A novel human cell culture model for the study of familial prostate cancer.

Research into molecular and genetic mechanisms underlying familial prostate cancer would be greatly advanced by in vitro models of prostate tumor cells representing primary tumors. We have successfully established an immortalized human prostate epithelial cell culture derived from primary tumors of familial prostate cancer patients with telomerase. The actively proliferating early-passaged 957E cells were transduced through infection with a retrovirus expressing the human telomerase catalytic subunit, human telomerase reverse transcriptase (hTERT). A high level of telomerase activity was detected in 957E/hTERT cells, but not in 957E cells. 957E/hTERT cells are currently growing well at passage 40, whereas 957E cells senesced at passage 5. 957E/hTERT cells exhibit epithelial morphology. Expression of an androgen-regulated prostate specific homeobox gene NKX3.1 and an epithelial cell-specific cytokeratin 8, but not prostate specific antigen or androgen receptor, was detected in 957E/hTERT cells. Prostatic stem cell antigen and p16 were also expressed in this line. 957E/hTERT cells showed growth inhibition when exposed to retinoic acid and transforming growth factor beta1, potent inhibitors of prostate epithelial cell growth. Chromosome analysis showed that the 957E/hTERT cell line (passage 10) was near diploid human male (XY), with most chromosome counts in the 44-46 range. However, there was random loss of chromosomes 8, 13, X, Y, and alteration in chromosome 4q. The late passage 957E/hTERT cell line (passage 32) was karyologically similar to the early passage 957E/hTERT cell line (passage 10) and also had the same alteration of 4q observed in the early passage 957E/hTERT cell line (passage 10) as well as a trisomy of chromosome 20. The well-characterized human cancer lines derived from such patients will be useful for the identification and characterization of prostate cancer susceptibility genes. This is the first documented case of an established human prostate cancer cell line from primary tumor of a familial prostate cancer patient.

Association of deletions and translocation of the reduced folate carrier gene with profound loss of gene expression in methotrexate-resistant K562 human erythroleukemia cells.

Severe impairment of methotrexate membrane transport in methotrexate-resistant K562 (K500E) cells was characterized by a nearly complete loss of reduced folate carrier (RFC) transcripts and RFC protein. As determined by 5'-rapid amplification of cDNA ends (5'-RACE), approximately 93% of the RFC transcripts in wild-type cells contained the KS43 5'-untranslated region transcribed from the RFC-B promoter. KS43 transcripts decreased > 90% in K500E cells. The basal and full-length RFC-B promoters were more active (3- and 2-fold, respectively) in directing transcription of a luciferase reporter gene in K500E than in wild-type cells. Treatment with a demethylating agent, 5-aza-2'-deoxycytidine, or with a histone deacetylase inhibitor, trichostatin A, did not increase the levels of RFC transcripts in K500E cells. No differences in RFC gene structure were detected between the lines on Southern blots; however, the RFC signals were decreased approximately 60% in K500E cells. DNA sequences were identical between the lines for the RFC coding region and the two 5'-non-coding exons and their respective promoters. Spectral karyotype analysis and fluorescence in situ hybridization in wild-type cells showed two normal chromosome 21 copies and one or two marker chromosomes, each with an RFC signal. In K500E cells, the RFC gene locus was no longer localized to a normal chromosome 21 (at 21q22.2), and a single RFC signal was associated with a small metacentric chromosome, characterized by a 21/22 translocation. Our results suggest that loss of RFC transcripts in K500E cells is unrelated to changes in the levels of critical transcription factors, or to differences in the extent of RFC promoter methylation or core histone deacetylation. Rather, this phenotype is due to the loss of one or more RFC alleles, and to a translocation of the remaining RFC allele with the formation of a 21/22 fusion chromosome.

Stepwise genetic changes associated with progression of nontumorigenic HPV-18 immortalized human prostate cancer-derived cell line to a malignant phenotype.

