Tumor progression in metastasis: an experimental approach using lectin resistant tumor variants

Is cancer progression caused by gradual or simultaneous acquisitions of new chromosomes?

Background

Foulds defined, “Tumor progression (as a) permanent, irreversible qualitative change in one or more of its characters” (Cancer Res. 1954). Accordingly progressions, such as metastases and acquired drug-resistance, were since found to be subspecies of cancers with conserved and numerous new chromosomes. Here we ask whether cancers acquire numerous new chromosomes gradually or simultaneously in progressions. The currently prevailing theory of Nowell (Science, 1976) holds that unexplained “genetic instability” generates “variant sublines (with) changes in chromosome number” and that “clonal” progressions arise by “stepwise selection of more aggressive sublines”. The literature, however, contains many examples of “immediate” selections of progressions with numerous new chromosomes - notably experimentally initiated fusions between cancers and heterologous cells. Furthermore, the stepwise progression theory predicts intermediate sublines of cancers with multiple non-clonal additions of new chromosomes. However, the literature does not describe such intermediates.

Results

In view of these inconsistencies with stepwise progression we test here a saltational theory, in which the inherent variability of cancer-specific aneuploidy generates “immediate” progressions with individual clonal karyotypes, transcriptomes and phenotypes in single steps. Using cell fusion as an established controllable model of “immediate” progression, we generated seven immortal murine hybridomas by fusing immortal murine myeloma cells and normal antibody-producing B-cells with polyethylene glycol within a few minutes. These immortal hybridomas contained individual sets of 71 to 105 clonal chromosomes, compared to the 52 chromosomes of the parental myeloma. Thus the myeloma had gained 19 to 53 new clonal chromosomes in seven individual hybridomas in a single step. Furthermore, no stable intermediates were found, as would be predicted by a saltational process.

Conclusions

We conclude that random fusions between myelomas and normal B-cells generate clonal hybridomas with multiple, individual chromosomes in single steps. Similar single-step mechanisms may also generate the “late” clonal progressions of cancers with gains of numerous new chromosomes and thus explain the absence of intermediates. Latency would reflect the low probability of rare stochastic progressions. In conclusion, the karyotypic clonality of hybridomas and spontaneous progressions suggests karyotypic alterations as proximate causes of neoplastic progressions. Since cancer-specific aneuploidy catalyzes karyotypic variation, the degree of aneuploidy predicts the clinical risk of neoplastic progression, confirming classical predictions based on DNA content.

Cell-cycle fate-monitoring distinguishes individual chemosensitive and chemoresistant cancer cells in drug-treated heterogeneous populations demonstrated by real-time FUCCI imaging

Essentially every population of cancer cells within a tumor is heterogeneous, especially with regard to chemosensitivity and resistance. In the present study, we utilized the fluorescence ubiquitination-based cell cycle indicator (FUCCI) imaging system to investigate the correlation between cell-cycle behavior and apoptosis after treatment of cancer cells with chemotherapeutic drugs. HeLa cells expressing FUCCI were treated with doxorubicin (DOX) (5 μM) or cisplatinum (CDDP) (5 μM) for 3 h. Cell-cycle progression and apoptosis were monitored by time-lapse FUCCI imaging for 72 h. Time-lapse FUCCI imaging demonstrated that both DOX and CDDP could induce cell cycle arrest in S/G2/M in almost all the cells, but a subpopulation of the cells could escape the block and undergo mitosis. The subpopulation which went through mitosis subsequently underwent apoptosis, while the cells arrested in S/G2/M survived. The present results demonstrate that chemoresistant cells can be readily identified in a heterogeneous population of cancer cells by S/G2/M arrest, which can serve in future studies as a visible target for novel agents that kill cell-cycle-arrested cells.

Clonal changes in tumours during growth and progression evaluated by southern gel analysis of random integrations of foreign DNA

We have exploited random integrations of foreign DNA as a means of genetically tagging tumour cell populations with which to analyse the clonal evolution of tumour growth in vivo. Transfection of a non-metastatic mouse mammary carcinoma called SP1 (or a metastatic variant, SP1HU9L) with the pSV2neo plasmid or retrovirus vector infection with a "clipped-wing' vector (delta p delta eMoTN) was used to generate large numbers of uniquely marked tumour cell clones in single-step selections. The basic approach was to pool large numbers of independently marked transfectants or infectants, inject these cells into mice and analyse the resulting primary tumours and/or metastases later. Overgrowth or derivation of tumour masses by a limited number of clones could be detected by Southern gel analysis. The main findings were: (i) injection of pooled populations containing large numbers of uniquely marked cell clones (up to several thousand) invariably resulted in advanced primary tumours that contained a very limited number of clones, and in some cases only one easily detectable clone; (ii) primary tumours could be overgrown within six weeks by the progeny of the same single metastatic clone when the inoculum contained 1-10% metastatic cells, which suggests that metastatic SP1 cells have a selective growth advantage in primary tumours as well as for metastatic spread; and (iii) spontaneous lung metastases were clonal or biclonal at the time of analysis. The results show that spontaneous metastases can develop from a genetically distinct subpopulation of cells in a non-random (i.e. selective) manner. Because primary tumours can become overgrown by the progeny of a metastatic clone, results of any comparison of the properties of a primary tumour with a distant metastasis could be affected by the stage at which the primary tumour is removed and analysed.

Wheatgerm agglutinin-mediated toxicity in pancreatic cancer cells

Lectin binding specificities for carbohydrate allow phenotypic and functional characterization of membrane-associated glycoproteins expressed on cancer cells. This analysis examined wheatgerm agglutinin binding to pancreatic cancer cells in vitro and the resulting toxicity. Membrane preparations of nine human pancreatic carcinoma cell lines were studied for lectin binding using wheatgerm agglutinin (WGA), concanavalin A (ConA) and phytohaemagglutinin-L (PHA-L) in a lectin blot analysis. Cell proliferation in vitro was measured by thymidine incorporation in the absence or presence of lectins at various concentrations. Sialic acid binding lectins or succinyl-WGA (succWGA) served as controls. WGA toxicity was tested after swainsonine or neuraminidase pretreatment. Binding and uptake of fluorescein-labelled lectins was studied under fluorescence microscopy. All pancreatic cell lines displayed high WGA membrane binding, primarily to sialic acid residues. Other lectins were bound with weak to moderate intensity only. Lectin toxicity corresponded to membrane binding intensity, and was profound in case of WGA (ID50 at 2.5-5 microg ml(-1)). WGA exposure induced chromatin condensation, nuclear fragmentation and DNA release consistent with apoptosis. Important steps for WGA toxicity included binding to sialic acid on swainsonine-sensitive carbohydrate and lectin internalization. There was rapid cellular uptake and subsequent nuclear relocalization of WGA. In contradistinction to the other lectins studied, WGA proved highly toxic to human pancreatic carcinoma cells in vitro. WGA binding to sialic acid residues of N-linked carbohydrate, cellular uptake and subsequent affinity to N-acetyl glucosamine appear to be necessary steps. Further analysis of this mechanism of profound toxicity may provide insight relevant to the treatment of pancreatic cancer.

