Introduction Of Human Chromosome Research Articles

Human chromosome 3p21.3 carries TERT transcriptional regulators in pancreatic cancer

Frequent loss of heterozygosity (LOH) on the short arm of human chromosome 3 (3p) region has been found in pancreatic cancer (PC), which suggests the likely presence of tumor suppressor genes in this region. However, the functional significance of LOH in this region in the development of PC has not been clearly defined. The human telomerase reverse transcriptase gene (hTERT) contributes to unlimited proliferative and tumorigenicity of malignant tumors. We previously demonstrated that hTERT expression was suppressed by the introduction of human chromosome 3 in several cancer cell lines. To examine the functional role of putative TERT suppressor genes on chromosome 3 in PC, we introduced an intact human chromosome 3 into the human PK9 and murine LTPA PC cell lines using microcell-mediated chromosome transfer. PK9 microcell hybrids with an introduced human chromosome 3 showed significant morphological changes and rapid growth arrest. Intriguingly, microcell hybrid clones of LTPA cells with an introduced human chromosome 3 (LTPA#3) showed suppression of mTert transcription, cell proliferation, and invasion compared with LTPA#4 cells containing human chromosome 4 and parental LTPA cells. Additionally, the promoter activity of mTert was downregulated in LTPA#3. Furthermore, we confirmed that TERT regulatory gene(s) are present in the 3p21.3 region by transfer of truncated chromosomes at arbitrary regions. These results provide important information on the functional significance of the LOH at 3p for development and progression of PC.

Repression of hTERT transcription by the introduction of chromosome 3 into human oral squamous cell carcinoma

Telomerase is a ribonucleoprotein enzyme that maintains telomere length. Telomerase activity is primarily attributed to the expression of telomerase reverse transcriptase (TERT). It has been reported that introduction of an intact human chromosome 3 into the human oral squamous cell carcinoma cell line HSC3 suppresses the tumorigenicity of these cells. However, the mechanisms that regulate tumorigenicity have not been elucidated. To determine whether this reduction in tumorigenicity was accompanied by a reduction in telomerase activity, we investigated the transcriptional activation of TERT in HSC3 microcell hybrid clones with an introduced human chromosome 3 (HSC3#3). HSC#3 cells showed inhibition of hTERT transcription compared to that of the parental HSC3 cells. Furthermore, cell fusion experiments showed that hybrids of HSC3 cells and cells of the RCC23 renal carcinoma cell line, which also exhibits suppression of TERT transcription by the introduction of human chromosome 3, also displayed suppressed TERT transcription. These results suggested that human chromosome 3 may carry functionally distinct, additional TERT repressor genes.

AIM1 and LINE-1 Epigenetic Aberrations in Tumor and Serum Relate to Melanoma Progression and Disease Outcome

Aberrations in the methylation status of non-coding genomic repeat DNA sequences and specific gene promoter region are important epigenetic events in melanoma progression. Promoter methylation status in LINE-1 and Absent in melanoma-1(AIM1;6q21) associated with melanoma progression and disease outcome was assessed. LINE-1 and AIM1 methylation status was assessed in paraffin-embedded archival tissues(PEAT)(n=133) and melanoma patients’ serum(n=56). LINE-1 U-Index(hypomethylation) and AIM1 were analyzed in microdissected melanoma PEAT sections. The LINE-1 U-Index of melanoma(n=100) was significantly higher than that of normal skin(n=14) and nevi(n=12)(P=0.0004). LINE-1 U-Index level was elevated with increasing AJCC stage(P<0.0001). AIM1 promoter hypermethylation was found in higher frequency(P=0.005) in metastatic melanoma(65%) than in primary melanomas(38%). When analyzed, high LINE-1 U-Index and/or AIM1 methylation in melanomas were associated with disease-free survival(DFS) and overall survival(OS) in Stage I/II patients (P=0.017, 0.027; respectively). In multivariate analysis, melanoma AIM1 methylation status was a significant prognostic factor of OS(P=0.032). Furthermore, serum unmethylated LINE-1 was at higher levels in both stage III(n=20) and stage IV(n=36) patients compared to healthy donors(n=14)(P=0.022). Circulating methylated AIM1 was detected in patients’ serum and was predictive of OS in Stage IV patients (P=0.009). LINE-1 hypomethylation and AIM1 hypermethylation have prognostic utility in both melanoma patients’ tumors and serum.

