Cytogenetic analysis of human renal carcinoma cell lines of common origin (NC 65).

Cytogenetic analyses were performed on 3 clonal cell lines derived from a human renal cell carcinoma and its lymph node metastasis, two long-term tissue culture cell lines (NC 65-Sp and NC 65-R) and a serially transplantable tumor line growing on nude mice and brought into culture at the fifth animal passage (NC 65-V). Karyotype were established using banding techniques. Most of the marker chromosomes could be identified and were derived by deletion, inversion, translocation, or isochromosome formation of Chromosomes 1, 3, 4, 5, 8, 9, and 17. These markers were different from HeLa markers. NC 65-Sp had a near diploid chromosome number, NC 65-R a hypotetraploid number, and NC 65-V had a bimodal chromosome number, and NC 65-V had a bimodal chromosome number. Three chromosome markers were shared by the three cell lines; NC 65-R and NC 65-V shared an additional set of four markers. Markers specific to each line were also observed; they demonstrated the independent derivation of the lines and eliminated laboratory cross-contamination. Common markers between the lines confirmed their common tumoral origin.     

Cytogenetic and molecular genetic analysis of tumorigenic human bronchial epithelial cells induced by radon alpha particles

To establish a cell culture model for lung carcinogenesis, independent populations of the human papillomavirus 18-immortalized human bronchial epithelial cell line BEP2D were treated with high linear energy transfer radon-simulated alpha-particles, expanded and xenotransplanted into Nu/Nu mice. Six independent cell lines were established from tumors that developed from three separate radiation treatments as follows: treatment (Tx) 1 (30 cGy--two doses), H2BT, Tx 2 (30 cGy-- single dose), R30T1L, R30T2 and R30T3L, Tx 3 (30 cGy--single dose), H1ATN and H1ATBA1. Cytogenetic analysis revealed common changes in all tumor lines: loss of the Y chromosome (ch), one of three copies of ch8, one of three copies of ch14, and one of two copies of ch4p16-pter and ch11p15-pter. Analysis of polymerase chain reaction-amplified short tandem repeats of informative loci confirmed the loss of chY in all lines and loss of heterozygosity (LOH) at eight loci spanning the length of ch8 in all lines from Tx's 1 and 2. Our data support previous studies indicating the presence of tumor suppressor genes on ch8. LOH also was confirmed on ch14 at locus D14S306 in all cell lines from Tx 2 and in one of two lines from Tx 3. This region, 14q12-q13, may contain changes in one of the five known somatostatin receptor genes (SSTR1). No LOH was detected at any of the informative loci tested for on ch4 or ch11.      

Integration of human papillomavirus 16 DNA and genomic rearrangements in immortalized human keratinocyte lines

Five foreskin-derived keratinocyte lines, immortalized by transfection of human papillomavirus (HPV16) DNA, were cytogenetically abnormal, exhibiting numerical deviations and altered chromosomes due to translocations, deletions, achromatic lesions, or partial duplications. Furthermore, all lines had cells with either homogeneously staining regions or double minute chromosomes, alterations associated with malignancy or drug resistance. None of these lines were tumorigenic in nude mice, showing that such alterations which are a manifestation of DNA amplification also occur in nonneoplastic cells. By in situ chromosome hybridization, viral sequences were identified on abnormal chromosomes at the junction of chromosome translocations, at achromatic lesions and within homogeneously staining regions and duplicated chromosome segments. Thus, for the first time in an experimental system, HPV16 integration into the cellular genome was associated with the induction of a subset of chromosome alterations. HPV16 integration that frequently occurred at fragile sites and near protooncogenes may be a critical alteration which confers a selective growth advantage and an indefinite proliferative potential to HPV-transfected cells.     

Cumulative gene and chromosome alterations associated with in-vitro neoplastic transformation of human cervical cells

The development of cancer is a multistep process requiring cumulative genetic alterations. An in vit ro model utilizing human cervical cells and papillomaviruses (HPV) that mimics human cervical cancer has been developed. Chromosome and gene alterations associated with distinctive stages of neoplastic transformation were demonstrated with an exocervical cell line obtained after sequential transfection with recombinant HPV-16 DNA and v-Ha-ras oncogene. Acquisition of immortality after HPV-16 transfection was associated with aneuploidy, structural changes of chromosomes 8, 10, 17, 19, 20, and 21, as well as proto-oncogene alterations. HPV-16 DNA was localized to two sites on chromosome 21, with one site at 21q22.2-22.3 near the ets-2 proto-oncogene. Ets-2 as well as c-myc gene mRNA levels were elevated in HPV immortal cells compared to primary nontransfected exocervical strains. Although the HPV-immortalized cells had several features characteristic of malignant cells, they lacked tumorigenic potential. Tumorigenicity occurred after transfection with v-Ha-ras oncogene, which was found stably integrated on chromosome 12 at the telomeric band q24.3. The tumorigenic line had additional clonal chromosomal abnormalities; consisting of multiple deletions involving regions of chromosomes 1p/q, 3p, 9q, loss of one copy of chromosome 11, and a complex rearrangement of chromosomes 8 and 13 as shown by in situ suppression hybridization with whole chromosome probes. Loss of tumor suppressor genes on deleted regions may have contributed to the acquisition of tumorigenicity. The genetic changes observed in these cells parallel those found in cervical carcinomas, demonstrating the validity of the in vitro model for studying the multistep progression resulting in cervical carcinoma.     

