Suppression of the tumorigenic phenotype of a rat liver epithelial tumor cell line by the p11.2–p12 region of human chromosome 11

Comparative chromosomal mapping studies and investigations of tumor-associated chromosomal abnormalities suggest that the development of hepatic tumors in humans and rats may share a common molecular mechanism that involves inactivation of the same tumor suppressor genes or common genetic loci. We investigated the potential of human chromosomes 2 and 11 to suppress the tumorigenic phenotype of rat liver epithelial tumor cell lines. These tumor cell lines (GN6TF and GP7TB) display elevated saturation densities in culture, efficiently form colonies in soft agar, and produce subcutaneous tumors in 100% of syngeneic rat hosts with short latency periods. Introduction of human chromosome 11 by microcell fusion markedly altered the tumorigenicity and the transformed phenotype of GN6TF cells. In contrast, the tumorigenic potential and phenotype of GP7TB cells was unaffected by the introduction of human chromosome 11, indicating that not all rat liver tumor cell lines can be suppressed by loci carried on this chromosome. Introduction of human chromosome 2 had little or no effect on the tumorigenicity or cellular phenotype of either tumor cell line, suggesting the involvement of chromosome 11–specific loci in the suppression of the GN6TF tumor cell line. The GN6TF-11^neo microcell hybrid cell lines displayed significantly reduced saturation densities in monolayer cultures, and their ability to grow in soft agar was completely inhibited. Although GN6TF-11^neo cells ultimately formed tumors in 80–100% of syngeneic rat hosts, the latency period for tumor formation was much longer. Molecular characterization of GN6TF-11^neo microcell hybrid cell lines indicated that some of the clonal lines had spontaneously lost significant portions of the introduced human chromosome, partially delineating the chromosomal location of the putative tumor suppressor locus to the region between the centromere and 11p12. Molecular examination of microcell hybrid–derived tumor cell lines further defined the minimal portion of human chromosome 11 capable of tumor suppression in this model system to the region 11p11.2-p12. © 1995 Wiley-Liss, Inc.     

Identification of candidate liver tumor suppressor genes from human 11p11.2 by transcription mapping of microcell hybrid cell lines

Our previous studies utilized a microcell hybrid (MCH) cell line-based functional model of tumor suppression to localize a liver tumor suppressor to human chromosome 11, map the suppressor locus to a <1-Mb region within human 11p11.2, and identify a number of expressed sequence tags (ESTs) and genes that represent candidate liver tumor suppressor genes. The Human Genome Project has recently positioned a number of additional genes, ESTs, and predicted genes within the human 11p11.2 liver tumor suppressor region. In this study, we analyzed 26 ESTs and genes (known and predicted) that have been localized to human 11p11.2. Four of these ESTs/genes (FLJ23598, FLJ10450, KIAA1580, SYT13) mapped to the minimal tumor suppressor region of human 11p11.2, the smallest region conferring suppression of tumorigenicity in the MCH cell lines. Each of these ESTs/genes were expressed among an index panel of suppressed MCH cell lines (derived from GN6TF rat liver tumor cells), suggesting that these ESTs/genes represent excellent candidates for the human 11p11.2 liver tumor suppressor gene. To verify the candidate status of these sequences, 8 additional MCH cell lines (derived from GN3TG and GP10TA rat liver tumor cells) were analyzed. Three ESTs/genes (FLJ23598, FLJ10450, KIAA1580) proved to be less than ideal candidates, based upon their loss from suppressed MCH cell lines (DNA deletion), and/or their retention and expression in a non-suppressed MCH cell line. In contrast, SYT13 is present in the DNA from all suppressed MCH cell lines (n=10), and is deleted in a non-suppressed MCH cell line. Furthermore, SYT13 mRNA is expressed in 100% of suppressed cell lines, and is not expressed in the non-suppressed MCH cell line or in MCH-derived tumor cell lines (n=6). These results suggest that SYT13 is an excellent candidate for the human 11p11.2 liver tumor suppressor gene based upon its: i) location within the human 11p11.2 liver tumor suppressor region; ii) loss from the DNA of a non-suppressed MCH cell line that lacks the human 11p11.2 liver tumor suppressor region; iii) expression among suppressed MCH cell lines; and iv) lack of expression by MCH-derived tumor cell lines.     