Novel glycosylation-defective baby hamster kidney cells

The plant lectin wheat germ agglutinin (WGA) has previously been used to select more than ten different glycosylation-defective phenotypes in a variety of mammalian somatic cells. Three WGA-resistant phenotypes have now been obtained spontaneously from baby hamster kidney (BHK) cells. These mutant BHK cells exhibit a pattern of cross resistance and sensitivity to multiple plant lectins, suggesting that the cell surface carbohydrates of these cells are altered. Two WGA-resistant BHK phenotypes appear similar to WGA-resistant CHO cells that lack terminal sialic acid and galactose residues on their cell surface carbohydrates. The third WGA-resistant BHK cell phenotype has not previously been seen in WGA-resistant mammalian cells.

Characterization of deoxyguanosine-resistant hypoxanthine-guanine phosphoribosyltransferase(-)metastatic variants altered in soybean-agglutinin-binding properties and cell-surface glycoproteins

The isolation of deoxyguanosine-resistant 10T1/2 mouse cell lines following stepwise selection in the presence of increasing concentrations of drug led to the identification of a highly metastatic line, as measured by the ability to form secondary tumors in syngenic mice after intravenous injection. This metastatic deoxyguanosine-resistant mutant was determined to be deficient in hypoxanthine-guanine phosphoribosyltransferase activity, accounting for the resistance to deoxyguanosine. Lectin-binding studies determined that the metastatic potential of high- and low-metastatic revertant clones of this deoxyguanosine-resistant mutant was negatively correlated to soybean agglutinin binding, but not to concanavalin A or wheat germ agglutinin binding. Examination of labelled cell-surface glycoproteins led to the identification of two glycoproteins, gp80 and gp48, which were present on the low-metastatic wild-type cell line but absent from the highly metastatic drug-resistant cells. Our studies suggest that these cell-surface glycoprotein alterations play a role in determining the malignant properties of the cells, and indicate that metastatic variants with the properties described in this report would be useful biological tools for investigations into the roles played by specific cell-surface structures in mechanisms of tumor progression.

Host and tumour factors in cancer metastasis

The process of cancer metastasis is sequential and selective and contains stochastic elements. The growth of metastases represents the endpoint of many lethal events that only few tumour cells survive. Primary tumours contain cells with heterogeneous metastatic properties, and the outcome of metastasis depends on the interplay of tumour cells with various host factors. Collectively, then, our studies and most data reported by others have led us to conclude that metastasis is a highly selective process regulated by a number of mechanisms. This belief is contrary to the once widely accepted notion that neoplastic dissemination is the ultimate expression of cellular anarchy. In fact, suggesting that cancer metastasis is a selective process is a more optimistic view in terms of cancer therapy than the one that contends that tumour dissemination is an entirely random event. A selective biological process is regulated by the interaction of tumour cells with their host, and these complex interactions can be studied and manipulated. A better understanding of the complexity of the processes of tumour evolution, progression, and metastasis should lead to improvements in the treatment of cancer.

Lectin-resistant variants of mouse Lewis lung carcinoma cells. I. Selection and in vivo properties

The availability of lectin-resistant cell lines with altered carbohydrate moieties in cell surface glycoproteins and glycolipids has greatly facilitated study of the involvement of cellular glycoconjugates in tumor growth and metastasis. We present here a new animal model for metastasis study based on mouse Lewis lung carcinoma LL2 in vitro cell line. From this line, five lectin-resistant variant sublines were selected with the following lectins: wheat germ agglutinin (WGAR), Ricinus communis agglutinin II (RCA IIR) and Aleuria aurantia agglutinin (AAAR). The correlation of the lectin resistance with their in vitro and in vivo growth properties, and especially lung colonizing ability, were investigated. Three WGAR variants with well-preserved tumorigenicity revealed reduced metastatic ability, both spontaneous, after subcutaneous (s.c.) administration and experimental, after intravenous (i.v.) administration. The RCA IIR variant also possessed reduced spontaneous and experimental metastatic ability, but exhibited higher growth rate of local s.c. tumors. The AAAR variant possessed reduced spontaneous metastatic ability but its ability to colonize the lungs after i.v. administration was five-fold higher than that of the parent LL2 line, whereas its tumorigenicity remained unchanged. The relative differences among WGAR variants and parent LL2 line, concerning their experimental metastatic ability, remained similar in cyclophosphamide-modified mice to those in normal recipients.

Origin and biology of cancer metastasis

Metastasis, the spread of cells from a primary neoplasm to distant sites where they grow, contributes to the death of most cancer patients. The process of metastasis is not random. Rather, the process consists of a series of linked, sequential steps that must be completed by tumor cells if a metastasis is to develop. Thus, metastatic cells must succeed in invasion and embolization, survive in the circulation, arrest in a distant capillary bed, and extravasate into and multiply in organ parenchyma. Although some of the steps in this process contain stochastic elements, as a whole metastasis favors the survival and growth of a few subpopulations of cells that preexist within the parent neoplasm. Moreover, metastases can have a clonal origin, and different metastases can originate from the proliferation of single cells. The outcome of metastasis depends on the interaction of metastatic cells with different organ environments. Organ-specific metastases have been demonstrated in a variety of experimental tumor systems, and even within one organ, site-specific tumor growth can be found. The conclusion that metastasis is a highly selective process that is influenced by both the intrinsic properties of tumor cells and by host factors is optimistic. A selective process is regulated and therefore can be studied and then manipulated.

Chinese hamster ovary cell mutants with multiple glycosylation defects for production of glycoproteins with minimal carbohydrate heterogeneity

The production of glycoproteins with carbohydrates of defined structure and minimal heterogeneity is important for functional studies of mammalian carbohydrates. To facilitate such studies, several Chinese hamster ovary mutants that carry between two and four glycosylation mutations were developed. All of the lines grew readily in culture despite the drastic simplification of their surface carbohydrates. Therefore, both endogenous glycoproteins and those introduced by transfection can be obtained with specifically tailored carbohydrates. The lectin resistance properties of the mutants showed that each line expresses a novel array of cell surface carbohydrates useful for identifying specific roles for carbohydrates in cellular interactions. In addition, they showed that the epistatic relationships among different glycosylation mutations are not entirely predictable, providing insight into the complexity of the carbohydrate structures at the Chinese hamster ovary cell surface.