Localization of an hTERT repressor region on human chromosome 3p21.3 using chromosome engineering

Telomerase is a ribonucleoprotein enzyme that synthesizes telomeric DNA. The reactivation of telomerase activity by aberrant upregulation/expression of its catalytic subunit hTERT is a major pathway in human tumorigenesis. However, regulatory mechanisms that control hTERT expression are largely unknown. Previously, we and others have demonstrated that the introduction of human chromosome 3, via microcell-mediated chromosome transfer (MMCT), repressed transcription of the hTERT gene. These results suggested that human chromosome 3 contains a regulatory factor(s) involved in the repression of hTERT. To further localize this putative hTERT repressor(s), we have developed a unique experimental approach by introducing various truncated chromosome 3 regions produced by a novel chromosomal engineering technology into the renal cell carcinoma cell line (RCC23 cells). These cells autonomously express ectopic hTERT (exohTERT) promoted by a retroviral LTR promoter in order to permit cellular division after repression of endogenous hTERT. We found a telomerase repressor region located within a 7-Mb interval on chromosome 3p21.3. These results provide important information regarding hTERT regulation and a unique method to identify hTERT repressor elements.

The functional evidence for metastasis suppressor genes of liver cancer harboring on chromosome 8

Objective To find out the functional evidence for metastasis suppressor gene in liver cancer on human chromosome 8p. Methods The microcell hybrid clones Neo8/C5F-1-10, which were generated by introducing human chromosome 8 randomly marked with neo gene into C5F cell line by mi-crocell mediated chromosome transfer (MMCT) and the C5F cell line were subcutaneously implanted in 6-7 week-old female BALB/CA nude mice to perform the spontaneous metastasis assay. Serial dissections of the lung tissues were done to count the microscopic metastatic foci. The number of the metastatic foci was compared by one-way ANOVA. Results All the microceli hybrids implanted had grown into measurable tumors subcutaneously. The spontaneous metastasis assay for these microcell hybrid clones showed that 6 clones displayed prominent lung metastasis suppression (P<0.05). Among 2 of them, lung metastases had been totally suppressed. Conclusion The successful introduction of human chromosome 8 into meta-static rat liver cancer cell line had changed the metastatic behavior of C5F, which provided the direct func-tional evidence for the metastasis suppressor gene in liver cancer harboring on human chromosome 8. Key words: Carcinoma,hepatocellular; Chromosomes; Metastasis; Suppressor genes

Gene expression profiling to identify markers associated with deregulated hTERT in HPV‐transformed keratinocytes and cervical cancer

Although high-risk human papillomavirus (HPV) infection plays a major role in the development of cervical cancer, additive oncogenic events are involved as well. One key event involves increased activity of telomerase resulting from a deregulated expression of its catalytic subunit hTERT. Our previous microcell-mediated chromosome transfer studies revealed that introduction of human chromosome 6 in the HPV16-immortalized keratinocyte cell line FK16A and in the HPV16-containing cervical cancer cell line SiHa induced growth arrest, resulting from a repression of hTERT mRNA expression and telomerase activity. Here, this model was used to analyze expression profiles associated with hTERT deregulation in HPV-transformed cells. Microarray expression analysis of 12 FK16A/chromosome 6 hybrids, 4 of which were negative for endogenous hTERT and 8 of which were positive for endogenous hTERT, resulted in the identification of 164 differentially expressed genes. Differential expression of a selection of 5 genes was verified by real-time RT-PCR. Of these 164 genes, 32 were also differentially expressed in other HPV transformed cells with deregulated hTERT. For 2 of these genes, encoding AQP3 and MGP, altered expression in hTERT positive cervical carcinomas was confirmed by real-time RT-PCR and immunohistochemistry, respectively. Moreover, increased MGP protein expression was significantly more frequent in high-grade cervical premalignant lesions with elevated hTERT mRNA expression compared to those without. In summary, we identified 32 candidate biomarkers for deregulated hTERT mRNA expression, which may enable the identification of cervical premalignant lesions that are at highest risk to progress to invasive cancer.