Cytogenetics, fluorescence in situ hybridization (FISH), and comparative genomic hybridization (CGH) were used to identify genes that are involved in the development and progression of prostate cancer. For that purpose, we chose a cell line established in vitro from a prostatic adenocarcinoma which was nontumorigenic in nude mice and followed its progression to a tumorigenic cell line. Stepwise changes were observed in the cell line as it became tumorigenic. The composite karyotype at the nontumorigenic stage (CA-HPV-10) was 68 approximately 77,XXY,-(1, 9, 13, 14, 19, 22),+(4, 5, 11, 18, 20, 21),+(del(1) (q23q31)=M1 (two copies), +der(9)t(1;9)(q24 approximately q31;p23)=M5(two copies), der(14)t(14;?)(q10;?)=M17 in the majority of metaphases. These two derivative chromosomes were also observed a previous study. Our CGH analysis clearly showed that this deleted region in M1 is, in fact, translocated with derivative M5 and, in reality, is amplified. The cell line established from nodule (SCID 5019 p11), showed a number of new changes, as described; however, the most significant change was amplification of the 8q23 approximately qter region, harboring c-myc. This region was translocated with chromosomes 2, 4, and 16 as der(2)t(2;8)(q33;q23)=M12, der(4)t(4;8)(q34;q23)=M11, and der(16)t(8;16)(q24;q21)=M9. We deduce from our study that amplification of c-myc and other genes in the 8q23 approximately qter region were important in progression but did not lead to tumorigenicity. The population that became tumorigenic (SCID 5019 II) showed almost all of the same changes in the karyotype as observed in the nodular cell line; the only significant change was the appearance of der(11)t(4;11)(q32;q22)=M7 and the addition of another copy of t(3q;7p)=M2. These new changes lead to loss of chromosomes 3p, 4pter approximately q34, 6, 7q21 approximately qter, 11q22 approximately qter, and 18q, and gain of 3q, 7p, 8q23 approximately qter, and 11pter approximately q22, before the cell line became tumorigenic. The clonal selection of the population is proven by the presence of a number of the same derivative chromosomes in both the nodular and tumorigenic cell line. As it progressed to tumorigenicity, some of the same changes observed in the original study re-appear at different stages of malignancy, although it was absent in the nontumorigenic cell line. These are: der(16)t(8;16)(q24;q21)=M9 in the nodular cell line and der(11)t(4;11)(q32;q22)=M7 in the tumorigenic cell line. In our system, amplification of c-myc and other genes in der(2)t(2;8)(q33;q23)=M12,der(4) t(4;8)(q34;q23)=M11 together with the presence of der(16)t(8;16)(q24;q21)=M9 and der(11)t(4;11)(q32;q22)=M5 makes the cell line tumorigenic. It is either nontumorigenic, with the presence of a marker equivalent to der(16)=M9 and der(11)=M7 observed in the original study, and only nodular (SCID 5019 p11, present study), with the presence of number of markers with c-myc amplification (M9, M11, and M12). There is accumulation of all the above-mentioned changes in the same cell before it becomes tumorigenic.

Genetic characterization of immortalized human prostate epithelial cell cultures. Evidence for structural rearrangements of chromosome 8 and i(8q) chromosome formation in primary tumor-derived cells.

We have utilized a combination of conventional and spectral karyotyping (SKY) techniques and allelotype analysis to assess numerical and structural chromosome alterations in two cell lines derived from normal human prostatic epithelium, and three cell lines derived from human prostate primary tumor epithelium, immortalized with the E6 and E7 transforming genes of human papilloma virus (HPV) 16 or the large T-antigen gene of simian virus 40 (SV40). These studies revealed trisomy for chromosome 20 and rearrangements involving chromosomes 3, 4, 8, 9, 10, 16, 17, 18, 19, 21, or 22. In addition, the four HPV-immortalized cell lines exhibited extensive duplications or translocations involving the 11q chromosomal region. Interestingly, allelotyping data disclosed loss of 8p sequences in two of the three primary tumor-derived cell lines, and SKY data revealed that the loss of 8p sequences was directly due to i(8q) chromosome formation and/or other structural alterations of chromosome 8. This provides intriguing evidence that 8p loss in primary human prostate tumors may, in some cases, result from complex structural rearrangements involving chromosome 8. Moreover, the data reported here provide direct evidence that such complex structural rearrangements sometimes include i(8q) chromosome formation.

Localization of tumor suppressor gene candidates by cytogenetic and short tandem repeat analyses in tumorigenic human bronchial epithelial cells.