Suppression of tumorigenicity of rat liver tumor cells by human chromosome 13: evidence against the involvement of pRb and BRCA2.

Aberrations of chromosome 13, including large-scale deletions and rearrangements, have been implicated in the development of a significant fraction of human hepatocellular carcinomas, suggesting that liver tumor suppressor genes may be located on this chromosome. In this study, we have employed a microcell hybrid-based model system to investigate the presence of liver tumor suppressor loci on human chromosome 13. The parental GN6TF rat liver epithelial tumor cells are highly tumorigenic in vivo and exhibit altered cellular morphology and growth characteristics in vitro. The GN6TF cells form tumors in 100% of syngeneic animals with short latency, are not contact inhibited or anchorage-dependent in cell culture, and do not express mRNAs for rat Rb1 and BRCA2. Microcell-mediated introduction of human chromosome 13 into the rat liver tumor cell line GN6TF resulted in the generation of clonal microcell hybrid (MCH) cell lines that differentially exhibited tumor suppression and/or alteration of other transformation-associated phenotypes in vitro. Two GN6TF-13neo MCH lines exhibited characteristics indicative of suppression by the human chromosome, including a normalized cellular morphology and growth pattern, loss of anchorage-independent growth potential, partial restoration of contact inhibition, reduction in tumorigenic potential in vivo, and dramatic elongation of tumor latency. In contrast, three GN6TF-13neo MCH cell lines were minimally affected by the introduction of the human chromosome and were nearly indistinguishable from the parental GN6TF tumor cells, exhibiting a highly aggressive tumorigenic phenotype in vivo. Both suppressed and non-suppressed GN6TF-13neo MCH cell lines express Rb1 and BRCA2 mRNA in vitro, and tumors derived from the non-suppressed GN6TF-13neo MCH cell lines continue to express Rb1 and BRCA2 mRNA in vitro, and express pRb in vivo. The results suggest that: i) human chromosome 13 contains a liver tumor suppressor locus, ii) expression of Rb1 and/or BRCA2 is insufficient to produce tumor suppression in this rat liver tumor cell line, and iii) that the human chromosome 13 liver tumor suppressor may represent a novel tumor suppressor gene, distinct from Rb1 and BRCA2.     

Suppression of tumorigenicity in somatic cell hybrids. II. Human chromosomes implicated as suppressors of tumorigenicity in hybrids with Chinese hamster ovary cells

Nontumorigenic diploid human cells were fused with tumorigenic Chinese hamster ovary cells (CHO), and the hybrids were tested for tumorigenicity to determine if specific human chromosomes are associated with suppression of tumorigenicity in cell hybrids. Chromosome complements of cells of 62 nontumorigenic and 45 tumorigenic hybrids (divided into those of low, medium, and high tumorigenicity) as well as 44 tumors derived from the tumorigenic hybrids were determined by both analysis of banded chromosomes and assays of gene markers. Although no single human chromosome was consistently associated with the suppressed phenotype, chromosome 2 was never found in tumor cells, and chromosomes 9, 10, 11, and 17 were found at very low incidences in tumor cells, which suggested that they carry tumorigenicity suppressor information. Since not all suppressed hybrids contained these chromosomes, it is likely that they suppressed tumorigenicity only in combination with each other or other chromosomes. Nine chromosomes in 12 pairwise combinations of nonhomologous chromosomes were not found in tumor cells and were found at an incidence of 5% or less in hybrids of both medium and high tumorigenicity. Other experiments implicated 11 of these combinations involving only 8 chromosomes (chromosomes 4, 7, 8, 9, 10, 11, 13, and 17) as those primarily involved in suppression. Whether chromosome 2 requires another chromosome to effect suppression could not be determined. Further evaluations of the implicated suppressors, including selection of tumorigenic segregants from a panel of suppressed hybrids, again implicated the same chromosomes and their combinations in suppression. Oncogenes have been mapped to many of these chromosomes, and they are frequently involved in tumor-type-specific numerical or structural abnormalities in human neoplasias. The combined evidence suggests that specific human chromosomes of a normal cell carry genes that can regulate several cell phenotypes necessary for the expression of tumorigenicity.     

