoprotein antigen and type IV collagenolytic activity known to be associated with spontaneous metastasis of 13762NF tumor cells were dissimilar in cells from different colonies, and these characteristics were independent of original tumor cell colony size in agarose. In contrast, the expression of cell surface proteins of Mr less than 300,000 were similar among cells derived from different agarose colonies. The data indicate that heterogeneity exists in the ability of 13762NF adenocarcinoma cells of different biochemical and metastatic potentials and drug sensitivities to grow in semisolid agarose. In addition, the cells that grow in agarose to form detectable colonies (greater than 50 cells) are not necessarily those with a high potential of metastasizing spontaneously to distant sites.

Directed migration of murine and human tumor cells to collagenases and other proteases.

Tumor cell motility and the passage of tumor cells through various tissue matrices, including basement membrane, are important components of the metastatic process. Proteolytic enzymes, including a type IV collagen-specific collagenase, have been demonstrated to play a significant role in extracellular matrix and basement membrane degradation. In addition, exogenous collagenase has been shown to enhance the motility of some tumor cells independent of its effect on collagen-containing material. Previous studies have also indicated that collagen fragments are chemotactic for many tumor cells. We therefore studied the effect of type I and type IV collagen-specific collagenases, other enzymes involved in collagenase activation and connective tissue degradation, and subsequent collagen degradation products on the directed migration of tumor cells. We report that type I and type IV collagen-specific mammalian collagenases were potent chemoattractants as were native type I and type IV collagens and collagen fragments. Collagenase inhibitor SC44483 inhibited the type IV collagenase-stimulated migration. Collagenase pretreatment of the tumor cells potentiated the migratory response of the tumor cells to collagen and collagen fragments. The plasminogen activator, urokinase, as well as plasminogen itself also enhanced the directed migration of tumor cells in concentrations that suggest involvement of the appropriate cell surface receptor. The chemotactic response of tumor cells to the proteases studied extends the prior report of a role for collagenases and other matrix-active enzymes in tumor cell behavior in addition to matrix degradation.