Different class I antigen oligosaccharides on a murine tumor and a lectin-resistant variant are not responsible for the differential recognition of the tumors by CTL

Previous studies have shown that whereas a highly malignant mouse cell line termed MDAY-D2 (d haplotype) does not elicit a detectable response by cytotoxic T lymphocytes (CTL) in DBA/2 mice, strong anti-tumor CTL are generated against a wheat-germ-agglutinin-resistant variant, designated MDW3. Additional evidence suggests these anti-MDW3 CTL may not be a consequence of a unique antigenic determinant on the variant cells. Because MDW3 cells are expected to differ from MDAY-D2 cells in their surface carbohydrate structures (due to their lectin resistance) and Class I major histocompatibility molecules play a crucial role in CTL-mediated responses, we speculated that the Asn-linked oligosaccharides present on Class I molecules of MDAY-D2 and MDW3 might be different and could potentially influence recognition analyses and Con A-Sepharose affinity chromatography clearly demonstrated that the oligosaccharides isolated from the H-2Dd molecule of MDAY-D2 cells are larger and more highly branched than those of the MDW3 variant. Taken together with the finding that anti-MDW3 CTL are restricted by H-2Dd, these results suggested that the larger H-2Dd oligosaccharides on MDAY-D2 cells could potentially mask or perturb determinants required for recognition by these CTL. To test this postulate, the surface Class I oligosaccharides of both MDAY-D2 and MDW3 cells were converted to simpler hybrid structures by treatment with the oligosaccharide processing inhibitor, swainsonine. However, no effect was observed on the lysis or binding of either MDAY-D2 or MDW3 cells by anti-MDW3 CTL. Thus, the results do not support the possibility that the larger H-2Dd oligosaccharides on MDAY-D2 cells are, in themselves, responsible for the poor recognition of the parent tumor by anti-MDW3 CTL. Our data do indicate, however, that CTL target binding and effector functions are not dependent on the fine structure of complex Asn-linked carbohydrates present on Class I molecules and possibly on other, accessory molecules at the target cell surface, since MDW3 cells maintained their sensitivity to lysis by CTL following swainsonine treatment.

Interactions between cancer cells and the microvasculature: a rate-regulator for metastasis

Hematogenous metastasis is a major consideration in the staging, treatment and prognosis of patients with cancer. Key events affecting hematogeneous metastasis occur in the microvasculature. This is a brief, selective review of some interactions involving cancer cells and the microvasculature in pathologic sequence, specifically: (1) intravasation of cancer cells; (2) the arrest of circulating cancer cells in the microvasculature; (3) cancer cell trauma associated with arrest; (4) microvascular trauma; (5) the inflammatory; and (6) the hemostatic coagulative responses associated with arrest, and finally (7) angiogenesis, leading to tumor vascularization. The evidence shows that through a series of complex interactions with cancer cells, the microvasculature acts as a rate-regulator for the metastatic process, in addition to providing routes for cancer cell dissemination and arrest sites for cancer cell emboli.

Chinese hamster ovary cell mutants with multiple glycosylation defects for production of glycoproteins with minimal carbohydrate heterogeneity

The production of glycoproteins with carbohydrates of defined structure and minimal heterogeneity is important for functional studies of mammalian carbohydrates. To facilitate such studies, several Chinese hamster ovary mutants that carry between two and four glycosylation mutations were developed. All of the lines grew readily in culture despite the drastic simplification of their surface carbohydrates. Therefore, both endogenous glycoproteins and those introduced by transfection can be obtained with specifically tailored carbohydrates. The lectin resistance properties of the mutants showed that each line expresses a novel array of cell surface carbohydrates useful for identifying specific roles for carbohydrates in cellular interactions. In addition, they showed that the epistatic relationships among different glycosylation mutations are not entirely predictable, providing insight into the complexity of the carbohydrate structures at the Chinese hamster ovary cell surface.

Generation of adhesive tumor variants: chromosomal changes, reduction in malignancy and increased expression of a distinct membrane glycoprotein

Tumor cell variants which grow adherent to a plastic surface could be isolated in a reproducible way from the high metastatic tumor cell line ESb which grows in a suspension culture. This occurred when starting selection from the uncloned parental line as well as from a freshly derived non-adhesive subclone. The variants showed changes in their karyotype. These were quantitative (tetraploidization) and qualitative (single chromosome aberrations involving the chromosomes 12 and 17 and a marker MX-7). Phenotypic cell surface changes were documented in vitro by immunofluorescence using a monoclonal antibody (mAb 12-15) directed against a distinct plasma membrane glycoprotein of 60-69kD (gp 60-69). The expression of gp 60-69 increased with time of selection for adherence to plastic surface. The adherent cells showed in all cases a greatly reduced overall malignancy as seen by a prolonged survival time of respective tumor bearing animals compared with the suspension growing parental cells.

Oncogene expression in related cancer lines differing in metastatic capacity

Various murine tumor cell lines with different metastatic capacities were tested in vitro for oncogene expression, especially of the p21-Ha-ras protein. Small differences were seen in the expression of several distinct oncogenes in the case of a high metastatic lymphoma variant (ESb) and its low metastatic parental line (Eb). In one instance we observed a 30-fold Ha-ras gene amplification in a metastasis-derived cell line from a spontaneous mouse mammary carcinoma. In spite of this amplification we did not find an increased p21 expression in these cells.

Lewis lung carcinoma (3LL) cells treated in vitro with ultraviolet radiation show reduced metastatic ability due to an augmented immunogenicity

The metastatic ability of 3LL tumor following in vitro irradiation with ultraviolet (u.v.) light was studied. Tumor cells were exposed to two courses of u.v.-irradiation (3LL X 2u.v. cells) and after two weeks of culture they were inoculated intravenously (i.v.) into syngeneic mice. These cells produced significantly fewer pulmonary metastases than the untreated population. In addition, intrafootpad (i.f.p.) injections of 3LL X 2u.v. cells into immunocompetent animals induced tumors only in 40 per cent of recipients. Interestingly, in normal mice with progressively growing 3LL X 2u.v. tumors, the formation of spontaneous pulmonary metastases was prevented, whereas metastatic foci were observed in 70 per cent of the nude recipients. The metastatic properties of u.v.-treated tumor cells were further analysed by using individual clones with varying immunogenicity. We found that variants with augmented immunogenicity also showed a parallel decrease in metastatic potential. Studies on H-2 antigen expression in different clones revealed that immunogenic and low metastatic variants expressed levels of H-2 antigens higher than the tumorigenic and metastatic clones. Finally, by using cyclophosphamide (Cy) treatment and adoptive transfer of immune spleen cells were able to eradicate macroscopic 3LL pulmonary metastasis. These results demonstrate that the decrease of metastatic ability in u.v.-treated cells was mainly due to an increase in their immunogenicity and H-2 antigen expression.

Tumor cell surface carbohydrate and the metastatic phenotype

The synthesis and expression of cell surface carbohydrates is a developmentally regulated process that appears to affect a number of cell-cell interactions. To determine whether specific oligosaccharide structures present on highly malignant cells are required for expression of the metastatic phenotype, we have isolated lectin resistant tumor cell mutants with defects in the biosynthesis of oligosaccharides. The mutants selected from the highly aggressive lymphoreticular-like tumor line MDAY-D2 were grouped into genetic complementation classes, compared for metastatic ability and for changes in cell surface glycoconjugates. The Asn-linked oligosaccharides and glycolipids of class 1 mutants were deficient in both sialic acid and galactose and the cells showed a greatly attenuated metastatic phenotype compared to the parental cells. A revertant of the class 1 mutation selected in vitro regained the wild type glycoconjugate profile and the highly metastatic phenotype indicating a direct association between the mutation and the loss of metastatic potential. Class 2 mutants remained highly metastatic and had Asn-linked oligosaccharide structures very similar to those found in the wild type cells with N-glycolylneuraminic acid rather than the N-acetylneuraminic acid. Swainsonine, an inhibitor of golgi alpha-mannosidase II, blocks the synthesis of complex-type Asn-linked oligosaccharides resulting in the expression of hybrid-type oligosaccharides at the cell surface and the cells display a lectin resistant phenotype. Although swainsonine inhibited neither tumor cell growth in vitro nor solid tumor growth in situ, the drug dramatically reduced the incidence of lung colonies after i.v. inoculation of both MDAY-D2 and B16F10 melanoma cells. These results, taken together, indicate that certain sialylated Asn-linked oligosaccharides found on metastatic tumor cells are required for expression of the metastatic phenotype.