Localization of a putative liver tumor suppressor locus to a 950-kb region of human 11p11.2-p12 using rat liver tumor microcell hybrid cell lines

We previously demonstrated that a locus (or loci) linked to the D11S436 marker, which is within the approximately 6-Mb cen-p12 region of human chromosome 11, suppresses the tumorigenic potential of some rat liver epithelial tumor microcell hybrid (MCH) cell lines. To more precisely map this putative liver tumor suppressor locus, we examined 25 loci from human chromosome 11 in suppressed MCH cell lines. Detailed analysis of these markers revealed a minimal area of overlap among the suppressed MCH cell lines corresponding to the chromosomal region bounded by (but not including) microsatellite markers D11S1319 and D11S1958E and containing microsatellite markers D11S436, D11S554, and D11S1344. Direct examination of the kang ai 1 (KAI1) prostatic adenocarcinoma metastasis suppressor gene (which is closely linked to D11S1344) produced evidence suggesting that this locus was not responsible for tumor suppression in this model system. In addition, our data strongly suggested that the putative liver tumor suppressor locus was distinct from other known 11p tumor suppressor loci, including the multiple exotoses 2 locus (at 11p11.2-p12), Wilms' tumor 1 locus (at 11p13), and Wilms' tumor 2 locus (at 11p15.5). The results of this study significantly narrowed the chromosomal location of the putative liver tumor suppressor locus to a region of human 11p11.2-p12 that is approximately 950 kb. This advance forms the basis for positional cloning of candidate genes from this region and, in addition, identified a number of chromosomal markers that will be useful for determining the involvement of this locus in the pathogenesis of human liver cancer. Mol. Carcinog. 19:267–272, 1997. © 1997 Wiley-Liss, Inc.     

Suppression of tumorigenicity of A549 lung adenocarcinoma cells by human chromosomes 3 and 11 introduced via microcell-mediated chromosome transfer

To map tumor suppressor genes for lung adenocarcinomas, we introduced normal human chromosomes 3, 7, and 11 into the A549 tumor cell line by microcell-mediated chromosome transfer to test which chromosomes had the ability to suppress tumorigenicity. These human chromosomes, which contain the neomycin gene as a selectable marker, were transferred into A549 lung adenocarcinoma cells at frequencies of 0.3–1.8 × 10^?6. Two microcell hybrid clones with an introduced chromosome 3, two with an introduced chromosome 7, and six with an introduced chromosome 11 were isolated and examined for their growth properties and tumorigenicity in nude mice. Whereas parental A549 cells formed tumors with an average latency of 68 d, both microcell hybrids with an introduced chromosome 3 failed to form tumors for over 360 d. Similar tumorigenicity results were obtained when the clones were implanted into denuded tracheas, a more orthotopic transplantation site. The two clones with an introduced chromosome 7 were still tumorigenic; they formed tumors within 100–123 d after injection and grew progressively, although the tumors grew slightly slower than the parental cells did. Among the six clones with an introduced chromosome 11, one clone was still highly tumorigenic but did not contain an extra copy of an intact introduced chromosome 11. Three clones with a single intact copy of introduced chromosome 11 formed tumors with latency periods significantly longer than those of the parental cells. Two clones had two copies of the introduced chromosome 11, and both failed to form tumors within 1 yr of injection. These results indicate that chromosomes 3 and 11 can suppress the tumorigenicity of A549 lung adenocarcinoma cells.     

Suppression of tumorigenicity of a Wilms' tumor cell line is associated with a decrease in synthesis of two proteins.

Wilms' tumor has been associated with deletions in two loci on chromosome 11, and the introduction of a translocated human chromosome [t(X;11)] into a Wilms' tumor cell line (G401.6TG.6) by microcell hybridization suppresses tumor formation in nude mice. The tumorigenic phenotype is restored in segregants of these microcell hybrids, in which the introduced chromosome is lost. We have used ultrahigh-resolution 'giant' two-dimensional gel electrophoresis of metabolically labeled cellular proteins and in vitro translation products of isolated mRNA to identify changes in cellular gene expression that occur in these cell lines. The changes in gene expression associated with these chromosomal manipulations per se are quite minimal. However, we have identified two proteins (p16 and p28) whose synthesis is consistently decreased in three non-tumorigenic (suppressed) microcell hybrid clones relative to parental and segregant tumorigenic lines. They are also decreased at the level of mRNA in at least two of the non-tumorigenic clones. The decrease of these proteins represents markers of the suppressed phenotype, and their down-regulation may conceivably mediate the suppression of tumorigenicity.     