Differences in Apoptosis and Cell Cycle Distribution between Human Melanoma Cell Lines UACC903 and UACC903(+6), before and after UV Irradiation

Introduction of human chromosome 6 into malignant melanoma cell line UACC903 resulted in generation of the chromosome 6-mediated suppressed cell subline UACC903(+6) that displays attenuated growth rate, anchorage-dependency, and reduced tumorigenicity. We have showed that overexpression of a chromosome 6-encoded tumor suppressor gene led to partial suppression to UACC903 cell growth. We now describe the differences in apoptosis and cell cycle between UACC903 and UACC903(+6) before and after UV irradiation. MTT assay revealed 86.92+/-8.24% of UACC903 cells viable, significantly (p<0.01) higher than 48.76+/-5.31% of UACC903(+6), at 24 hr after 254-nm UV irradiation (40 J/M(2)). Before UV treatment, flow cytometry analysis revealed 6.06+/-0.20% apoptosis in UACC903, significantly (p=0.01) lower than 6.67+/-0.15% in UACC903(+6). The G0/G1, S and G2/M phase cells of UACC903 were, respectively, 54.10+/-0.59%, 22.31+/-0.50% and 16.85+/-0.25%, all significantly (p<0.01) different from the corresponding percentages (58.82+/-0.35%, 20.48+/-0.05%, and 13.17+/-0.45%) of UACC903(+6). After the UV treatment, UACC903 cells in apoptosis, G0/G1, S, and G2/M became 12.59+/-0.17%, 38.90+/-0.67%, 19.74+/-0.70%, and 27.01+/-0.66%, respectively, while UACC903(+6) cells were 24.16+/-0.48%, 37.97+/-0.62%, 19.20+/-0.52%, and 15.69+/-0.14%. TUNEL assay revealed 2.31+/-0.62% apoptosis in UACC903, significantly (p<0.01) lower than 9.60+/-1.14% of UACC903(+6), and a linear and exponential increase of apoptosis, respectively, in response to the UV treatment. These results indicate that UACC903(+6) cells have a greater tendency to undergo apoptosis and are thus much more sensitive to UV irradiation. Our findings further suggest a novel mechanism for chromosome 6-mediated suppression of tumorigenesis and metastasis, i.e., through increased cell death.

Induction of cellular senescence in a telomerase negative human immortal fibroblast cell line, LCS-AF.1-3, by human chromosome 6.

In immortal cells (LCS-AF.1-3) which originated from cultured skin fibroblasts from a patient with Li-Fraumeni syndrome, a specific deletion has been identified on chromosome 6. To examine the relationship between this deletion and the loss of function in aging genes, we performed microcell mediated chromosome transfer (MMCT) of normal human chromosome 6 into LCS-AF.1-3 cells and analyzed their characteristics. Transferred human chromosome 6 induced morphological changes in the cells and cellular senescence with growth suppression. In a revertant clone that had escaped from induced senescence, a specific deletion was found at D6S309 in the transferred chromosome 6. High molecular weight telomeric sequences were lost in a clone that had been induced to senescence by introduction of human chromosome 6. On the other hand, human chromosome 7 induces senescence in immortal cells by suppressing the alternative lengthening of telomere (ALT) mechanism. We also performed MMCT of chromosome 7 and discuss the effect of chromosome transfer by comparing the two chromosomes. LCS-AF.1-3 cells containing a transferred chromosome 7 showed no changes in immortality. These results suggest that genes which are new candidates for aging and which suppress the ALT mechanism are located in the region D6S309 in human chromosome 6.

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.

