Enhanced experimental metastatic capacity of a human tumor line following treatment with 5-azacytidine

We have studied the effect of the nucleoside analogue 5-azacytidine (5-azaC) a known activator of gene expression, on the metastatic behavior of the human melanoma cell line DX3. After exposure to 3 microM 5-azaC for 24 h cells were carried through five subcultures before being tested for their metastatic capacity. Following i.v. injection in BALB/c nude mice, cells treated with 5-azaC showed a 40-fold increase in the number of lung tumor nodules as compared to that obtained with control cells. Tumors resulting from 5-azaC-treated cells exhibited a 5-fold increase in mitotic figures, considerable cellular pleomorphism, and variation in the histological character of the individual nodules. These in vivo differences were not reflected in vitro where treated and untreated cells showed no significant differences in morphology, karyotypes, growth rates, saturation densities, or plating efficiencies. Cells populating the lung tumor nodules retained their increased metastatic capacity through successive cycles of growth in vitro followed by reinjection into nude mice and indeed the ability of the cell lines to form lung tumors was increased with the succeeding cycles in vivo. These cell lines, each established from individual tumor nodules, maintained a human karyotype and reacted positively with human-specific antiserum. Characterization of these lines showed that while there were no alterations in in vitro growth behavior the selected lines exhibited a decreased latency period for s.c. tumor formation, increased retention in the lungs following i.v. injection, and enhanced lung nodule formation (60- to 80-fold compared to control cells). Examination of genomic DNA showed that treatment with 5-azaC brought about a significant decrease (50%) in the percentage of methylated cytosine residues but this extensive hypomethylation was not maintained in the lung tumor nodule-derived cell lines.     

Comparison of 'spontaneous' and 'experimental' metastasis using rat 13762 mammary adenocarcinoma metastatic cell clones

Rat 13762NF mammary adenocarcinoma cloned cell lines were assayed at different in vitro passage numbers and compared for their abilities to form 'spontaneous' metastases by subcutaneous injection of cells and 'experimental' metastases by intravenous injection of cells. Tumor cell clones were established from locally growing tumor and spontaneous lung metastases, and these clones were found to possess heterogeneous metastatic potentials in both metastasis assays. The rank order of clonal metastatic potentials based on either the average number of lung tumor colonies or the average total lung tumor volume was generally equivalent for 'spontaneous' and 'experimental' metastases, but some differences were noted. Ranking of 'spontaneous' metastasis by average total lung tumor volumes more closely resembled the rank order of 'experimental' metastasis than by the average number of spontaneous metastases. The results demonstrated that in the 13762NF mammary adenocarcinoma system (i) there is heterogeneity in tumor cell clonal metastatic potential using either 'spontaneous' or 'experimental' assays; (ii) these two assay methods yield generally the same rank order of metastatic potential; (iii) the metastatic potential of each of the tumor cell clones drifts with time (passage number) in cell culture, and (iv) ranking by average tumor burden calculated from total lung tumor volumes may yield a better estimate of metastatic potential than ranking by the average number of lung tumor colonies.     

Correlation of growth capacity of human tumor cells in hard agarose with their in vivo proliferative capacity at specific metastatic sites

The purpose of this study was to determine whether the degree of anchorage-independent growth of human tumor cells in increasing concentrations of agarose correlated with the capacity of the cells to produce experimental metastases in nude mice. Human melanoma, breast carcinoma, and colon carcinoma cells from parental lines and variants selected in vivo for metastasis and in vitro cloned lines were plated into medium containing 0.3%, 0.6%, 0.9%, or 1.2% of agarose. These cells were also injected into nude mice: intravenously for melanoma, into the mammary fat pad for breast carcinoma, and into the spleen for colon carcinoma. Production of tumor cell colonies in dense agarose (greater than 0.6%) correlated with production of experimental metastases in the lung (melanoma, breast carcinoma) or liver (colon carcinoma). We conclude that the degree of anchorage-independent growth of tumor cells can predict their biological behavior and metastatic potential in vivo. Thus, this technique may be useful for the isolation of metastatic cells from heterogeneous human neoplasms.     