Multiple chromosomes carrying tumor suppressor activity for a uterine endometrial carcinoma cell line identified by microcell-mediated chromosome transfer

Putative tumor suppressor genes can be mapped to specific chromosomes by the introduction of individual chromosomes derived from normal cells via microcell fusion. We have examined whether a highly malignant human uterine endometrial carcinoma cell line, HHUA, can be suppressed by only one normal chromosome or by multiple chromosomes. A library of mouse A9 clones containing different human chromosomes tagged with the pSV2-neo plasmid DNA were constructed. Transfer by microcell fusion of either chromosome 1, 6, 9, 11, or 19 into the HHUA tumor cell line was performed, and the abilities of the microcell hybrids to form tumors in nude mice were examined. The introduction of a chromosome 19 had no effect on the tumorigenicity of the cells, whereas microcell-hybrid clones with an introduced chromosome 1, 6 or 9 were completely suppressed for tumorigenicity. A decrease in tumor-take incidence in some but not all clones was observed following the introduction of a chromosome 11. The nontumorigenic microcell hybrids with an introduced chromosome 1 differed from the nontumorigenic microcell hybrids with an introduced chromosome 6, 9, or 11. A large percentage of hybrids with chromosome 1 senesced and/or showed alterations in cellular morphology and transformed growth properties in vitro. No growth or morphology alterations were observed following transfer of the other chromosomes. These results may indicate that more than one chromosome carries a tumor suppressor gene(s) for this human uterine endometrial carcinoma cell line and support the hypothesis that multiple tumor suppressor genes control the tumorigenic phenotype in the multistep process of neoplastic development.     

Chromosome 13q12 region critical for the viability and growth of nasopharyngeal carcinoma hybrids

Allelic losses of chromosome 13 are often detected in nasopharyngeal carcinoma (NPC) and other cancers, implicating the presence of possible tumor suppressor genes (TSGs) on this chromosome. To identify candidate regions from larger and multiple lost areas observed from direct tumor studies, the technique of monochromosome transfer was utilized to provide functional evidence to verify and define these deletion findings. An intact chromosome 13 was transferred into the NPC HONE1 cell line. Resultant hybrids were used to map putative TSG activity. A critical region at 13q12 was non-randomly eliminated in all surviving microcell hybrids around the marker D13S893; these hybrids were uniformly tumorigenic. Although a known TSG, BRCA2, is mapped close to this critical region, no aberrant expression of this gene was detected in microcell hybrids and other NPC cell lines. These results suggest that at least one novel growth control gene on chromosome 13q12, which is not the BRCA2 gene, is essential for hybrid selection and may play a critical role in tumorigenicity.     

Suppression of tumorigenesis by the breast cancer cell line MCF-7 following transfer of a normal human chromosome 11.

Breast cancer development is associated with several genetic abnormalities. Loss of heterozygosity in the short arm of chromosome 11 has been observed in 30% of tumors. We found homozygosity at five chromosome 11 polymorphic loci in genomic DNA of the MCF-7 breast carcinoma cell line, suggesting a possible loss of one chromosome 11. We have studied the transformed and tumorigenic phenotypes of MCF-7 cells following introduction of a normal human chromosome 11 via microcell fusion. MCF-7/H11 cell hybrids, containing chromosome 11, showed in vitro characteristics similar to the parental cell line. However, tumorigenicity in athymic mice was completely suppressed. Since tumor formation by MCF-7 cells is estrogen dependent, we have analysed the expression of the estrogen receptor and of the estrogen-activated gene pS2. No difference was detected between the parental MCF-7 cells and the derived chromosome 11 cell hybrids, indicating that the mechanism of MCF-7 tumor suppression by chromosome 11-associated functions does not directly involve the estrogen/estrogen receptor molecular pathway.     

Suppression of acute lymphoblastic leukemia by the human wild-type p53 gene.