Telomerase suppression by chromosome 6 in a human papillomavirus type 16-immortalized keratinocyte cell line and in a cervical cancer cell line.

High-risk human papillomavirus (HPV) types play a major role in the development of cervical cancer in vivo and can induce immortalization of primary human keratinocytes in vitro. Activation of the telomere-lengthening enzyme telomerase constitutes a key event in both processes. Because losses of alleles from chromosome 6 and increased telomerase activity have been observed in high-grade premalignant cervical lesions, we analyzed whether human chromosome 6 harbors a putative telomerase repressor locus that may be involved in HPV-mediated immortalization. Microcell-mediated chromosome transfer was used to introduce chromosomes 6 and 11 to the in vitro generated HPV type 16 (HPV16)-immortalized keratinocyte cell line FK16A and to the in vivo derived HPV16-containing cervical cancer cell line SIHA: Hybrid clones were analyzed for growth characteristics, telomerase activity, human telomerase reverse transcriptase (hTERT) and HPV16 E6 expression, and telomere length. FK16A hybrid clones were also transduced with an hTERT-containing retrovirus to examine the effect of ectopic hTERT expression on growth. Statistical tests were two-sided. Introduction of human chromosome 6 but not of chromosome 11 to both cell lines yielded hybrid cells that demonstrated crisis-like features (i.e., enlarged and flattened morphology, vacuolation, and multinucleation) and underwent growth arrest after a marked lag period. In the chromosome 6 hybrid clones analyzed, telomerase activity and hTERT messenger RNA (mRNA) expression were statistically significantly reduced compared with those in the chromosome 11 hybrid clones (for telomerase activity, P =.004 for the FK16A hybrids and P =.039 for the SiHa hybrids; for hTERT mRNA expression, P =.003 for the FK16A hybrids). The observed growth arrest was associated with telomeric shortening. Ectopic expression of hTERT in FK16A cells could prevent the telomeric shortening-based growth arrest induced by chromosome 6. Chromosome 6 may harbor a repressor of hTERT transcription, the loss of which may be involved in HPV-mediated immortalization.

Introduction of Chromosome 7 Suppresses Telomerase with Shortening of Telomeres in a Human Mesothelial Cell Line

Introduction of human chromosome 7 by microcell-mediated chromosome transfer induced senescence in a telomerase-positive human mesothelial cell line, MeT5A. In microcell hybrids which underwent senescence, telomerase activity was decreased before entering senescence and telomeric sequences were shortened as cell division proceeded. Concomitantly, expression of the gene encoding telomerase catalytic subunit was abolished, whereas the genes encoding the RNA component of telomerase and its associated protein TEP1 were not affected. In revertants which arose from such microcell hybrids, telomerase activity was restored and the telomeric sequences were elongated. In microcell hybrids which showed no growth arrest, telomerase activity was unaltered. These results suggest that a putative mortality gene on chromosome 7 negatively regulates the telomere maintenance mechanism in MeT5A.

Suppression of tumorigenicity of rat liver epithelial tumor cell lines by a putative human 11p11.2-p12 liver tumor suppressor locus.

We have previously identified and mapped a locus within human chromosome 11p11.2-p12 that suppresses the tumorigenic potential of a rat liver tumor cell line (termed GN6TF) which contains well defined chromosomal aberrations involving rat chromosomes 1, 4, 7, and 10. In the present study, we investigated the potential of this human 11p11.2-p12 liver tumor suppressor locus to suppress the tumorigenic potential of two other rat liver tumor cell lines (GN3TG and GP10TA) following microcell-mediated introduction of human chromosome 11. These tumor cell lines are aneuploid and contain chromosomal abnormalities that are similar to the GN6TF tumor line. The tumorigenic potential and other phenotypic characteristics of GN3TG-11neo and GP10TA-11neo microcell hybrid (MCH) cell lines were variable, and dependent upon the status of the introduced human chromosome 11. MCH cell lines that retained the region of 11p11. 2-p12 delineated by microsatellite markers D11S1385 and D11S903 exhibited suppression of tumorigenicity in vivo (decrease in tumorigenicity and/or elongation of latency), whereas, the tumorigenic potential of one MCH line that lacked markers in this region of human 11p11.2-p12, but retained flanking markers, was not changed from that of the parental tumor cell line. The chromosomal interval between microsatellite markers D11S1385 and D11S903 encompasses the previously localized minimal liver tumor suppressor region, suggesting that a common locus is responsible for tumor suppression among the rat liver tumor cell lines examined. The results of the present study have verified the presence of a liver tumor suppressor locus within human 11p11.2-p12, and have identified a substantial number of microsatellite markers that are closely linked to this tumor suppressor region. These chromosomal markers will facilitate positional cloning of candidate genes from this region, and may prove useful for determining the involvement of this locus in the pathogenesis of human liver cancer.