DNA stemline heterogeneity in colorectal cancer

The current study was carried out on 88 colorectal carcinomas to assess the degree of intratumor heterogeneity as reflected by multiple aneuploid DNA stemlines and their relation to tumor stage and morphologic differentiation. Each tumor was segregated into an average of nine specimens (3-15), which were analyzed separately. DNA aneuploidies were identified in 72 cases (82%), 29 revealing multiple aneuploid DNA stemlines with up to four aneuploid subpopulations. In 10 of the 29 carcinomas with DNA stemline heterogeneity, a ratio of 2:1 was calculated from the different DNA indices, possibly indicating that the additional DNA stemline emerged from the first one by doubling its DNA content. No correlation was found between the overall frequency of DNA aneuploidies or heterogeneous DNA stemlines and the tumor stage according to Dukes' staging. Well-differentiated carcinomas tended to express aneuploid DNA stemlines more frequently than moderately or poorly differentiated tumors, although the morphologic intratumor heterogeneity did not correspond to the appearance of multiple aneuploid DNA stemlines. These data indicate a high degree of intraneoplastic diversity in colorectal cancer and emphasize the usefulness of DNA analyses for the quantitative assessment of tumor heterogeneity.

Sporadic somatic fusion between MDAY-D2 murine tumor cells and DBA/2 host cells: role in metastasis

An ouabain- and 6-thioguanine-resistant mutant (K3T103) of the metastatic MDAY-D2 murine tumor cell line was transplanted s.c. into syngeneic DBA/2 mice in order to isolate K3T103 X host cell hybrids emerging in vivo, and examine their metastatic potential. Of 10 tumor-bearing animals that were analyzed at various time intervals, only 3 developed fusion products in the primary site, present at a frequency ranging between 10(-5) and 10(-4). These hybrids survived in HAT + ouabain medium, had a lymphoblastoid morphology and a hypo-tetraploid karyotype, were non-adherent, and were as rapidly metastatic as K3T103 cells when transplanted s.c. or i.v. into DBA/2 mice. All these characteristics were shared by cloned hybrids generated in vitro following polyethylene glycol (PEG)-mediated fusion of K3T103 cells with normal DBA/2 normal splenocytes. In marked contrast, the products of K3T103 X DBA/2 normal lung fibroblast fusion displayed a fibroblastic appearance, were adherent, progressively ceased to divide and remained dormant for several weeks in culture. These results indicate: that spontaneous fusion of K3T103 cells with host cells in the course of their expansion and subsequent dissemination is a stochastic and rare event, and that since the expression of their tumorigenic and metastatic potential is retained after fusion with splenocytes, host cells of lymphoreticular origin are most likely involved in that process.

Biochemical regulation of adenylate cyclase in murine melanoma clones with different metastatic properties

The regulation of adenylate cyclase in murine melanoma tumor cell clones with different metastatic capacities has been studied in intact cells and isolated membrane preparations. Analysis of the responses of intact cells from a number of B16 melanoma clones revealed that treatment with melanocyte-stimulating hormone (MSH) or the diterpene, forskolin, produced significantly greater accumulation of intracellular cyclic adenosine 3',5' monophosphate (cAMP) in strongly metastatic clones than in weakly metastatic tumor cell clones. In contrast, in isolated membranes from the same panel of clones, the extent of activation by forskolin but not by MSH correlated with metastatic capacity. Sodium fluoride and 5'-guanyl-beta-gamma-imidodiphosphate [Gpp(NH)p] also stimulated adenylate cyclase in isolated membranes but the extent of activation did not correlate with the metastatic behavior of the donor cells. A combination of forskolin and Gpp(NH)p proved to be a sensitive prospective indicator for identifying differences in the metastatic capabilities of individual B16 melanoma clones. Adenylate cyclase in membrane preparations from strongly metastatic B16 clones displayed synergistic activation but stimulation of the enzyme from weakly metastatic clones was less than additive. To test the generality of these findings, similar investigations were performed on B16-BL6 melanoma cells, a highly invasive subline of the B16 melanoma, and the K1735, an ultraviolet-light-induced murine melanoma arising in a different mouse strain (C3H). Consistent with their high metastatic potential, clones derived from the B16-BL6 melanoma displayed elevated levels of hormonally-stimulated adenylate cyclase, thereby confirming, for this tumor system, a close association between hormonal responsiveness and metastatic capacity. In contrast, K1735 melanoma cell clones exhibited significant interclonal variation in adenylate cyclase activity and metastatic performance, but no consistent relationship between the two traits was detected. Differences in the regulation and/or the intrinsic catalytic capacity of adenylate cyclase may account, at least in part, for the variation in hormonal responsiveness observed among B16 clones with distinct metastatic properties and suggest that cAMP-dependent molecular processes may be required for the expression of B16 melanoma experimental metastatic potential.(ABSTRACT TRUNCATED AT 400 WORDS)

The role of tumor-cell surface carbohydrate in experimental metastasis

Quantitative studies on the binding of concanavalin A (Con A) and wheat-germ agglutinin (WGA) to a series of rat hepatocarcinoma metastatic variants revealed a positive correlation between the amount of cell-surface-bound lectin and lung colonization potential. Scatchard analysis of Con A and WGA binding to 10 individual clones isolated from a subcutaneous (s.c.) tumor transplant and to tumor-cell isolates from 10 individual spontaneous lung metastases from the same animal showed diverse binding characteristics for these cell populations. Nevertheless, the expression of Con A receptor sites accurately predicted the lung colonization potential of 3 isolates from the lung metastases. Higher lectin binding curves were observed for the clones from the subcutaneous tumor than for the isolates from lung metastases. These data suggest that a high Con-A binding potential is indicative of a high lung colonization potential for these hepatocarcinoma cells, but that this phenotype may be rapidly lost during tumor outgrowth in the lungs. The binding of tumor cells to vascular endothelial cell monolayers was inhibited in the presence of Con A; however, no inhibition was observed with 2 other lectins. Attachment of tumor cells to endothelial cell monolayers was also inhibited by the monosaccharides methyl alpha-D-mannopyranoside and N-acetyl-D-galactosamine. Other monosaccharides tested did not alter the attachment of tumor cells to endothelial cell monolayers.

Development of highly immunogenic variants of a rat fibrosarcoma line during in vitro cultivation

Rat fibrosarcoma KMT-17 cells decreased in tumorigenicity when cultured in vitro. Eight clones derived from cultured KMT-17 cell lines (c-KMT-17) were examined for their tumorigenicity, immunosensitivity, and immunogenicity. All the clones were less or nontumorigenic in normal syngeneic rats than KMT-17 cells maintained in vivo. All eight clones produced tumors in rats immunosuppressed with 600 rad 60Co; differences in degree of tumorigenicity were seen among clones in rats irradiated with 250 rad 60Co. Although immunosensitivity of the eight clones to complement-dependent and cell-mediated cytotoxicity was the same or less than that of KMT-17 cells, al leight clones induced greater transplantation resistance to KMT-17 than KMT-17 itself. Cold target inhibition tests demonstrated new antigens in a highly immunogenic variant in addition to the original tumor associated antigen (TAA). New glycolipids, not observed in KMT-17 cells, were demonstrated in the clones by thin layer chromatography. These results suggest that new antigens appearing during culture of KMT-17 may act as helper antigens for TAA, increasing the immunogenicity and decreasing the tumorigenicity of the cultured cells.