Radon exposure is associated with increased risk for bronchogenic carcinoma. Mutagenesis analyses have revealed that radon induces mostly multi-locus chromosome deletions. Based on these findings, it was hypothesized that deletion analysis of multiple radon-induced malignant transformants would reveal common mutations in chromosomal regions containing tumor suppressor genes responsible for malignant transformation. This hypothesis was supported by a previous study in which tumorigenic derivatives of the human papillomavirus 18-immortalized human bronchial epithelial cell line BEP2D were established following irradiation with 30 cGy of high linear energy transfer radon-simulated alpha-particles. Herein, we describe the analyses of 10 additional tumorigenic derivative cell lines resulting from the irradiation of five additional independent BEP2D populations. The new transformants have common cytogenetic changes, including the loss of chromosome (ch)Y, one of three copies of ch8, one of two copies of ch11p15-pter and one of three copies of ch14. These changes are the same as those reported previously. Analysis of PCR-amplified short tandem repeats of informative loci confirmed the loss of heterozygosity (LOH) at 12 loci spanning the length of ch8 in cell lines from four of the total of eight irradiation treatments to date and the loss of chY in all cell lines (8 of 8). LOH analysis with a total of 17 informative loci confirmed loss on ch14 in transformants from seven of eight irradiation treatments and indicated a 0.5-1.7 cM region of common involvement centered around locus D14S306. No LOH was detected at any of the informative loci on ch11. The overall results support our stated hypothesis. Further studies are currently in progress to determine whether the ch8 and ch14 regions contain genes with tumor suppressor function in bronchial epithelial cells.

Reduced folate carrier gene expression in childhood acute lymphoblastic leukemia: relationship to immunophenotype and ploidy.

Reduced folate carrier (RFC) transcripts in human leukemias were measured by a competitive PCR assay. Total RNAs were reverse transcribed and amplified in the presence of competitive templates for RFC and beta-actin. RFC transcripts were normalized to transcripts for beta-actin. In a series of K562 sublines, a approximately 30-fold range of RFC transcripts measured by PCR assay closely agreed with results of Northern analysis and varied in proportion to RFC protein on Western blots and [3H]methotrexate transport. RFC transcripts varied over a 88-fold range in 49 specimens from 48 children with acute lymphoblastic leukemia (ALL). Median RFC transcripts were similar for 15 T-cell and 33 B-precursor ALL samples (RFC/beta-actin = 6.13 x 10(-3) and 7.92 x 10(-3), respectively) and for 41 diagnostic (7.20 x 10(-3)) and 8 relapse (5.58 x 10(-3)) samples. Whereas PCR measurements of RFC transcripts approximated changes in methotrexate transport in B-precursor ALL blasts (n = 10), for T-ALL blasts (n = 12) there was no apparent relationship between these parameters. For hyperdiploid B-precursor blasts (n = 11) with greater than 52 chromosomes and three to five copies of chromosome 21, the median RFC transcript level was approximately 3-fold higher than that for diploid B-precursor blasts. RFC transcripts were also elevated for two of three B-precursor specimens with acquired trisomy 21. Our results suggest that RFC gene expression is far more predictive of methotrexate uptake capacity in B-precursor than T-ALL and that increased copies of chromosome 21 in B-precursor ALL blasts are generally associated with increased RFC transcripts. Hence, the good prognosis for children with hyperdiploid B-precursor ALL treated with antimetabolite-based chemotherapy and the high levels of methotrexate and methotrexate polyglutamates accumulated may, in part, reflect elevated RFC gene expression and capacities for methotrexate transport.

Cell line characterization and authentication.

Research and development involving the use of cell lines require precise knowledge of the purity and species of origin of the cell lines used. This can only be assured by periodic monitoring of cultured cell lines for possible contamination by other cells and for characteristics that authenticate the cell line identity. In the absence of such monitoring, inter- and intraspecies cell line contaminations are likely to occur in the laboratories of unsuspecting investigators and can result in the generation of mistaken conclusions with an attendant loss of investigators' time, effort, and resources. This chapter provides a history and an overview of the methods that have been developed for cell line authentication, the type of information each of these different methods provides, and how synthesis of that information can be used to characterize a cell line and confirm its identity. An effective cell line monitoring strategy is described that involves testing for a combination of genetic markers, including cell membrane species antigens, isoenzymes, chromosomes, and DNA fingerprints, and use of databases for each marker system to compare the results obtained with a test cell culture with results from an extensive panel of previously tested cell lines.

Gene amplification and increased expression of the reduced folate carrier in transport elevated K562 cells.