Independent mutations in both alleles of the p53 tumor suppressor gene are a frequent finding in human T-cell acute lymphoblastic leukemia (T-ALL) cell lines and in the cells of some T-ALL patients in relapse. One major goal of studying the status of p53 (and other tumor suppressor genes) in human cancer is to facilitate the suppression of the tumorigenic phenotype through the restoration of the expression of the wild-type allele. While the efficient insertion of a suppressor into all cells of solid/metastatic human tumors may at present be impossible, insertion into leukemia cells may be feasible due to the accessibility of the leukemia cells in the body. To examine the feasibility of suppressing the tumorigenicity of human T-leukemia cells, the human T-ALL cell line Be-13, which lacks endogenous p53 protein, was infected with a recombinant retrovirus encoding the wild-type allele of human p53 (hwtp53). Expression of p53 reduced the growth rate of infected Be-13 cells in vitro, suppressed colony formation in methylcellulose cultures, and abrogated their tumorigenic phenotype in nude mice in vivo. These results suggest that suppression of the leukemic phenotype of relapse T-ALL-derived Be-13 cells is feasible. Acute leukemia cell suppression via high-efficiency infection with retroviruses encoding wtp53 may be feasible and beneficial in T-ALL cases as part of a bone marrow transplantation regimen in an effort to reduce the frequency of posttransplantation relapse.     

Characterization of intestinal alkaline phosphatase expression and the tumorigenic potential of gamma-irradiated HeLa x fibroblast cell hybrids

Fusion of tumorigenic HeLa cells with human skin fibroblasts results in genetically stable hybrids which are nontumorigenic and no longer express the HeLa tumor-associated antigen, intestinal alkaline phosphatase (IAP). Previous analysis of spontaneous segregants of the nontumorigenic hybrid have implicated the loss of one copy of human fibroblast chromosome 11 with reexpression of IAP and tumorigenicity. This observation suggests that a putative HeLa tumor suppressor gene(s) is located on chromosome 11 and that this gene may be a negative regulator of the IAP gene. We have isolated several gamma-ray-induced mutants (GIMs) of the nontumorigenic HeLa x skin fibroblast hybrid CGL1 that were specifically selected for reexpression of IAP to further investigate the potential linkage between IAP regulation and the putative tumor suppressor locus. The GIMs have a wide range of cell morphology and level of IAP expression (nearly a factor of 40). The tumorigenicity of the GIMs was examined by s.c. injection into nude mice and all were found to be tumorigenic. The tumor volume-doubling time is in the range of 4 to 8 days for all the cell lines; however, the lag time to reach 500 mm3 tumor volume was significantly longer when the GIM IAP activity was low (less than 20% relative activity), suggesting perhaps that there is a threshold level of IAP expression required for tumor formation and selection for high IAP expression in vivo. However, studies with tumor reconstitutes of the GIMs and transfection studies with an IAP complementary DNA expression vector indicate that high IAP expression alone is not sufficient to confer rapid tumor growth. Therefore, while the data lend strong support to the continued tight correlation between IAP reexpression and tumorigenicity and to our proposal that the tumor suppressor may negatively regulate the IAP gene, it suggests that selection for other gene activities may be responsible for aggressive tumor growth in this cell hybrid system.     

Evidence for human DNA-mediated transfer of the suppressed phenotype into malignant Chinese hamster cells.

Genetic suppression of the neoplastic phenotype has been demonstrated in somatic cell hybrids between tumor and normal cells. Suppression in whole-cell and microcell hybrids cannot, as yet, be attributed to specific elements defined at the molecular level. To identify a gene capable of suppressing the neoplastic phenotype, we have introduced DNA of normal human cells into tumorigenic Chinese hamster Wg3-h-o cells. Primary and secondary transfectants which exhibit the suppressed phenotype similar to Wg3-h-o x embryonic fibroblast hybrids were selected. The cells require serum growth factors and anchorage for proliferation in vitro and show a reduced tumorigenicity in nude mice. Transferred human DNA segments were molecularly cloned from a secondary transfectant. Indirect evidence suggests that the cloned human DNA is associated with the expression of the suppressed phenotype.     

Alteration of tumorigenicity in undifferentiated thyroid carcinoma cells by introduction of normal chromosome 11

The tumorigenicity of various cell lines has been shown to be suppressed by the introduction of chromosome 11 and other chromosomes via micro-cell-mediated chromosome transfer. In this study, we investigated whether a human undifferentiated thyroid carcinoma cell line, TTA-1, was suppressed by the introduction of normal human chromosome 11 or 10. Chromosome 10 or 11 was transferred from A₉ cells containing a single human chromosome 10 or 11 tagged with pSV₂-neo plasmid DNA into TTA-1 cells, by microcell fusion. The tumorigenicity of the TTA-1 cells and their colony-forming efficiency in soft agar were suppressed by chromosome 11, but not by chromosome 10. These results suggest that normal human chromosome 11 carries a putative tumor suppressor gene that affects the tumor-associated phenotypes of TTA-1 cells. © Wiley-Liss, Inc.     