Human tumor spontaneous metastasis in immunosuppressed newborn rats. I. Characterization of the bioassay

We characterize a new model of spontaneous metastasis of human tumor cells using anti-thymocyte serum (ATS) immunosuppressed newborn rats. We analyzed the intrinsic value of the bioassay of measurement of tumorigenicity and metastatic capacity using 17 human tumor cell lines, of which were 9 human malignant melanomas. Most of these cell lines revealed as tumorigenic and metastatic in lungs and/or lymph nodes 3 weeks after s.c. injection in the ventral flank of newborn rats, irrespective of their origin. All the melanoma cell lines that we injected were tumorigenic and 77% were metastatic, whereas the same cell lines grafted in nude mice showed no evidence of metastases after 6 weeks' examination. We were not able to show any relationship between tumorigenicity in nude mice and the malignant behavior of these cells in ATS-treated newborn rats. Likewise, neither chromosome abnormalities, nor antigenic marker expression were found to be related to tumor growth in nude mice or newborn rats. Two intrinsic parameters of the model were studied: number of cells injected vs. dose of ATS injected for one melanoma cell line; and role of the 3rd and 4th injections of ATS in the establishment and development of pulmonary metastases. Moreover, we show that s.c. injection in the ATS-treated newborn rat may represent a suitable method for studying melanoma cell tumor growth and spontaneous dissemination.     

Genetic evidence for progressive selection and overgrowth of primary tumors by metastatic cell subpopulations

We have exploited random insertions of transfected DNA as unique clonotypic markers to follow cell lineages during primary and metastatic tumor growth of a mouse mammary adenocarcinoma, SP1. Southern analysis was undertaken of primary solid tumors and metastases obtained after injection of a pooled population of individual SP1 transfectants, or reconstituted mixtures of genetically marked metastatic and unmarked nonmetastatic cells. Here we provide evidence for the reproducible selection and eventual overgrowth of primary tumors by genotypically distinct metastatic clones, thereby illustrating that late-state, advanced primary tumors can evolve to become biologically similar, or even identical, to distant metastases. The selective growth advantage of metastatic cells within primary tumors was shown to occur despite the fact that tumors generated by both metastatic and nonmetastatic SP1 cell populations grew at comparable growth rates when injected and analyzed separately. The extent of the local growth advantage manifested by individual metastatic clones varied considerably, from 5- to 50-fold. Clonal overgrowth was also observed whether the tumor cells were injected ectopically, or orthotopically (i.e., into the mammary fat). This type of experimental approach should provide new insights into the dynamics of tumor progression and metastasis, the lineage relationship of primary tumors to metastases, the influence of clonal interactions on tumor behavior, and the physiological changes which are causative of malignant disease.     

Clonal origin of metastasis in B16 murine melanoma: a cytogenetic study

A cell line isolated from the B16 melanoma and carried in continuous culture for 8 years (the parent line) exhibited great heterogeneity in terms of marker chromosome content. A lung metastasis from a C57BL/6 mouse inoculated im with cells of this line showed karyotypic homogeneity. Inoculation iv of cells from the parent line produced numerous tumor foci in various organs. Cytogenetic analyses of 18 such lesions led to the following conclusions: Cells from each metastatic colony exhibited relatively homogeneous karyotypic characteristics, indicating that metastases are of clonal origin; many parental cells with different marker chromosomes had metastatic potential; and some genomes maintained homogeneity longer than others.     