The molecular bases for the 6-fold elevated methotrexate transport capacity of K562.4CF cells (Matherly et al., Cancer Res. 51: 3420-3426, 1991) were studied with reduced folate carrier (RFC) cDNA, genomic, and antibody probes. Southern analysis showed that RFC gene copies were increased (approximately 4- to 5-fold) in K562.4CF over wild-type K562 cells. Fluorescence in situ hybridization using a genomic RFC probe confirmed the localization of the RFC gene to the q-arm of chromosome 21. In K562.4CF cells, the frequent loss of a normal copy of chromosome 21 (61% of metaphases) was accompanied by RFC gene amplification and translocations of amplified RFC gene fragments to several (2 to 6) different chromosomal loci not seen in wild-type cells. Particularly intense RFC signals were mapped to homogeneously staining regions in chromosomes 2 and 15. Increased RFC gene copies were accompanied by a similar increase in the major 3.1 kb RFC transcript by northern blotting and an approximately 7-fold elevated level of the broadly migrating (80-95 kDa) RFC protein on a western blot probed with an RFC C-terminal peptide antibody. These results demonstrate that selection of cells with a growth-limiting concentration of reduced folates (0.4 nM of leucovorin) is sufficient to promote chromosomal aberrations, including gene amplification and translocations that result in increased RFC expression and folate transport.

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.

Chromosomal changes observed in immortalized human keratinocytes transformed by ionizing radiation.

Human epithelial cancer cells were induced by concerted action of DNA tumor virus and X-ray radiation. Treatment of nontumorigenic early passage AD12-SV40 immortalized epithelial cells (RHEK-1) at passage 23 with radiation, resulted in further changes in their growth properties. One day old cultures of these RHEK-1 cells were irradiated with graded doses of X-rays (0, 2, 4, 6, and 8 Gy i.e. RHEK-1, RHEK-1/200R, RHEK-1/400R, RHEK-1/600R, and RHEK-1/800R). Morphologic alterations, the ability to grow in soft agar, and to form rapidly-growing squamous cell carcinomas in nude mice were concomitantly acquired properties of the radiation transformed cell lines RHEK-1/200R and RHEK-1/ 400R. On the basis of commonality in having addition of some extra material in chromosome 11 in the region between q14/q22 in all tumorigenic cell lines RHEK-1/200R and RHEK-1/400R, and deletion of the same region in nontumorigenic irradiated cell lines-RHEK-1/600R and RHEK-1/800R, it is deduced this region may have some important oncogene/s or other gene/s that play an important role in tumorigenesis. When compared to squamous cell carcinoma data, the duplication observed in the present study is also observed in 28 to 38% of head and neck and also in 25% of cases of untreated malignant lesions of oral squamous cell carcinoma. Thus, this study shows the correlation between in vitro induced squamous cell carcinoma to in vivo tumors.

Malignant transformation of human prostate epithelial cells by N-nitroso-N-methylurea.

We report the malignant transformation of adult human prostate epithelial cells after multiple exposures to the chemical carcinogen N-nitroso-N-methylurea. Such transformants showed morphological alterations and anchorage-independent growth in soft agar and induced carcinomas when transplanted into nude mice. No p53 or ras mutations were observed. Stepwise chromosomal changes in the progression to tumorigenicity were observed. Loss of the p arms of chromosome 8 (p10>pter) and chromosome 10 (p10>pter) and gain of the q arm of chromosome 8 (q10>qter) were only observed in the tumor outgrows. These findings provide the first evidence of malignant transformation of human prostate epithelial cells exposed to a chemical carcinogen.

Reassessment of immortalization complementation group D.

Previous somatic cell hybridization studies have assigned many human cell lines to one of four complementation groups (A-D) for immortalization. We report here that the A1698DM cell line, which contains selectable markers and has previously been defined as the immortalization group D representative, was derived from T24 cells rather than A1698. A1698DM did not undergo senescence when fused with cell lines assigned to groups A, B, or C. This raises the possibility that this cell line has undergone further evolution and lost multiple putative senescence genes so that it is now unable to complement any, or most, other cell lines for senescence. Cell lines previously assigned to group D may, therefore, be heterogeneous with respect to the genetic changes that resulted in their immortalization. This has important implications for strategies to clone senescence genes based on complementation groups.

Alterations in p53 and p16INK4 expression and telomere length during spontaneous immortalization of Li-Fraumeni syndrome fibroblasts.