The use of hybridoma cells as a murine model to study tumor immunity

The secretion of antibody by hybridoma cells allows the growth of individual cells to be measured by a hemolytic plaque assay. Similarly, plaque reduction assays were sensitive indicators of tumor immunity. A series of strains of hybridoma have been isolated from an original isolate which is sensitive to cytotoxic T cells and NK cells. In the derivation of a spleen-seeking variant, the cells appear to have lost immunogenic but not antigenic characteristics. This model lends itself to the quantitative study of immune constraints on tumor growth in vivo. Combined with the selection of tumor variants, the model is of wide application to many fields of tumor biology, particularly where sensitive measurement of tumor cell number and viability is crucial.

Quantitative genetic analysis of tumor progression

Metastasis and resistance to chemotherapy are common features of progressed cancers. With respect to the latter phenotype, it is thought that during tumor growth drug-resistant cells arise spontaneously at rates characteristic of the genetic alterations involved. On application of chemotherapy, such variant tumor cells are more likely to survive, and they may eventually dominate, resulting in a non-responsive malignancy. Aspects of this model have been confirmed in a number of experimental systems and in patients. In contrast to our understanding of drug resistance, steps involved in the progression to metastatic spread of tumor cells are much less well-understood. In this review we describe methodologies of quantitative genetic analysis with reference to development of drug resistance. We then describe attempts by ourselves and others to use a similar approach to investigate metastatic properties. Based on these studies, we have proposed the quantitative 'dynamic heterogeneity' model of tumor metastasis, which is presented here. Using an 'experimental' metastasis assay and Luria-Delbruck fluctuation analysis, we determined that in murine KHT fibrosarcoma and B16 melanoma lines, 'metastatic' variants with a distinct phenotype are generated at high rates. These variants are relatively unstable resulting in a dynamic equilibrium between generation and loss of metastatic variants. The metastatic ability of such a tumor population is thus dependent on the frequency of a subpopulation of metastatic variants which are turning over rapidly. This dynamic heterogeneity model is able to quantitatively provide a unifying explanation for a wide range of observations concerning tumor heterogeneity and clonal instability. Genetic mechanisms involving rapid rates have been characterized in drug-resistant variants. We speculate that similar processes may be involved in different aspects of tumor progression such as those resulting in metastasis.

Cancer metastasis: experimental approaches, theoretical concepts, and impacts for treatment strategies

It has been the purpose of this article to describe recent advances in cancer metastasis research. Clinical realities and experimental approaches to the study of underlying basic mechanisms of metastasis formation were discussed. Wherever possible, results were reported which led to the development of theoretical concepts. Such results and concepts were finally evaluated in light of their possible impact for the design of new treatment strategies. Experimental findings from many diverse research fields were summarized with the help of tables, figures, and references. It was concluded that the process of metastasis is a dynamic event that can be described as a sequence of interrelated steps. Experimental results indicated that malignant cells that migrate and disseminate from the primary organ to distant sites and there eventually develop into metastases have to survive a series of potentially lethal interactions. Intimate tumor-host interactions were reported to take place all along the metastatic process. They were elucidated at the steps of angiogenesis, invasion, organ interaction, dormancy, tumor rejection, and tumor immune escape. The outcome of such tumor-host interactions seemed to depend on intrinsic properties of the tumor cells themselves as well as on the responsiveness of the host. Metastasis does not appear as a merely random process. Both clinical and experimental studies revealed that the whole process can be described more appropriately in terms of stochastic, sequential, and selective events, each of which is controlled and influenced by a number of mechanisms. With regard to therapeutic intervention, a selective event offers more possibilities than a random one because it is governed by rules that can be exploited experimentally. Various impacts from experimental studies for the design of antimetastatic cancer treatment strategies were discussed. Sequential steps of the metastatic cascade could become new therapy targets. Conventional empirically derived treatment modalities should become flanked by methods aimed more specifically at critical steps of cancer spread in order to prevent progression of the disease. This is where basic research on mechanisms could make significant contributions to therapy planning in the future. Furthermore, possible negative effects of surgery, radiotherapy, and adjuvant chemotherapy or immunotherapy that could result in enhancement of metastatic progression need to be critically evaluated to limit them as much as possible.(ABSTRACT TRUNCATED AT 400 WORDS)

Adoptive immune therapy in mice bearing poorly immunogenic metastases, using T lymphocytes stimulated in vitro against highly immunogenic mutant sublines

MDW3, a highly immunogenic and non-tumorigenic (tum-) mutant of the poorly immunogenic metastatic murine tumor called MDAY-D2, has been employed in an immune therapy scheme for the treatment of widespread established visceral MDAY-D2 metastases in syngeneic mice. MDW3 was selected from a mutagenized population of MDAY-D2 cells for the ability to grow in the presence of toxic concentrations of wheat-germ agglutinin (WGA) in vitro. The mutant expresses a common tumor-associated antigen (TAA) present on MDAY-D2 as well as a new antigen whose presence enhances the anti-TAA cell-mediated immune response in vivo and in mixed lymphocyte tumor cultures (MLTC) in vitro. For immune therapy, spleen cells from DBA/2 mice which had rejected an inoculum of MDW3 cells were restimulated in MLTC and injected i.v. into MDAY-D2 tumor-bearing mice. Two protocols were used. In the first, mice were given an i.v. injection of 10(3) MDAY-D2 cells ("artificial metastasis") and subsequently treated with 400 R whole-body irradiation and MDW3-stimulated T cells. Such mice had a 75% long-term survival rate, whereas 400 R alone, or no treatment, resulted in 25% and 0% long-term survivors, respectively. In the second protocol, treatment of mice bearing a 12-day-old subcutaneous MDAY-D2 tumor by surgical removal of the solid tumor, 400 R whole-body irradiation, and systemic administration of MDW3-stimulated spleen cells, resulted in a 75-100% survival rate, whereas omitting any part of the treatment resulted in 0-50% survival rates. The treatment increased splenic anti-TAA CTL activity, and the mice acquired immunity against the new antigen on MDW3, suggesting that the injected lymphocytes were proliferating in the host. The optimal combination of resection, whole-body irradiation and passive infusion of MDW3-stimulated spleen cells was ineffective when used on mice bearing a tumor-antigen-loss variant of MDAY-D2, suggesting that success of our immune therapy protocol required specific recognition of the tumor-associated antigen of MDAY-D2.