Irradiation-induced marker chromosomes in a metastasizing murine tumor

We have used irradiation to induce marker chromosome formation in a metastasizing murine tumor with a stable karyotype. The induced recombinant chromosomes then served to determine whether metastases were of clonal or multicellular origin. Cumulative data were obtained from four series of experiments on spontaneous metastases originating from tumors grown from irradiated cells; 20 of these metastases expressed unique chromosomal alterations consistent with a clonal origin. The majority of metastasis-derived cell populations remain stable with respect to their marker chromosomes in culture as well as in successive animal transplantation. In several instances, however, chromosomal instability was sufficient to obscure the cellular origins of individual metastases. A few metastases showed mixed chromosomal patterns initially that were consistent with multicellular origin, but repeat examinations have revealed a chromosomal instability which persisted during propagation in culture. The frequency of chromosomal recombinants in metastases from the combined series was sufficient to suggest biological and statistical significance. The morphology of recombinants was not associated with radiation dose but appeared as an apparently random response of the tumor population in different experiments. Analysis of chromosomal markers by banding techniques was performed to determine if specific chromosomes or chromosomal sites were associated with tumor cells from metastatic foci (a host-selected subpopulation with a metastatic phenotype). Our results did not reveal preferential involvement of whole chromosomes or intrachromosomal sites in recombinant formation.     

Malignant potential of cells isolated from lymph node or brain metastases of melanoma patients and implications for prognosis

We studied the correlation between the formation of brain metastasis and the malignant growth potential of seven human melanoma cell lines, isolated from lymph node metastases (A375-SM, TXM-1, DM-4) or from brain metastases (TXM-13, TXM-18, TXM-34, TXM-40), and the potential of three variants of the mouse K-1735 melanoma. Growth rates in different concentrations of fetal bovine serum and colony-forming efficiency in semisolid agarose were measured, and the tumorigenicity and metastatic ability were determined in nude mice (for the human melanoma cell lines) or in C3H/HeN mice (for the K-1735 variants). The ability to form brain metastasis was tested by injection of cells into the carotid artery. A high colony-forming efficiency in agarose, especially at concentrations of agarose greater than 0.6%, corresponded with high tumor take rates, rapid tumor growth rates, and metastatic colonization of the lungs of the recipient mice. For the human melanomas, the lymph node metastasis-derived cells were more tumorigenic and metastatic than the brain metastasis-derived cells. In the K-1735 mouse melanoma, the tumorigenic and metastatic behavior of the cells after i.v. and s.c. injection corresponded with growth in agarose cultures. However, for growth in the brain after intracarotid injection, the different melanoma cell lines showed similar frequencies of tumor take, regardless of tumorigenicity in other sites of the recipient mice, although mice given injections of brain metastasis-derived cells survived longer than mice given injections of lymph node metastasis (human melanoma) or lung metastasis (K-1735 M-2)-derived cell lines. The results from the human and mouse melanoma cell lines show that the brain metastasis-derived cell lines were not more malignant than the lymph node or lung metastasis-derived cells. These data imply that the production of brain metastasis is not always the final stage of a metastatic cascade.     

Tumorigenicity and dissemination of primary and metastatic human melanomas implanted into different sites in athymic nude mice

In the present study, the growth features and metastatic capacity of human primary and metastatic melanomas transplanted by different routes in nude mice was examined. Eight different human melanoma early cell cultures derived from 3 primary tumors, 1 local recurrence and 4 metastatic lesions of 6 melanoma patients were characterized for cell surface HLA (class I and II) and melanoma-associated antigens and karyotype. These tumors were then transplanted in CD-1 outbred nude mice by subcutaneous, intraperitoneal and intrasplenic routes. It was found that 7 out of 8 melanomas were tumorigenic after subcutaneous implantation without giving rise to metastases; 5 out of 7 melanomas grew when injected intraperitoneally and 3 of them disseminated to peritoneal organs and infiltrated intraperitoneal lymph nodes, liver and pancreas; of 8 melanomas implanted intrasplenically 4 grew in the spleen or invaded intraperitoneal lymph nodes, liver, pancreas, ovaries or lungs. Primary and metastatic melanomas did not differ in the pattern of dissemination. In fact, 2 out of 4 metastases and 1 of 3 primary tumors and 1 recurrence disseminated after intrasplenic or intraperitoneal inoculation. Heterogeneity in the growth pattern of different metastases of the same melanoma patient was also found. No correlation could be detected between the metastatic ability of melanoma cells studied and clinical stage of patients, tumor cell karyotype abnormalities, modal number or with the antigenic phenotype.     