Metastasis suppressor gene(s) for rat prostate cancer on the long arm of human chromosome 7.

Allelotype analyses of human prostate cancer indicate that allelic losses on human chromosome arms 7q, 8p, 10q, 13q, 16q, 17q, and 18q are observed frequently. For the study of the possible biological significance of the frequently observed deletions on chromosome arm 7q in human prostate cancer, human chromosome 7 was introduced into highly metastatic rat prostate cancer cells by use of a microcell-mediated chromosome transfer technique. The introduction of human chromosome 7 resulted in the suppression of metastatic ability of the microcell hybrids, whereas no suppression of tumorigenicity was observed. To identify the portion of chromosome 7 containing the metastasis-suppressive function gene, the derivative chromosome 7 that was generated with the initial transfer was retransferred into rat prostate cancer cells. Human chromosome 7-containing rat prostate cancer cells could be used as the donor cells, because rodent cells produced a sufficient number of microcells with colchicine treatment. Cytogenetic and molecular analyses of these clones demonstrated that loss of segments on 7q was related to the reexpression of the metastatic phenotype. These results show that human 7q contains a metastasis suppressor gene or genes for rat prostate cancer. The findings also suggest that this gene may play an important role in the progression of human prostate cancer.

Decrease in Amplified Telomeric Sequences and Induction of Senescence Markers by Introduction of Human Chromosome 7 or Its Segments in SUSM-1

Introduction of human chromosome 7 by microcell-mediated chromosome transfer suppresses indefinite division of SUSM-1, anin vitroestablished human fibroblast line. This cell line has unusually long telomeric sequences although it lacks detectable telomerase activity. Thus, we examined whether such telomeric sequences change upon introduction of chromosome 7 or its segments. In the microcell hybrids that stopped dividing by introduction of chromosome 7, the telomeric sequences were found to be lost or markedly diminished. Introduction of various fragments (2–40 Mb) of chromosome 7 contained in radiation hybrids gave similar results. On the other hand, the telomeric sequences were not altered significantly in the unsuppressed hybrids, a revertant of one suppressed clone, or subclones of SUSM-1 used as controls. In the suppressed microcell hybrids, the distribution of a mortality marker, mortalin, was changed to the cytosolic type of mortal cells from the immortal type of perinuclear fibres. Also, senescence-associated β-galactosidase was induced to a level similar to that of normally senesced diploid fibroblasts. These results suggest that human chromosome 7 induces senescence in SUSM-1 by suppressing its telomere maintenance mechanism, which does not depend on telomerase.

Selective loss of the hepatic phenotype due to the absence of a transcriptional activation pathway.

Liver-enriched trans-acting factors hepatocyte nuclear factor-1 alpha (HNF1 alpha) and -4 (HNF4) are components of a transcriptional activation pathway that is thought to play a major role in hepatic gene activation. We previously described the isolation and characterization of distinct classes of hepatoma variants which lack the HNF4-->HNF1 alpha pathway (1). In order to determine the influence of the HNF4-->HNF1 alpha pathway on hepatic gene expression, genetic rescue experiments were done using hepatoma variant line H11 as a model system. Results suggest that this pathway is required for basal expression of a number of endogenous hepatocyte-specific genes. Complementation groups were established by fusion of H11 cells with other variant lines. Lastly, introduction of human chromosome 20 (containing the HNF4 locus) or randomly-marked human chromosomes into H11 cells failed to rescue the hepatic phenotype, suggesting that what appears to be a 'simple' defect may involve multiple genetic loci.