Suppression of tumorigenicity and anchorage-independent growth of BK virus-transformed mouse cells by human chromosome 11.

Viral transformation models may be useful for detecting and mapping human tumor suppressor genes. BK virus (BKV), a human papovavirus, readily transforms rodent cells but is unable to transform human cells, suggesting that oncosuppressive functions expressed in human cells control BKV oncogenic activity. We have transferred human chromosome 11 to BKV-transformed mouse cells. All of the cell clones were suppressed in the tumorigenic phenotype and anchorage-independent growth, except one clone which was nontumorigenic but maintained the ability to grow in soft agar. Cytogenetic analysis and DNA hybridization with chromosome 11-specific probes showed that all the reverted hybrids had an intact human chromosome 11, except the clone growing in semisolid medium which had lost the short arm. The results suggest that a gene located on 11p controls anchorage independence, whereas a gene on 11q controls the tumorigenicity of BKV-transformed cells. BKV T-antigen was expressed in all the hybrid clones at the same level as in the parental cell line, indicating that the putative human tumor suppressor gene(s) do not inhibit expression of the viral oncogene and must operate by another mechanism in inducing reversion of the oncogenic phenotype. Since BKV-transformed mouse cells are highly susceptible to retrovirus infection, this model can be used for searching and cloning tumor suppressor gene(s) by retrovirus-mediated "insertional mutagenesis".     

Suppression of tumorigenicity in hybrids of tumorigenic Chinese hamster cells and diploid mouse fibroblasts: dependence on the presence of at least three different mouse chromosomes and independence of hamster genome dosage

Somatic cell hybrids were generated between Chinese hamster cell lines (Cl-4 and TK 17-O) with a near-diploid number of partially abnormal chromosomes and embryonic mouse fibroblasts (BALB/c). Hybrids harboring a near-diploid, near-triploid, and near-tetraploid set of hamster chromosomes plus 22 to 30 mouse chromosomes were analyzed for the expression of the transformed or tumorigenic phenotype, respectively, indicated by their capacity to form colonies in soft agar and by tumor formation after s.c. injection into nude mice. The hybrids showed (partial) suppression of tumorigenicity and of anchorage independence. The minimum number of hybrid cells required to initiate tumor growth in nude mice was 100- to 50,000-fold higher, and the latency period was 3- to 6-fold longer in comparison with the highly tumorigenic parental hamster cells. Suppression of tumorigenicity was also found in intraspecific Chinese hamster hybrids involving tumorigenic cells (E 36-O and TK 17-O) and embryonic hamster fibroblasts. To identify those mouse chromosomes associated with suppression of tumorigenicity, we investigated the expression of mouse isozyme genes and the presence of mouse chromosomes in interspecific suppressed hybrids and their tumorigenic hybrids described previously. No single mouse chromosome, even if present in two copies, and no combination of two different mouse chromosomes was sufficient to suppress tumorigenicity in these hybrids. This conclusion is based on either the presence of these chromosomes in hybrids isolated from tumors or their absence in suppressed hybrids.     

Functional localization of a melanoma tumor suppressor gene to a small (< or = 2 Mb) region on 11q23.

We have previously demonstrated the existence of a melanoma tumor suppressor gene(s) on the long arm of chromosome 11 through suppression of tumorigenicity assays. Although loss of heterozygosity studies also support this finding, only a large critical region (44 cM) has been identified to date on 11q22-25. To further localize a tumor suppressor gene(s) within this region, we have now generated and characterized nine melanoma microcell hybrids, each retaining an introduced fragment of 11q. Of the nine hybrids, four were suppressed for tumor formation in nude mice, while five formed tumors at the same rate as the parental melanoma cell line (UACC 903). Molecular analysis of the hybrids with 118 microsatellite markers narrowed the location of a putative suppressor gene to a small (< or =2 Mb) candidate region on 11q23 between the markers D11S1786 and D11S2077 and within the larger region frequently deleted in melanoma tumors and cell lines. While multiple tumor suppressor genes are likely to reside on 11q22-25, the presence of this region in all four suppressed hybrids supports the simplest model that a single locus is responsible for the suppressed phenotype observed in UACC 903.