Influence of nitric oxide synthase II gene disruption on tumor growth and metastasis

The relationship between nitric oxide (NO) synthase II (NOS II) expression and the metastatic ability of tumor cells is inconclusive. We determined the role of host NOS II expression in the growth and metastasis of the B16-BL6 murine melanoma and M5076 murine ovarian sarcoma cell lines. The cells were either s.c. or i.v. injected into syngeneic wild-type (NOS H+/+) and NOS II-null (NOS H-/-) C57BL/6 mice. Both cell lines produced slightly larger s.c. tumors in NOS H-/- mice than in NOS II+/+ mice. However, B16- BL6 cells produced more and larger experimental lung metastases in NOS II+/+ mice than in NOS II-/- mice, whereas M5076 cells produced fewer and smaller experimental lung metastases in NOS II+/+ mice than in NOS II-/- mice. After activation with IFN-gamma and lipopolysaccharide, macrophages isolated from NOS II+/+ C57BL/6 mice produced NO-dependent cytotoxicity in sarcoma cells, whereas macrophages from NOS II-/- C57BL/6 mice did not. In contrast, activated macrophages produced little to no NO-mediated cytotoxicity in melanoma cells. Immunostaining analyses indicated that NOS II expression was apparent in the metastases growing in NOS H+/+ mice and correlated with increased cell proliferation in B16-BL6 lung metastases but with decreased cell proliferation in M5076 liver metastases. Our data suggest that disruption of host NOS II expression enhanced the growth and metastasis of NO-sensitive tumor cells but suppressed the metastasis of NO-resistant tumor cells, proposing that host-derived NO may differentially modulate tumor progression.     

Determination of clonality of metastasis by cell-specific color-coded fluorescent-protein imaging

It has been thought that metastases are clonal and originate from rare cells in primary tumors that are heterogeneous in genotype and phenotype. Recent studies using DNA array analysis challenge this hypothesis and suggest the genetic background of the host is the important determinant of metastatic potential implying that metastases are not necessarily clonal. Previous methods to determine clonality of metastasis used karyotype or molecular analysis that were complicated, thereby limiting the number of metastatic colonies analyzed and the conclusions that could be drawn. We describe here the use of green fluorescent protein-labeled or red fluorescent protein-labeled HT-1080 human fibrosarcoma cells to determine clonality by simple fluorescence visualization of metastatic colonies after mixed implantation of the red and green fluorescent cells. Resulting pure red or pure green colonies were scored as clonal, whereas mixed yellow colonies were scored as nonclonal. In a spontaneous metastasis model originating from footpad injection in severe combined immunodeficient mice, 95% of the resulting lung colonies were either pure green or pure red, indicating monoclonal origin, whereas 5% were of mixed color, indicating polyclonal origin. In an experimental lung metastasis model established by tail vein injection in severe combined immunodeficient mice, clonality of lung metastasis was dependent on cell number. With a minimum cell number injected, almost all (96%) colonies were pure red or green and therefore monoclonal. When a large number of cells were injected, almost all (87%) colonies were mixed color and therefore heteroclonal. We conclude that spontaneous metastasis may be clonal because they are rare events, thereby supporting the rare-cell clonal origin of metastasis hypothesis. The clonality of the experimental metastasis model depended on the number of input cells. The simple fluorescence method of determining clonality of metastases described here can allow large-scale clonal analysis in numerous types of metastatic models.     

Vascular anatomy and organ-specific tumor growth as critical factors in the development of metastases and their distribution among organs