Asparagine-linked oligosaccharides in murine tumor cells: comparison of a WGA-resistant (WGAr) nonmetastatic mutant and a related WGA-sensitive (WGAs) metastatic line

MDW40, a wheat germ agglutinin-resistant (WGAr) mutant of the highly metastatic tumor cell line called MDAY-D2, is restricted to local growth at the subcutaneous site of inoculation. The WGAr tumor cells acquire metastatic ability by fusing spontaneously with a normal host cell followed by chromosome segregation, a process accompanied by reversion of the WGAr phenotype (i.e., WGAs). Since lectin-resistant mutant cell lines often have oligosaccharide alterations that may affect membrane function and consequently metastatic capacity, we compared the major Asn-linked glycopeptides in WGAr and WGAs cell lines. [2-3H]mannose-labeled glycopeptides were separated into four fractions on a DEAE-cellulose column and then further fractionated on a concanavalin A-Sepharose column. Glycopeptide structures were determined by: (a) sequential exoglycosidase digestion followed by chromatography on lectin/agarose and Bio-Gel P-4 columns and (b) proton nuclear magnetic resonance analysis. The metastatic WGAs cells had a sialylated poly-N-acetyllactosamine-containing glycopeptide which was absent in the nonmetastatic mutant cell line. Unique to the mutant was a neutral triantennary class of glycopeptide lacking sialic acid and galactose; the WGAr lesion therefore appeared to be a premature truncation of the antennae of the poly-N-acetyllactosamine-containing glycopeptide found in the WGAs cells. High mannose glycopeptides containing five to nine mannose residues constituted a major class in both WGAr and WGAs cells. Lysates of both wild-type and mutant cells had similar levels of galactosyltransferase activity capable of adding galactose to the N-acetylglucosamine-terminated glycopeptide isolated from mutant cells; the basis of the WGAr lesion remains to be determined.

Identification of asparagine-linked oligosaccharides involved in tumor cell adhesion to laminin and type IV collagen

MDW4, a wheat germ agglutinin-resistant nonmetastatic mutant of the highly metastatic murine tumor cell line called MDAY-D2 has previously been shown to attach to fibronectin and type IV collagen, whereas MDAY-D2 and phenotypic revertants of MDW4 attached poorly to these substrates. The increased adhesiveness of the mutant cells appeared to be closely related to a lesion in cell surface carbohydrate structures. In an effort to identify the carbohydrates involved in cell attachment, glycopeptides isolated from mutant and wild-type cells as well as from purified glycoproteins were tested for their ability to inhibit the attachment of MDW4 cells to plastic surfaces coated with fibronectin, laminin, or type IV collagen. The addition of mannose-terminating glycopeptide to the adhesion assay inhibited MDW4 cell attachment to type IV collagen. In contrast, a sialylated poly N-acetyllactosamine-containing glycopeptide, isolated from wheat germ agglutinin-sensitive MDAY-D2 cells but absent in MDW4 cells, inhibited MDW4 attachment to laminin. None of the glycopeptides used in this study inhibited attachment of MDW4 cells to fibronectin-coated plastic. Peptide N-glycosidase treatment of the cells to remove surface asparagine-linked oligosaccharides inhibited MDW4 adhesion to type IV collagen, but not to laminin, and the same treatment of the wheat germ agglutinin-sensitive cells enhanced attachment to laminin. Tumor cell attachment to, and detachment from, the sublaminal matrix protein laminin and type IV collagen are thought to be important events in the metastatic process. Our results indicate that tumor cell attachment to these proteins may be partially modulated by the expression of specific oligosaccharide structures associated with the cell surface.

Metastatic properties of distinct phenotypic classes of lectin-resistant mutants isolated from murine MDAY-D2 cell line

Single-step mutants were isolated from the murine metastatic MDAY-D2 cell line after selection in toxic concentrations of wheat-germ agglutinin. They were partially characterized by measuring their relative level of resistance to WGA, PHA, Con A, RIC, and LCA (Lec phenotype), and by comparing their karyotype and their ability to produce metastases upon transplantation into syngeneic DBA/2 mice. Based on their Lec phenotype, a total of 19 independent isolates were ranked into 10 distinct classes. Among them, two EMS-induced mutants were nontumorigenic (Lec II, Lec III), one nonmetastatic (Lec IV), and one spontaneous mutant (Lec I) failed to produce blood-borne metastases. Other spontaneous mutants belonging to Lec I, Lec II, and other classes were as metastatic as their parents. The Lec IV phenotype was found to segregate independently from metastatic potential in somatic hybrids. Metastatic ability was recovered in mutants expressing the Lec IV phenotype, after further selection for resistance to RIC. Our results strongly suggest that the loss or reduction of the invasive property of tumor cells is associated with only few Lecr1 phenotypes and, therefore, that a restricted number of cell surface glyconjugates are essential for this particular function.

Characterization of in vitro immunoselected variants from a highly metastatic murine tumor for alterations in malignant behavior in vivo

A new Ly-6.2- antigen-loss variant (called L61 -M1) of the highly metastatic DBA/2 mouse (Ly-6.2+) MDAY-D2 tumor has been obtained by means of a monoclonal anti-Ly-6.2 antibody in an in vitro immunoselection technique. Whereas L61 -M1 grew poorly when inoculated subcutaneously into the syngeneic host, it grew and metastasized in a similar way to the parental MDAY-D2 tumor when inoculated into immunosuppressed, athymic nude mice. L61 -M1 as well as another Ly-6.2- variant of the same MDAY-D2 tumor (called L61 ) which is poorly metastatic in the syngeneic host salvaged exogenous fucose into glycoproteins and glycolipids at rates 5.5 and 7.8 times that of the parental MDAY-D2 line. In contrast, the Ly-6.2- variants exhibited a 50-70% decrease in the incorporation of exogenous mannose into glycoproteins and glycolipids. L61 -M1 and L61 also exhibited alterations in the structures of the oligosaccharide moieties linked to the cell surface glycoproteins and/or glycolipids. Thus, the in vitro immunoselection technique can be used to obtain a panel of variants with stable phenotypic alterations in their growth and metastatic capacities. Such mutants may, like previously described lectin-resistant mutants, be useful in studying the contribution of cell surface glycoproteins and glycolipids to tumorigenicity and metastasis.

Nonmetastatic tumor cells acquire metastatic properties following somatic hybridization with normal cells