Cytogenetic analysis of rat cells, transformed by human papillomavirus genes

Chromosomal analysis of immortalized rat embryo fibroblasts (IE5) and transformed by HPV18 E6+E7 genes (A4E5) or HPV16 E7 alone (trB4; trF8; trC2) variants have been done. Transformed cell lines represented heterogeneous cell populations containing neardiploid subpopulations with 41-44 chromosomes and also heterogeneous polyploid cells in contrast to immortal cells IE5 that contained normal number of chromosomes-42. In transformed cells the abnormalities of interphase nuclei (giant-, micro-, apoptotic nuclei) were observed which could reflect genomic instability of polyploid cells. Several chromosomal alterations were revealed in immortal IE5 cells, but only reciprocal translocation t(8; 10) (q22q12.3) was stable and kept in cells transformed by HPV18 E6+E7 genes or HPV16 E7 alone. We can conclude that genomic instability and clonal expansion of the cells with specific chromosomal alterations contribute to HPV-mediated transformation.     

Stability of cytogenetic alterations in a human melanoma cell line and five clonal derivatives

A cytogenetic study was done on a human malignant melanoma cell line and its 5 clones. Chromosome banding analysis indicated the presence of 7 "shared" markers (M) and 9 unique markers (m) that were present only in the clones. Chromosomes 1, 5, 9, 12, 17 and 21 were involved in M-markers and chromosomes 1, 2, 4, 6, 8, 9, 11, 16, 17, 18 and 21 were involved in m-marker formation. Both parental and clonal lines had near-triploid chromosome numbers. A number of M-markers were isochromosomes of the short (p) and long (q) arms of chromosome 1. Our cytogenetic data indicate that the parental line contained subpopulations of cells that were in different stages of karyotypic evolution.     

Molecular and cytogenetic analysis of immortalized human primary keratinocytes obtained after transfection with human papillomavirus type 16 DNA

A proliferating population of human foreskin keratinocytes (presently in the sixtieth passage) has been obtained after transfection with human papillomavirus (HPV) type 16 DNA. In contrast, the control cultures did not survive beyond the sixth passage. Cytogenetic analysis of cells taken from the twelfth passage revealed a heteroploid male karyotype. In approximately 50% of the cells a common marker chromosome was found, suggesting a clonal origin for at least part of the population. This is further substantiated by Southern blot analysis of cellular DNA which revealed oligomeric HPV 16 genomes integrated at a single site within the host DNA. RNA transcribed from the early region of the HPV 16 genome was identified in the cytoplasm. The immortalizing effect of HPV 16 DNA on human keratinocytes could be reproduced in a second experiment. Such cell lines represent an unique system to study the interaction of HPV with its natural target cell in vitro.     

Continuous cell lines with altered growth and differentiation properties originate after transfection of human keratinocytes with human papillomavirus type 16 DNA

Immortalization of human keratinocytes (HKc) by human papillomavirus type 16 (HPV16) is reproducible at a high frequency, is due directly to the presence of the viral sequences in the cells, and occurs independently from the genetic characteristics of the host cells. Ten human keratinocyte strains, each derived from a different individual, were transfected with pMHPV16d and selected with G418. Eight became established lines. Two strains, which failed to grow shortly after successful G418 selection, were negative for HPV16 DNA. No lines were established following transfection of the same HKc strains with vector sequences only. The immortalized lines maintained a constant number of copies of the viral genome integrated into the cellular DNA. Each line showed a unique integration pattern of HPV16 sequences into the cellular genome, but expressed similar patterns of viral messages. Sublines able to grow in the absence of growth factors (epidermal growth factor and bovine pituitary extract), and others which became resistant to differentiation stimuli (serum and calcium) were obtained by selection in growth factor-free medium and serum-supplemented medium, respectively. The establishment of continuous cell lines is a direct consequence of the presence of viral sequences; however, because none of these lines formed tumors in nude mice, additional events must be necessary for progression of malignancy. HPV16-immortalized human keratinocyte lines can be used to investigate and identify the viral factors involved with the modification of growth and differentiation control by HPV16.     