Suppression of invasive ability of highly metastatic rat prostate cancer by introduction of human chromosome 8.

Introduction of human chromosome 8 to a highly metastatic subline (AT6.2) from the Dunning R-3327 rat prostate cancer resulted in suppression of metastatic ability of the resultant microcell hybrids (AT6.2-8 clones) [12]. The present study has been performed to clarify which step of metastasis was suppressed in the microcell hybrids. Northern blot analysis of E-cadherin and alpha-catenin, in vitro invasion assay, and intra-venous metastasis assay by injection of tumor cells into the lateral tail vein of nude mice were performed. No detectable expressions of either E-cadherin or alpha-catenin were found in either AT6.2 parental or AT6.2-8 microcell hybrid clones. In the invasion assay, invasiveness of AT6.2-8 hybrid clones was less than that of the AT6.2 parental clone. In the intravenous metastasis assay, no significant differences in the number of lung metastases were observed among these cell lines. Introduction of human chromosome 8 to AT6.2 cells shows suppression of invasiveness and no suppression of cell dissociation or process after entry into blood circulation. This suggests that human chromosome 8 contains suppressor gene(s) for the invasive ability of prostate cancer.

KiSS-1, a novel human malignant melanoma metastasis-suppressor gene.

Microcell-mediated transfer of chromosome 6 into human C8161 and MelJuSo melanoma cell suppresses their ability to metastasize by at least 95% without affecting their tumorigenicity. This observation demonstrates that the ability to metastasize is a phenotype distinct from tumor formation and suggests that tumorigenic cells acquire metastatic capability only after accumulating additional genetic defects. These results also imply that mutations of genes on chromosome 6 are among those late genetic changes responsible for metastatic potential. They further suggest that a melanoma metastasis-suppressor gene(s) is encoded on chromosome 6 or is regulated by genes on chromosome 6. Our objective was to identify the gene(s) responsible for the suppression of metastasis in chromosome 6/melanoma cell hybrids. A modified subtractive hybridization technique was used to compare the expression of messenger RNAs (mRNAs), via an analysis of complementary DNAs (cDNAs), in metastatic cells (C8161 or MelJuSo) and nonmetastatic hybrid clones (neo6/C8161 or neo6/MelJuSo). A novel cDNA, designated KiSS-1, was isolated from malignant melanoma cells that had been suppressed for metastatic potential by the introduction of human chromosome 6. Northern blot analyses comparing mRNAs from a panel of human melanoma cells revealed that KiSS-1 mRNA expression occurred only in nonmetastatic melanoma cells. Expression of this mRNA in normal heart, brain, liver, lung, and skeletal muscle was undetectable by northern blot analysis. Weak expression was found in the kidney and pancreas, but the highest expression was observed in the placenta. The KiSS-1 cDNA encodes a predominantly hydrophilic, 164 amino acid protein with a polyproline-rich domain indicative of an SH3 ligand (binds to the homology 3 domain of the oncoprotein Src) and a putative protein kinase C-alpha phosphorylation site. Transfection of a full-length KiSS-1 cDNA into C8161 melanoma cells suppressed metastasis in an expression-dependent manner. These data strongly suggest that KiSS-1 expression may suppress the metastatic potential of malignant melanoma cells. KiSS-1 may be a useful marker for distinguishing metastatic melanomas from nonmetastatic melanomas.

Metastasis suppressed, but tumorigenicity and local invasiveness unaffected, in the human melanoma cell line MelJuSo after introduction of human chromosomes 1 or 6.