Somatic cell hybridization between nonmetastatic tumor cells and normal cells of the lymphoreticular system results in hybrid cells manifesting metastatic properties of defined target organ specificity. Thus, fusion of the nonmetastatic BALB/c originated NSI plasmacytoma with C57BL B lymphocytes resulted in hybridomas, each of which were metastatic. Of 10 hybridomas, 7 generated metastases in the spleen and liver, whereas 3 generated liver metastases. The generation of liver metastases by hybridomas which homed to both spleen and liver, but not by those which homed to the liver only, was controlled by the spleen. The acquisition of metastatic properties via somatic cell fusion seems to represent a general principle, in which the normal partner determines the target organ specificity for the metastatic growth. Thus, fusion of SP2/O myeloma cells with syngeneic B lymphocytes also resulted in a hybrid cell metastasizing to the spleen and liver, yet a somatic hybrid between NSI and a macrophage or dendritic-like cell metastasized to the lung. Cell surface molecules encoded by the genome of the normal partner was demonstrated to control the target organ specificity: antibodies against MHC-encoded antigens of the normal B cell partner prevented the generation of metastases by hybridomas metastasizing to the spleen and liver, but not by those metastasizing to the liver only. This is in accordance with the function of MHC molecules on lymphocytes in controlling their homing to lymphoid organs. Hybridomas of T cell lymphomas also manifested metastatic properties. Analysis of the cell surface Thy-1 antigens of a hybridoma (DCH10), produced via somatic fusion between BW5145 lymphoma and a putative macrophage cell indicated that cells of liver metastases (DCH10-Li) generated by the hybrid cells might have undergone further somatic cell fusion in vivo with host (T?) cells. These cells have acquired new metastatic properties, generating metastases in spleen, liver and kidneys. In fact, even the inoculation of the parental BW lymphoma cells resulted in a case of liver metastasis (BW-Li). Such BW-Li cells, upon reinoculation, also generated metastases in the spleen, liver and kidneys. Analysis of the Thyl phenotype indicated that BW-Li cells may also have undergone somatic cell fusion in vivo with host (T?) cells, resulting in the acquisition of metastatic properties. The pattern of cell-cell interactions (adhesion, infiltration) with liver cell monolayers of BW-Li cells and of DCH10-Li (T-cell lymphomas) was identical, and differed from cells of liver metastases of the myeloma-B cell hybridomas which might be based on responses to liver growth signals.(ABSTRACT TRUNCATED AT 400 WORDS)

Neoplastic cells as targets of spontaneously cytotoxic lymphocytes: studies with natural killer-like cell lines

Native natural killer (NK) cells comprise a heterogeneous family of lymphocytes distributed among several organs, which display spontaneous cytotoxic reactions directed against a broad range of tumor targets. In these studies, murine cell lines have been established in vitro following the selective expansion of bone marrow- and spleen-derived killer progenitors in culture medium supplemented with interleukin-2. Several clones of independent origin have been characterized in order to determine the extent of their phenotypic and functional diversity. With few exceptions most of them were found to be highly effective in lysing a variety of tumor cell lines, to share common cell surface alloantigens, lectin-binding receptors, and cytochemical markers. The presence of prominent azurophilic cytoplasmic granules is the most characteristic ultrastructural feature of these cells. In attempting to elucidate the nature of membrane components specifically recognized by NK cells we compared several isogenic tumor cell variants selected on the basis of their differential NK susceptibility, immunogenicity, metastatic potential or resistance to cytotoxic plant lectins. Sialylated glycoconjugates exposed on the external face of the tumor cell membrane appear to be essential determinants in the interaction between NK cells and their targets. Permanent cell lines retaining most of the functional attributes of endogenous NK cells may prove instrumental in understanding their role during tumor progression.

Cell surface molecules and tumor metastasis. Regulation of metastatic phenotypic diversity

Metastatic tumor cells are characterized by quantitative alterations in cell surface and other properties that confer to these cells their abilities to invade, disseminate, implant, survive and grow at secondary sites. Metastasis is also determined by a variety of host factors that prevent, allow or even stimulate metastatic processes. The emergence of diversified cell subpopulations in malignant tumors insures that some cells will ultimately become highly metastatic, resulting in tumor progression towards characteristics which are the most favorable for survival and growth. Unknown mechanisms appear to stimulate and then to control phenotypic diversification of tumor cell subpopulations. These mechanisms may be altered by genetic (mutational) and/or epigenetic (non-mutational) modifications that individually influence cells within a malignant neoplasm.

Lectin-resistant CHO cells: selection of new mutant phenotypes

Cytotoxic plant lectins select for mutants which exhibit unique structural changes in surface carbohydrates reflecting specific defects in glycosylation reactions. However, lectins are not highly specific selective agents and, as a result, only the most frequently occurring mutants are obtained from single lectin selections. We have previously shown that the specificity of lectin selections may be improved by utilizing a combination of lectins added together or sequentially. This strategy has now been further exploited in the search for novel lectin-resistant mutants of Chinese hamster ovary cells. Five new LecR phenotypes have been uncovered. One belongs to a new, recessive complementation group, two behave dominantly in somatic cell hybrids, and the remaining two appear to represent new phenotypes which fall into previously described complementation groups.

Spontaneous fusion in vivo between normal host and tumor cells: possible contribution to tumor progression and metastasis studied with a lectin-resistant mutant tumor

Previous studies demonstrated that growth in DBA/2 mice of MDW4, a wheat germ agglutinin-resistant (WGAr) mutant of the highly metastatic MDAY-D2 DBA/2 mouse tumor, led to the emergence of WGA-sensitive (WGAs) revertants having higher ploidy levels at the site of inoculation as well as at distant visceral metastases. The results implied that MDW4 was nonmetastatic but progressed to become metastatic in vivo only after a cellular change took place which was accompanied by extinction of the WGAr phenotype and acquisition of a higher number of chromosomes. Results presented here provide strong and direct evidence for the underlying mechanism being spontaneous cell fusion in vivo between the MDW4 (WGAr) tumor cells and normal host cells, at least some of which are of bone marrow origin. Thus, growth of the H-2d MDW4 tumor cells in (C3H X DBA/2)F1 (H-2k X H-2d) or (C57BL/6 X DBA/2)F1 (H-2b X H-2d) mice led to the appearance of WGAs revertants bearing the H-2k or H-2b major histocompatibility complex antigens associated with the C3H or C57BL/6 parental strains, respectively. Similarly, WGAs revertants of MDW4 were found to express H-2k antigens after growth in CBA/HT6T6 (H-2k) leads to DBA/2 bone marrow radiation chimeras. Attempts to mimic the in vivo hybridization process were successful in that in vitro somatic cell fusion between an ouabain-resistant (OuaR), 6-thioguanine-resistant (Thgr) derivative of the MDW4 mutant and either normal bone marrow or spleen cells resulted in loss of the WGAr phenotype in the hybrids (thus showing its recessive character) and increased malignant properties in vivo. An analysis of spontaneous frequencies of re-expression of various drug resistance genetic markers in several hybrid metastatic cells was also consistent with chromosome segregation of the sensitive alleles. The results show that tumor progression and the emergence of metastatic cell variants could arise as a consequence of tumor X host cell fusion followed by chromosome segregation. We also discuss the possibility that this type of event may normally be a very rare one during the growth of tumors, the frequency of which can be artificially amplified by the use of certain classes of lectin-resistant mutants carrying particular cell surface alterations.