A methylation profile of in vitro immortalized human cell lines

Normal human diploid cells have a limited life span and undergo replicative senescence after various limited population doublings. Cells must pass the senescence barrier to become immortal. The exact mechanisms of immortalization are not clear, although inactivation of the RB pathway, and/or the p53 pathway and activation of telomerase has been shown to be necessary for immortalization of certain cell types with DNA viruses or hTERT. Methylation-associated inactivation of tumor suppressor genes plays an important role in tumor progression. To test if gene-specific methylation contributes to the immortalized and transformed phenotype, we analyzed the methylation status of 17 genes in normal cells immortalized with SV40, hTERT, Ad5, Ad12-SV40 or HPV-18. Some of these immortalized lines were progressively transformed and tumorigenic in nude mice. We observed gene-specific methylation in the in vitro immortalized and transformed cells. SV40 and HPV18 immortalization resulted in different methylation spectra. In SV40- and h-TERT-immortalized prostate epithelial cells, the most frequently methylated gene was RASSF1A, while in HPV18-immortalized cell lines, the RAR-beta2 gene was universally methylated. Immortalization with SV40 resulted in methylation of a greater number of genes than immortalization with HPV. Furthermore, in SV40-immortalized cell lines, methylation affected different genes in fibroblasts compared with epithelial cells, suggesting that different mechanisms may be used by SV40 to immortalize cell lines of different origins. In HPV18-immortalized and subsequently transformed cell lines, the most commonly methylated genes were hormone responsive genes, such as AR, ER-beta and RAR-beta2. In general, more genes were methylated in neoplastically-transformed cell lines than in only immortalized cell lines, indicating that accumulation of epigenetic abnormalities may contribute to oncogenesis.     

Human cervical and foreskin epithelial cells immortalized by human papillomavirus DNAs exhibit dysplastic differentiation in vivo.

Human papillomavirus (HPV) DNAs are detected in approximately 90% of anogenital carcinomas. To assess directly the effect of HPV on squamous differentiation, normal human cervical and foreskin epithelial cells and cells immortalized by recombinant HPV DNAs were transplanted beneath a skin-muscle flap in athymic mice. Xenografts containing normal cells formed well-differentiated stratified squamous epithelia 2 to 3 weeks after transplantation, but cell lines immortalized by four HPV types (HPV16, HPV18, HPV31, and HPV33) detected in anogenital cancer exhibited dysplastic morphology and molecular alterations in gene expression characteristic of intraepithelial neoplasia. Morphological alterations were accompanied by delayed commitment to terminal differentiation, alterations in the pattern of involucrin expression, and reductions in levels of involucrin and keratin 1 RNAs. HPV18-immortalized cells developed dysplastic changes more rapidly than cells immortalized by HPV16 DNA. These results show that human genital epithelial cells immortalized by HPV DNAs detected in genital cancers undergo dysplastic differentiation in vivo.     

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.     

Radiation-induced deletion of chromosomal regions containing tumor suppressor genes in human bronchial epithelial cells

While several specific genetic alterations have been associatedwith malignant transformation of human bronchial epithelialcells, they are not all present in every tumor and there isreason to believe that additional genes important for loss ofreplication control in these cells remain to be identified.In an effort to develop a human bronchial epithelial cell modelsuitable for identification and functional analysis of genesinvolved in loss of replication control, and for studying thegenetic basis of the multi-stage phenotypic changes associatedwith tumorigenesis, we treated multiple independent populationsof the human papillomavirus (HPV)-immortalized human bronchialepithelial cell line BEP2D with ionizing radiation. Followingirradiation, cell lines representing the radiated populationswere established from single soft agar-selected colonies. Theselines—R2B5SA, R3B5DSA, R2H9S, R2H16S, R2H18S and R3D7S—werecompared cytogenetically to the parent cell line and found tohave new chromosomal deletions involving putative or confirmedtumor suppressor genes, including chromosome 13 in most R2B5SAcells and all R3B5SA cells, chromosomes 11p and 22 in R216S,and 3p, 11p and 22 in R2H18S. The R2B5SA cells that have lostone copy of chromosome 13 overgrow the culture but are not tumorigenic,suggesting that loss of a single copy of chromosome 13 confersgrowth advantage but not tumorigenicity. The data confirm thationizing radiation induces many large chromosomal alterationsincluding chromosomal loss, translocation and deletion and thatfollowing radiation it is possible to isolate immortalized non-tumorigeniccell lines monosomic for regions known or suspected to containtumor suppressor genes. The cell lines described here providepowerful models for further investigation of putative tumorsuppressor genes including identification, functional analysisand stage of transformation at which they are operative.     