We have examined with 19 tumor cell lines the discrete roles that vascular anatomy and tumor-cell-organ-affinity play in the development of metastases and their distribution among organs. Spontaneous metastases of B16-G3.26 melanoma cells from a primary tumor growing in the foot pad of mice, or experimental metastases 21 days after intravenous tumor-cell injection resulted in tumor colonies only in the lungs. In contrast, when the lung microvasculature was bypassed, and the same cells given by systemic intra-arterial (s.i.a.) injection, large tumor colonies developed selectively in the ovaries, adrenal glands and bones, but rarely in the lungs. When animals injected i.v. were allowed to live with lung metastases for a long period of time, small tumor colonies began to develop in extra-pulmonary organs with a distribution identical to that seen after s.i.a. injection. Seven murine tumor cell lines (previously characterized by their ability to colonize primarily the lungs after i.v. injection) and 7 of the 8 studied human tumor cell lines colonized different specific extra-pulmonary organs after s.i.a. injection, frequently producing metastatic syndromes commonly described in patients with cancer, but rarely seen in animal models of metastasis. These results suggest that metastatic cells, even those capable of colonizing specific organs, do not freely circulate in the blood stream and lodge in specific tissues. In contrast, the cells must establish a vascular route of access to the target organ, e.g., through the systemic circulation from metastatic tumors in the lungs. Two cell lines considered to be tumorigenic but non-metastatic failed to colonize the lungs or extra-pulmonary organs after i.v. injection, but readily colonized specific organs after s.i.a. injection. Thus, tumor cells considered to be non-metastatic may be indeed metastatic if they are provided with vascular access to an organ more congenial to their growth requirements.     

DNA amplification and metastasis of the human melanoma cell line MeWo

A positive correlation was found between the presence of amplified DNA in the form of homogeneously staining regions (HSRs), and the formation of spontaneous metastases by the human melanoma cell line MeWo. HSR+ and HSR- MeWo sublines and clones were injected s.c. into BALB/c nude mice. All MeWo lines produced primary tumors that were allowed to grow to a similar size before the animals were sacrificed and examined for the presence of metastatic nodules in the lungs and abdominal cavity. HSR+ lines gave extensive metastases (greater than 100 nodules) in the lungs and/or liver and abdomen in 18 of 19 animals. The HSR- MeWo lines were effectively nonmetastatic, producing metastases in 3 of 20 animals, two of which had only a single metastatic lung nodule each. Evidence for the presence of HSRs in the primary tumors and metastatic nodules was obtained by DNA dot-blot hybridization to a sequence (D15Z1) amplified in the HSRs, flow cytofluorometry for cellular DNA content, and quinacrine staining of metaphase spreads. The HSR+ clones also colonized the lung to a much greater extent than HSR- clones following i.v. injection. In addition, the HSR+ clone had a selective advantage in lung colonization, since i.v. injection of a 50:50 mixture of HSR+ and HSR- clones resulted in extensive metastases populated exclusively by HSR+ cells. The results suggest that DNA sequences amplified in the HSRs of human melanoma MeWo cells may confer enhanced metastatic properties to these cells.     

Intranasal therapy with an adenoviral vector containing the murine interleukin-12 gene eradicates osteosarcoma lung metastases.

The purpose of these studies was to determine the effect of adenovirus-mediated interleukin-12 (IL-12) gene transfer on the growth and development of osteosarcoma (OS) lung metastases in nude mice. A nude mouse model was produced by repetitive cycling of human SAOS OS cells through the lung. The resultant SAOS-LM6 cell line produced microscopic lung metastases by 5-6 weeks after i.v. injection of the tumor cells, with visible lung metastases present 8 weeks after injection. Transfection of SAOS-LM6 cells with a plasmid containing the murine IL-12 gene resulted in a decrease in metastatic potential. Animals injected with IL-12-transfected clones had fewer metastases compared with mice injected with SAOS-LM6 cells transfected with a control plasmid. Furthermore, nasal delivery of an adenoviral vector containing the murine IL-12 gene resulted in the inhibition of pulmonary metastases. Together, these data indicate that IL-12 may be an effective agent against OS and that nasal delivery may offer a unique way to deliver the gene to the local tumor environment, potentially decreasing systemic toxic effects.     