Spontaneous fusion in vivo between normal host and tumor cells: possible contribution to tumor progression and metastasis studied with a lectin-resistant mutant tumor

Previous studies demonstrated that growth in DBA/2 mice of MDW4, a wheat germ agglutinin-resistant (WGAr) mutant of the highly metastatic MDAY-D2 DBA/2 mouse tumor, led to the emergence of WGA-sensitive (WGAs) revertants having higher ploidy levels at the site of inoculation as well as at distant visceral metastases. The results implied that MDW4 was nonmetastatic but progressed to become metastatic in vivo only after a cellular change took place which was accompanied by extinction of the WGAr phenotype and acquisition of a higher number of chromosomes. Results presented here provide strong and direct evidence for the underlying mechanism being spontaneous cell fusion in vivo between the MDW4 (WGAr) tumor cells and normal host cells, at least some of which are of bone marrow origin. Thus, growth of the H-2d MDW4 tumor cells in (C3H X DBA/2)F1 (H-2k X H-2d) or (C57BL/6 X DBA/2)F1 (H-2b X H-2d) mice led to the appearance of WGAs revertants bearing the H-2k or H-2b major histocompatibility complex antigens associated with the C3H or C57BL/6 parental strains, respectively. Similarly, WGAs revertants of MDW4 were found to express H-2k antigens after growth in CBA/HT6T6 (H-2k) leads to DBA/2 bone marrow radiation chimeras. Attempts to mimic the in vivo hybridization process were successful in that in vitro somatic cell fusion between an ouabain-resistant (OuaR), 6-thioguanine-resistant (Thgr) derivative of the MDW4 mutant and either normal bone marrow or spleen cells resulted in loss of the WGAr phenotype in the hybrids (thus showing its recessive character) and increased malignant properties in vivo. An analysis of spontaneous frequencies of re-expression of various drug resistance genetic markers in several hybrid metastatic cells was also consistent with chromosome segregation of the sensitive alleles. The results show that tumor progression and the emergence of metastatic cell variants could arise as a consequence of tumor X host cell fusion followed by chromosome segregation. We also discuss the possibility that this type of event may normally be a very rare one during the growth of tumors, the frequency of which can be artificially amplified by the use of certain classes of lectin-resistant mutants carrying particular cell surface alterations.

Organ specific metastasis with special reference to avian systems

Many malignant tumors demonstrate a definite propensity for metastasis to specific organs despite the fact that tumor cells with the potential for metastasis may circulate randomly throughout the body. Current concepts of organ specific metastasis (OSM) center around the generation of tumor cell variants with enhanced capacity for metastasis to specific organs. At present three hypotheses, mechanical, seed and soil, and specific tumor cell adherence (STCA), stand out as possible explanations for OSM. These possible mechanisms of OSM are by no means mutually exclusive. Recent efforts to understand OSM have included the selection of organ-specific metastasizing variants from tumor cell lines and an examination of their surface and metastatic properties. OSM-selected cell lines from many different tumor systems have been used to examine the relative contributions of the three mechanisms. While examples of each mechanism have been reported, the relative contributions of each for different tumor systems may differ substantially. Therefore, generalizations about the behavior of tumors based on studies with just a few tumor lines and systems may not be valid. There is substantial evidence that cell surface molecules are important in the process of OSM and homing of lymphocytes to specific lymph nodes. Monoclonal antibodies have been produced against putative cell surface receptors and initial biochemical characterization has begun. There is much evidence that cell surface glycoconjugates can serve as specific recognition structures on normal cells and in addition, may play important roles in OSM. The role of these carbohydrates is discussed. The chick embryo as a model system is discussed as it offers several advantages for the study of metastasis in general and OSM in particular. A variety of human and murine tumors, including some freshly isolated, have been shown to grow and metastasize in these embryos. Furthermore, cell lines which have been selected for OSM in adults show similar patterns of metastasis in chick embryos indicating that this system may be an especially attractive one for the analysis of OSM.

Immunology of metastasis. Can the immune response cope with disseminated tumor?

The application of immunologic methods to the treatment of neoplasia has been a goal of research in tumor immunology. Unfortunately, no clearly defined success for such therapy has been achieved. However, the most recent advances in tumor biology have provided for a more valid conceptual framework upon which to plan further research in this area. The more general awareness of tumor progression and heterogeneity, particularly in the context of tumor metastasis, while imposing a sense of gloom regarding all therapeutic modalities, shifted immunologic thinking toward the development of nonspecific modalities. We herein propose that this 'shift' may be premature and that immunotherapy using cytolygic T cells could still be feasible. Our views are based on newer approaches for selecting immunogenic variants of malignant tumors and a better understanding of the relationship of the immune response to metastases.

Cytogenetic changes during tumor progression towards invasion, metastasis and immune escape in the Eb/ESb model system

Related tumor lines which represent different stages in their progression towards metastatic capacity were investigated and compared at the chromosomal level. The parental low-metastatic tumor line (L5178Y/Eb) was derived from a long-term transplanted, chemically induced T-cell lymphoma of the DBA/2 mouse. The cytogenetic analysis included this Eb line, a spontaneous high metastatic variant thereof which expressed a distinct tumor-associated transplantation antigen (ESb TATA+), and an immunoresistant TATA-negative variant of the latter (ESb TATA-). All three cell lines were characterized by a near-diploid chromosome count and by some common chromosomal markers derived from Nos. 6, 13 and 16 Large-scale chromosomal rearrangments resulted in the formation of eight marker chromosomes in Eb cells, 16 in ESb TATA+ cells and 18 in ESb TATA- cells. Tumor progression in this system showed a tendency to monosomies, which could bring the corresponding genes to a hemizygous state and possibly to a release from repression. Chromosome 15 was trisomic in Eb cells, monosomic in ESb TATA+ cells and hardly detectable in ESb TATA- cells. The Ig heavy-chain gene-carrying region of both chromosomes No. 12 was found in translocation with chromosomes Nos. 5, 13 and 14 (Eb cells) and with Nos. 1 and 17 (ESb cells). ESb TATA- cells differed from ESb TATA+ cells at four different chromosomes (Nos. 5, 8, 14 and 15).

Antigenic variation in cancer metastasis: immune escape versus immune control

Antigenic variation in cancer metastasis was observed in a syngeneic murine tumor system consisting of a low metastatic parental tumor line (derived from a methylcholanthrene-induced DBA/2 T lymphoma, Eb), a high metastatic spontaneous variant thereof (ESb), and a low metastatic 'revertant' from ESb (ESb-M). All three lines expressed tumor-associated transplantation antigens (TATA) which elicited specific T cell-mediated antitumor immune reactions in the host. The strongest host response was elicited upon intradermal inoculation. It could be followed by (a) the infiltration of the locally growing tumor by host cells, such as lymphocytes and macrophages, (b) the establishment of specific systemic antitumor immunity, (c) the generation of immune cells capable of transferring protective antitumor immunity into a normal syngeneic recipient, and (d) the generation of tumor specific cytotoxic T lymphocytes (CTL). Anti-TATA CTL were used as typing reagents to investigate the stability or variability in the TATA expression by cloned tumor cell lines. Antigenic variability in the TATA expression was seen under various conditions: (a) clone-dependent variation in the sensitivity to anti-TATA CTL lysis upon prolonged growth in tissue culture, (b) qualitative change in the TATA (TATA1 leads to TATA2) upon successive i.p. transplantation of the parental Eb tumor line and, (c) generation of TATA negative immune escape variants (TATA2 leads to TATA-) during metastasis formation from a s.c. site. The relative inefficiency of specific immunization procedures against ESb was found to be due to the effective generation of TATA negative variants by this highly metastatic tumor. The balance between immune control and immune escape could be influenced to the advantage of the host by some means, for instance optimizing the route of antitumor-immune sensitization or by infusion of allogeneic but H-2 identical antitumor-immune T cells. Such immune cells recognized the tumor via minor histocompatibility antigens and thus circumvented the need of TATA recognition. Finally, manipulations at the cell surface of the highly malignant ESb tumor such as those introduced in the ESb-M variant were found to dramatically effect its metastatic potential.