Induction of human cervical squamous cell carcinoma by sequential transfection with human papillomavirus 16 DNA and viral Harvey ras

Clinical and epidemiological data are consistent with the hypothesis that human papillomaviruses (HPVs) are a factor in genital, particularly cervical cancer. Although HPV16 and 18 are found primarily in cervical malignancy, the transfection of HPV16 or 18 DNA into cervical cells results in immortalization but not tumorigenicity. The addition of activated Ha-ras, an oncogene found in some cervical cancers expressing HPV16 or 18, to HPV16-immortalized human cervical cells results in malignancy as proven by the formation of cystic squamous cell carcinomas by HPV16-Ha-ras cells in nude mice. This two-stage model utilizing relevant human cells demonstrates that HPVs play a critical role in cervical malignancy and provides a system for elucidating critical cellular changes associated with progression to malignancy.     

Transforming growth factor beta1 promotes chromosomal instability in human papillomavirus 16 E6E7-infected cervical epithelial cells

Uterine cervical cancer, the second most frequently occurring cancer in women worldwide, is tightly associated with the expression of high-risk human papillomavirus [mainly human papillomavirus (HPV)-16 and HPV18] oncogenes E6 and E7 and characteristically exhibits chromosomal instability. However, the mechanisms underlying chromosomal instability in cervical cancer are still not fully understood. In this study, we observed that two of three human cervical epithelial cell lines expressing HPV16 E6E7 became immortalized without extensive chromosomal instability and crisis. The introduction of transforming growth factor (TGF)-beta1, a multiple functional cytokine/growth factor, in the culture medium induced crisis, which was associated with massive chromosomal end-to-end fusions and other structural aberrations. The distributions of structural aberrations on individual chromosomes were significantly correlated with the profiles of telomere signal-free ends. The immortalized cells that emerged from the TGF-beta1-induced crisis showed multiple clonal structural aberrations that were not observed in cells without TGF-beta1 treatment. Overexpression of the catalytic subunit of telomerase (hTERT) abolished the effects of TGF-beta1 on chromosomal instability. Interestingly, another HPV16 E6E7-expressing cervical cell line that experienced crisis and telomere dysfunction under ordinary culture condition had a higher level of autocrine TGF-beta1 production than the other two crisis-free immortalized cell lines. Blocking the TGF-beta1 pathway by an inhibitor of TGF-beta1 receptor type I prevented the crisis and telomere-mediated chromosomal instability. In addition, more dramatic telomere shortening was observed in cervical intraepithelial neoplasias having higher expression of TGF-beta1 in vivo. These results together suggest an important role of TGF-beta1 in the early process of cervical carcinogenesis.     

Immortalization of human adult prostatic adenocarcinoma cells by human papilloma virus HPV16 and — 18 DNA

Primary prostate epithelial and prostate adenocarcinoma cells cultured in serum-free medium grew for up to 10 passages before senescence. Cells from prostate adenocarcinoma of a 55-year-old patient without lymph node involvement were transfected with plasmids containing recombinant human papilloma virus HPV16 or HPV18 DNA and the selectable neomycinresistance gene. After G-418 selection, cells underwent crisis, and surviving cells infected with retroviruses encoding the HPV18 E6/E7 genes (HPV-PAC1), transfected with a head-to-tail dimer of the complete HPV16 genome (HPV-PAC2), or transfected with HPV18 E6/E7 early genes (HPV-PAC3) were established. HPV-PAC1 and HPV-PAC2 cultures appeared morphologically similar to primary cultures even after 40 passages. However, HPV-PAC2 cultures had a clonal morphology. All lines were positive for cytokeratin 18, had acquired vimentin expression, and contained either HPV16 or HPV18 sequences integrated into host DNA. None was tumorigenic in nude mice or formed colonies in soft agar. These cells did not secrete prostate specific antigen nor respond to androgen although tamoxifen inhibited the growth of the cells. Immunohistochemistry showed no evidence of p53 overexpression. Further characterization of these cell lines and examination of their response to chemotherapeutic agents may provide relevant information for the study of hormone-independent PC.     

Differential sensitivity of human papillomavirus type 16(+) and type 18(+) cervical carcinoma cells to CD95-mediated apoptosis

When cervical carcinoma cells were monitored for apoptotic signals, HPV18(+) lines were found to be highly sensitive to agonistic CD95 antibodies or recombinant CD95 ligands after co-exposure with CHX (CD95(S)). In contrast, HPV16(+) cervical carcinoma cells and HPV16-immortalized non-malignant human keratinocytes were CD95-resistant (CD95(R)) under equivalent conditions. Somatic cell hybridization between CD95(S) and CD95(R) cervical carcinoma cell lines revealed that CD95 sensitivity was a dominant trait, which could be correlated with abundant c-Myc and low Bcl-X(L) expression. Although CD95(R) cervical carcinoma cells expressed even higher levels of p53 and CD95 receptor at the surface, resistance could be attributed to the inability to form a functional DISC, necessary for successful transmission of the apoptogenic response. These data indicate that resistance to apoptotic stimuli represents an important immunological escape mechanism during virus-induced carcinogenesis.