Antisense oligodeoxynucleotides for urokinase-plasminogen activator receptor have anti-invasive and anti-proliferative effects in vitro and inhibit spontaneous metastases of human melanoma in mice

We have targeted the urokinase-type plasminogen activator receptor (uPAR) with phosphorothioate antisense oligonucleotides (aODN) in vitro to evaluate the anti-invasive and anti-proliferative effects of uPAR down-regulation, as well as in vivo to evaluate anti-tumor and anti-metastatic activity. aODN-dependent uPAR downregulation in vitro was induced in cells of human melanoma, mammary carcinoma, ovarian carcinoma and SV-40-transformed embryonic lung fibroblasts. uPAR was determined by an antibody-based assay and by semiquantitative polymerase chain reaction. Cell invasion was evaluated by Matrigel invasion assay and cell proliferation by direct cell counting. aODN reduced uPAR, invasion and proliferation in all the treated cell lines. Following aODN treatment, human melanoma cells exhibited a strong decrease of uPAR-dependent ERK1/2 activation and were used in vivo to control metastasis in CD-1 male nude (nu/nu) mice by uPAR aODN injection. 60 mice were injected in the hind leg muscles with a suspension of 10(6) melanoma cells. After 4 days, when a tumor mass of about 350 mg was evident in all the mice injected, 20 mice were treated i.v. with aODN and 20 with dODN at 0.5 mg/day for 5 consecutive days. Twenty control mice were not treated. A second and third cycle of treatment was administered at 2-day intervals. Treatment with aODN resulted into a 78% reduction of lung metastases and 45% reduction of the primary tumor mass with no loss of body weight. Our results suggest to evaluate the utility of uPAR aODN in controlling the metastatic spreading of human melanoma.     

Loss of heterozygosity at autosomal and X-linked loci during tumor progression in a patient with melanoma

Restriction fragment length polymorphisms at 61 autosomal and 7 X-linked loci were screened for heterozygosity in cell lines derived from 6 independent metastases and autologous B-cells from a patient with melanoma. Segregations resulting in the loss of heterozygosity were detected in the tumor cells at 8 of 16 autosomes with at least 1 informative locus and at the 3 informative X-linked loci. With a single exception, karyotypic abnormalities were not detected in the region of loci where loss of heterozygosity had been detected. Three patterns of loss were identified: unique segregations in cells from a single metastasis; segregation of the same alleles in different subsets of metastases; and identical segregations in all 6 metastases. The monoclonal derivation of the 6 metastases is supported by the inactivation of the same X-chromosome and the presence of identical segregation at loci on chromosomes 9 and X. Analysis of the patterns of segregation in the metastatic tumor cells permitted the development of a genealogy of tumor progression in this patient and the development of a model of tumor progression which describes the accumulation of selectively neutral and advantageous segregations in metastatic tumor cells.     

Metastatic heterogeneity of cells from Lewis lung carcinoma

To allow investigations of the role of tumor cell proteases in invasion and metastasis, an attempt was made to obtain well-defined homogeneous populations of Lewis Lung carcinoma cells differing widely in their metastatic potential. From a single Lewis lung carcinoma, a parental line of cells was established and subsequently cloned so as to provide 18 clonal tumor cell lines. These clones differed in their ability to produce spontaneous, macroscopically visible metastases in the lung after i.m. inoculation into syngeneic C57BL/6 mice. Several of them were less metastatic than the parental line. The parental line expressed a metastatic behavior close to that of the high-metastatic cell subpopulations that it contained. There was, within certain limits, a good correlation between the potential for spontaneous lung metastases arising from a primary tumor and that for "artificial" lung colonies obtained after i.v. injection of the Lewis lung carcinoma cells. Although positively correlated with the growth rate of the tumor cells, the metastatic ability of the clones could not be considered as a mere reflection of the proliferation rates of the cells constituting the primary tumors. Differences in metastatic behavior observed among clones persisted in several cases after the cells had been maintained in culture for prolonged periods. However, this stability of the clones in vitro was not absolute. Indeed, some subclones isolated from the low-metastatic clone H122 displayed metastatic abilities which were lower than that of the parent clone. Furthermore, a significant increase in metastatic potential was once observed after a prolonged culture period of that same clone, H122. Thus, new metastatic phenotypes can emerged under in vitro culture conditions. However, the relative rarity of this event suggests that some metastatic heterogeneity already preexisted in vivo among the tumor cells.     