Normal cells have a strictly limited growth potential and senesce after a defined number of population doublings (PDs). In contrast, tumor cells often exhibit an apparently unlimited proliferative potential and are termed immortalized. Although spontaneous immortalization of normal human cells in vitro is an extremely rare event, we observed this in fibroblasts from an affected member of a Li-Fraumeni syndrome kindred. The fibroblasts were heterozygous for a p53 mutation and underwent senescence as expected at PD 40. In four separate senescent cultures (A to D), there were cells that eventually recommenced proliferation. This was associated with aneuploidy in all four cultures and either loss (cultures A, C, and D) or mutation (culture B) of the wild-type (wt) p53 allele. Loss of wt p53 function was insufficient for immortalization, since cultures A, B, and D subsequently entered crisis from which they did not escape. Culture C has continued proliferating beyond 400 PDs and thus appears to be immortalized. In contrast to the other cultures, the immortalized cells have no detectable p16INK4 protein. A culture that had a limited extension of proliferative potential exhibited a progressive decrease in telomere length with increasing PD. In the culture that subsequently became immortalized, the same trend occurred until PD 73, after which there was a significant increase in the amount of telomeric DNA, despite the absence of telomerase activity. Immortalization of these cells thus appears to be associated with loss of wt p53 and p16INK4 expression and a novel mechanism for the elongation of telomeres.

On the use of Syrian-hamster cell-cultures as targets for carcinogen-screening.

Syrian hamster embryo (SHE) cells have a reported culture lifespan limited to 30 to 40 population doublings (PDs). In contrast, we have observed continuous growth of two SHE cell lines without the hallmarks of cellular senescence. Two independent primary isolates (SHE-3, and SHE-15) have been grown for more than 160 PDs (SHE-3) and 50 PDs (SHE-15), respectively, with weekly subcultures and with no sign of senescence. During this study, we observed that SHE-3 cells ceased to multiply after about 30 PDs when grown in a nutritionally-inadequate serum-free medium, but resumed growth when switched to an adequate medium. The chromosomal profiles of both SHE cultures revealed a near diploid karyotype but not a completely normal karyotype, even at early passages with increasing chromosomal changes with continued culture. In addition, Syrian hamster chondrocytes were isolated, partially characterized, and their sensitivity to chemically-induced morphological transformation was compared to that of the standard Syrian hamster embryo (SHE) mixed cell culture. It appears that chondrocytes may be a suitable and more sensitive target for carcinogen-screening in vitro.

Role of chromosome 5 in immortalization and tumorigenesis of human keratinocytes.

Rhim et al. were first to show that superinfection of Ad12-SV40-infected immortalized human epidermal cells with an RNA tumor virus containing a ras oncogene, such as Ki-MSV, or their treatment with chemical carcinogens, leads to the ability of cells to both grow in anchorage-independent fashion and to form tumors in athymic nude mice. We describe details of the chromosome changes observed during the transformation. The culture was monitored through 40 passages after Ad12-SV40 infection. Chromosomes 9 and 11 showed random monosomy during the initial stages, but by passage 10 clonal evolution of the cell line was well established. Observed chromosome monosomy/trisomy coupled with chromosome rearrangements (identified as chromosomes A through F) were monosomy 13, loss of p arms of 8 and 10, partial loss of 5 (del(5)(q13) and of the q arm of 18(del(18)(q12)), and extra copies of 11q, 20 and 21. During its progression to tumorigenicity, a derived chromosome E containing a segment of 5q, also appeared to play a major role. The cells remained immortalized as long as the 5q segment was present in some of the cell population as derived chromosomes E or F. Derivative chromosome E showed noteworthy changes during the progression to tumorigenicity, in both viral and chemical transformations. There was loss of heterozygosity of 5q due to an exchange of 5q with chromosomes E or F. In Ki-MSV- and 4NQO-transformed cells, presence of an altered chromosome E (identified as E1) was observed. In MNNG-treated cells, there was a selection of population of cells with further alteration in chromosome E (identified as E3). Besides alterations in chromosome E, additional chromosome changes leading to gene activation and amplification indicating a multistep progression to tumorigenicity were observed. The cytogenetic data reiterate the ever-increasing need for molecular analysis of nonrandom karyotype changes.