Progression of human melanoma toward increasing malignant behavior is associated with several nonrandom chromosomal aberrations, most commonly involving chromosomes 1, 6, 7, 9, and 10. We previously showed that introduction of human chromosome 6 into the highly metastatic human malignant melanoma cell line C8161 completely suppressed metastasis without altering tumorigenicity (Welch DR, Chen P, Miele ME, et al., Oncogene 9:255-262, 1994). Alterations of chromosome 1 are the most frequent chromosome abnormality observed in melanomas, and they frequently arise late in tumor progression. The purpose of the study presented here was to compare the effects of chromosomes 1 and 6 on malignant melanoma metastasis. By using microcell-mediated chromosome transfer, single copies of neo-tagged human chromosomes 1 or 6 were introduced into the human melanoma cell line MelJuSo. The presence of the added chromosome was verified by G banding of karyotypes, fluorescence in situ hybridization, and screening for polymorphic markers on each chromosome. The incidence and number of metastases per lung after intravenous or intradermal injection of parental MelJuSo cells was significantly (P<0.01) greater than those of hybrids containing either chromosome 1 or chromosome 6, although chromosome 1 was a less potent inhibitor of metastasis than chromosome 6. Cultures established from primary tumors and metastases remained neomycin resistant, suggesting that portions of the added chromosomes were retained. These results strengthen the evidence for the presence of a melanoma metastasis suppressor gene on chromosome 6. neo6/MelJuSo hybrids expressed 2.4- to 3.4-fold more of the melanoma differentiation-associated gene mda-6 (previously shown to be identical to WAF1/CIP1/Sdi1/CAP20) than parental metastatic cells. mda-6/WAF1 is among the candidate genes on chromosome 6. These results also demonstrate, for the first time, the existence of metastasis suppressor genes on human chromosome 1, although these genes appear to be less potent than the one encoded on chromosome 6.

Complementation Mapping in Microcell Hybrids: Localization of XRCC4 to 5q15–q21

Microcell-mediated chromosome transfer (MMCT) offers a unique method for introducing tagged individual human chromosomes from mouse/human monochromosomal hybrids into cell lines displaying recessive mutant phenotypes. Functional analysis of the resultant microcell hybrids bearing different tagged individual human chromosomes permits identification of the complementing chromosome. Using this approach, a number of human DNA repair genes that complement DNA repair defects in Xeroderma pigmentosum, Ataxia telangiectasia, Bloom's syndrome, and rodent mutant cells have been mapped to specific chromosomes. In this paper, we present experiments performed to map a DNA double-strand break (dsb) repair gene, XRCC4, to human chromosome 5q15–q21. The introduction of human chromosome 5 into Chinese hamster mutant XR-1 cells corrected their X-ray sensitivity and DNA dsb repair deficiency. Loss of chromosome 5 and concomitant reversion to the radiosensitive phenotype confirmed the presence of XRCC4 on this chromosome. Analysis of DNA markers in radiation-resistant and -sensitive clones bearing different segments of chromosome 5 placed this gene in the region 5q15–q21. These studies demonstrate the application of MMCT technology to the genetic analysis of mutations that escape other experimental approaches.

Human chromosome 11 inhibits tumorigenicity of a murine squamous cell carcinoma cell line.

Loss of heterozygosity (LOH) of mouse chromosome 7 has been consistently demonstrated in chemically induced murine squamous cell carcinomas (SCCs). The region of this chromosome presenting LOH in the mouse tumors is syntenic to human chromosome segments 11p15 and 11q. To determine whether the introduction of human chromosome (Hchr) 11 can suppress the growth of murine SCC, we injected four clones of a chemically induced murine SCC cell line bearing an Hchr 11 into athymic BALB/c nude mice. All microcell hybrid clones with Hchr 11 (CH72/Hchr 11) had latency periods twice as long as those of the parental CH72 cells and control hybrids containing a Hchr 12. Tumor-derived cells from CH72/Hchr 11 hybrids had lost centromeric and telomeric sequences from Hchr 11. All repressed cell lines grew significantly more slowly in vitro than did the controls. These results suggest that Hchr 11 contains a tumor-suppressor gene capable of inhibiting tumorigenicity in chemically induced SCC, confirming common pathways in the development of human neoplasias and the murine model.