Generation of phenotypic diversity in the B16 mouse melanoma relative to spontaneous metastasis

Serial s.c. transplantation of the B16 melanoma in syngeneic mice for nearly 30 monthly generations effected gradual changes in the incidence of spontaneous pulmonary metastasis. Cell lines derived from s.c. tumors and from secondary tumor growths in the lungs were comparably variable in metastatic predilection and also differed in ability to produce tumor colonies in the lungs following i.v. injection of cultured cells. Some lines metastasized to the lungs from s.c. tumors and also colonized the lungs; others were metastatic but noncolonizing, colonizing and nonmetastatic, or nonmetastatic and noncolonizing ("null"). Metastatic and colonizing activities of all cell lines except the most potent colonizers were unstable in culture and during s.c. growth. Over 150 clones and subclones were obtained from B16 melanoma cell lines, and four distinct categories were defined on the basis of dissemination-related phenotypic characteristics: slow-growing null (Ns); rapid-growing null; metastatic; and colonizing. No single cell belonged to more than one category at the same time, but interconversions occurred rapidly and consistently during growth in vitro and in vivo. Progenitor Ns cells generated metastatic cells in culture and in tumors and became rapid-growing null cells and colonizers solely within tumors. Metastatic activity was transient, with cells reverting back to an Ns phenotype in culture and s.c. or converting to rapid-growing null cells and colonizers in vivo. Only potent colonizers were stable, an apparent end result of phenotypic diversification, but formation or proliferation of these cells within tumors was somehow regulated. Comparable heterogeneity was generated within lung metastases, except that reversion of metastatic cells to Ns cells and regeneration of metastatic activity were not demonstrated; the result was a progressive loss of metastatic cells within developing metastases.     

Anti‐tumor activity of CpG‐ODN aerosol in mouse lung metastases

Studies in preclinical models have demonstrated the superior anti‐tumor effect of CpG oligodeoxynucleotides (CpG‐ODN) when administered at the tumor site rather than systemically. We evaluated the effect of aerosolized CpG‐ODN on lung metastases in mice injected with immunogenic N202.1A mammary carcinoma cells or weakly immunogenic B16 melanoma cells. Upon reaching the bronchoalveolar space, aerosolized CpG‐ODN activated a local immune response, as indicated by production of IL‐12p40, IFN‐γ and IL‐1β and by recruitment and maturation of DC cells in bronchoalveolar lavage fluid of mice. Treatment with aerosolized CpG‐ODN induced an expansion of CD4+ cells in lung and was more efficacious than systemic i.p. administration against experimental lung metastases of immunogenic N202.1A mammary carcinoma cells, whereas only i.p. delivery of CpG‐ODN provided anti‐tumor activity, which correlated with NK cell expansion in the lung, against lung metastases of the poorly immunogenic B16 melanoma. The inefficacy of aerosol therapy to induce NK expansion was related to the presence of immunosuppressive macrophages in B16 tumor‐bearing lungs, as mice depleted of these cells by clodronate treatment responded to aerosol CpG‐ODN through expansion of the NK cell population and significantly reduced numbers of lung metastases. Our results indicate that tumor immunogenicity and the tumor‐induced immunosuppressive environment are critical factors to the success of CpG therapy in the lung, and point to the value of routine sampling of the lung immune environment in defining an optimal immunotherapeutic strategy.     

Dynamic heterogeneity: characterization of two cell lines derived from experimental lung metastases of mouse KHT fibrosarcoma

We have recently demonstrated that KHT fibrosarcoma variant cells that form experimental metastases are generated by a stochastic process at high effective rates (approximately 10(-5)/cell/generation). The metastatic variant cells are unstable and are rapidly lost with an effective rate of reversion of approximately 10(-1)/cell/generation. In this study, we have examined the dynamics of generation of metastatic variant cells for two lines of KHT cells derived from individual experimental lung metastases in a single step selection. When grown in vitro, the KHT35-L1 cell population maintained a highly metastatic phenotype whereas the KHT3-L1c cell population reverted to a poorly metastatic phenotype. Our results indicate that there is an approximately 10-fold higher effective rate of generation of metastatic variant cells for KHT35-L1 cells relative to KHT3-L1c cells. Thus, a higher effective rate of generation of metastatic variants accompanies a stably expressed metastatic ability in fibrosarcoma cells and, as we have previously reported, in melanoma cells.