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

While several specific genetic alterations have been associated with malignant transformation of human bronchial epithelial cells, they are not all present in every tumor and there is reason to believe that additional genes important for loss of replication control in these cells remain to be identified. In an effort to develop a human bronchial epithelial cell model suitable for identification and functional analysis of genes involved in loss of replication control, and for studying the genetic basis of the multi-stage phenotypic changes associated with tumorigenesis, we treated multiple independent populations of the human papillomavirus (HPV)-immortalized human bronchial epithelial cell line BEP2D with ionizing radiation. Following irradiation, cell lines representing the radiated populations were established from single soft agar-selected colonies. These lines--R2B5SA, R3B5DSA, R2H9S, R2H16S, R2H18S and R3D7S--were compared cytogenetically to the parent cell line and found to have new chromosomal deletions involving putative or confirmed tumor suppressor genes, including chromosome 13 in most R2B5SA cells and all R3B5SA cells, chromosomes 11p and 22 in R216S, and 3p, 11p and 22 in R2H18S. The R2B5SA cells that have lost one copy of chromosome 13 overgrow the culture but are not tumorigenic, suggesting that loss of a single copy of chromosome 13 confers growth advantage but not tumorigenicity. The data confirm that ionizing radiation induces many large chromosomal alterations including chromosomal loss, translocation and deletion and that following radiation it is possible to isolate immortalized nontumorigenic cell lines monosomic for regions known or suspected to contain tumor suppressor genes. The cell lines described here provide powerful models for further investigation of putative tumor suppressor genes including identification, functional analysis and stage of transformation at which they are operative.

Human glucocorticoid receptor gene deletion following exposure to cancer chemotherapeutic drugs and chemical mutagens.

The sensitivity of the human glucocorticoid receptor (hGR) gene to mutagenesis by the cancer chemotherapeutic drugs adriamycin, bleomycin, and chlorambucil was evaluated using glucocorticoid-sensitive (dexs) subclones of the human leukemic cell line CEM-C7. Treatment of cells with either bleomycin or chlorambucil increased the frequency of glucocorticoid-resistant (dexr) clones 3.3- and 10-fold, respectively. Measurement of steroid-binding activity in intact dexr cells demonstrated that the predominant phenotype of drug-induced dexr clones was receptorless (r-). dexs CEM cells express only one functional hGR allele and, in addition, are heterozygous for a BclI restriction fragment length polymorphism in the hGR gene (L. A. Palmer and J. M. Harmon, Cancer Res., 51:5224-5231, 1991). To determine the basis of the r- phenotype, BclI digests of genomic DNA isolated from r+ and r- cell lines were examined for the presence of the polymorphic 2.4- and 4.4-kilobase digestion products. A deletion of all or part of the hGR gene was demonstrated by the absence of the 4.4-kilobase fragment in one of two bleomycin-induced dexr clones, as well as the ICR191-induced dexr cell line ICR27TK.3. Cytogenetic analysis of ICR27TK.3 showed that the distal portion of the long arm of one chromosome 5 had been replaced with a portion of chromosome 15. Thus, in at least two dexr cell lines, deletions and/or chromosome breaks in the hGR locus appear to account for the r- phenotype.

A human bronchial epithelial cell strain with unusual in vitro growth potential which undergoes neoplastic transformation after SV40 T antigen gene transfection.

Bronchial epithelial cells were cultured from an individual with no evidence of malignant disease. These cells, designated HB56B, had a greatly extended in vitro life-span, being able to undergo 50 passages and 200 population doublings in contrast to the usual 3 to 4 passages and 20 to 30 population doublings characteristic of normal human bronchial epithelial cells. HB56B cells had karyotypic evidence of an amplified region on the short arm of chromosome II. Unlike normal bronchial epithelial cells, which undergo terminal squamous differentiation in vitro in response to fetal bovine serum, HB56B cells were only minimally affected by serum. These cells were readily established as an immortalized cell line, HB56B/5T, following transfection with a plasmid containing SV40 early region DNA. HB56B cells were non-tumorigenic in athymic nude mice, but HB56B/5T cells within a few passages of transfection with the SV40 plasmid formed tumors of which 28/37 regressed. HB56B cells may offer an experimental system for the study of proliferation, differentiation, and senescence control in human bronchial epithelial cells.

Comparative properties of untreated and N-nitrosobenzylmethyl-amine-transformed rat esophageal epithelial cell lines.

A culture system utilizing rat esophageal epithelial cells has been developed. Four normal and eight N-nitrosobenzylmethylamine-treated lines were compared with respect to chromosome number, anchorage-independent growth in agarose, and tumorigenic potential in syngeneic rats. All cell lines were aneuploid with nine in the near-tetraploid range and three in the near-diploid range. No relation between tumorigenic potential and chromosome number or structure was apparent. Similarly, anchorage-independent growth in agarose did not correlate with tumorigenic potential. Three of the 12 immortalized lines (two carcinogen-treated and 1 untreated) induced well-differentiated squamous cell carcinomas in syngeneic rats. These tumors had weak metastatic potentials suggesting that tumorigenic potential and metastatic ability are separately controlled. These cell lines will be useful for the investigation of factors involved in the conversion of immortalized rat esophageal epithelial cell lines to lines of high metastatic potential.