Transforming and carcinogenic potential of cadmium chloride in BALB/c-3T3 cells

A large number of workers are potentially exposed to cadmium during mining and processing. Therefore, there is a concern regarding the potential carcinogenic hazards of cadmium to exposed workers. Studies have been performed to determine if cadmium chloride (CdCl(2)) can induce morphological cell transformation, DNA from CdCl(2)-induced transformed cells can transform other mammalian cells, and the transformed cells induced by CdCl(2) can form tumors in nude mice. BALB/c-3T3 cells were treated with different concentrations of CdCl(2) for 72 h. The frequency of transformed foci from each treatment was determined after cells were cultured for 4 to 5 weeks. DNAs from five CdCl(2)-induced transformed cell lines were isolated and gene transfection assay was performed using NIH-3T3 cells. Non-transformed BALB/c-3T3 cells and cells from 10 transformed cell lines induced by CdCl(2) were injected into both axillary regions of nude mice. Mice were screened once a week for the appearance and size of tumors. CdCl(2) caused a statistically significant, concentration-related increase in the transformation frequency. DNA from all five CdCl(2)-induced transformed cell lines tested was found to induce varying degrees of transfection-mediated transformation in NIH-3T3 cells. All 10 CdCl(2)-induced transformed cell lines formed fibrosarcomas in nude mice within 39 days of inoculation. Within this time period, no tumors were found in nude mice injected with non-transformed BALB/c-3T3 cells. These results indicate that CdCl(2) is capable of inducing morphological cell transformation and that the transformed cells induced by CdCl(2) are potentially tumorigenic.     

Partial transformation of mouse fibroblastic and epithelial cell lines with the v-myc oncogene

To investigate the role of the myc gene in mammalian cell transformation, plasmid constructs containing the v-myc oncogene and a co-selectable G418 resistance marker were introduced into both mouse fibroblasts (NIH-3T3) and bladder epithelial cells (BBN3 and BBN7). After transfection or microinjection of DNA, no transformed foci could be detected on confluent monolayers but, when the cells were cultured under conditions in which individual cells were allowed to grow and form colonies, morphological transformation was observed. Unlike ras-transformed NIH-3T3 cells, v-myc-transformed cells were unable to grow in serum-free medium and therefore still required exogenous growth factors. v-myc-transformed NIH-3T3 cells were poor at forming foci when co-cultivated with untransformed cells; however, the efficiencies could be increased by addition of EGF to the medium. Both v-myc-transformed fibroblasts and epithelial cells acquired the ability to grow in soft agar, though at efficiencies lower than the corresponding ras transformants. Subcutaneous inoculation of v-myc-transformed NIH-3T3 cells into nude mice resulted in no tumours within 6 weeks. After protracted periods (2-3 months) a few tumours were detected, but at a frequency barely above that for spontaneous tumour formation. Epithelial cells transformed by v-myc were either non-tumorigenic or gave a very low incidence of tumours. We conclude that the v-myc oncogene induces morphological changes and anchorage independence in immortal mouse fibroblasts and epithelial cell lines but further events are required for the cells to become tumorigenic.     

BALB/C mouse 3T3 fibroblasts expressing human estrogen receptor: effect of estradiol on cell growth

Mouse 3T3 fibroblasts (clone A31) were stably transfected with human estrogen receptor (hER). Among the four sublines expressing functional hER at approximately 10(4) estrogen binding sites/cell, three retained a non-transformed morphology and growth characteristics while the fourth displayed a transformed phenotype (criss-cross growth, lack of density arrest, reduced dependence on exogenous growth factors). Estradiol (E2) had no effect on the growth of the three non-transformed hER expressing sublines. In contrast, low concentrations (1 to 20 nM) of E2 strongly inhibited the proliferation of the subline with transformed phenotype and high (100 nM) concentrations were toxic in these cells.     

The regulation of DNA repair processes in mammalian cells. II. The repair of DNA radiation damage in NIH 3T3 murine cells transformed by the v-myc oncogene]

The kinetics of repair of the ionizing radiation-induced DNA single- and double-strand breaks in the normal NIH 3T3 mouse cells and in those transformed with virus oncogenes v-myc has been investigated. The incubation of non-transformed cells for 18 hours in serum-free medium results in significant decrease in the rate of the single-strand DNA breaks repair during the first minutes of post-irradiation incubation. This effect is absent in transformed cells. The DNA double-strand breaks repair is more efficient in transformed NIH 3T3 cells as compared to that in the non-transformed ones both after their incubation in the medium with 10% fetal bovine serum or without serum. However, more significant differences in the rate of elimination of these DNA lesions was found in the serum-free medium. Hence, the presence of v-myc sequences in the transformed cells prevented from a decrease in the efficiency of DNA repair due to incubation of cell culture in serum-free medium. These results agree with the assumption that c-myc gene product may be a mediator in regulation of DNA repair by the epidermal growth factor. These data also show that the c-myc gene expression in an important condition providing a high efficiency of the constitutive DNA repair process.     

Novel two-stage screening procedure leads to the identification of a new class of transfection enhancers

BACKGROUND: Non-viral gene transfer efficiency is low as compared to viral vector systems. Here we describe the discovery of new drugs that are capable of enhancing non-viral gene transfer into mammalian cells using a novel two-stage screening procedure. METHODS: First, potential candidates are preselected from a molecular library at various concentrations by a semi-automated yeast transfection screen (YTS). The maximal transfection efficiency of every positive drug is subsequently determined in independent experiments at the optimal concentration and compared to the inhibitory effect of the drug on cell growth (IC50). In a subsequent mammalian cell transfection screen (MTS), the maximal transfection efficiency and the IC50 are determined for all preselected drugs using a human cell line and a luciferase reporter gene construct. RESULTS: Employing our novel system we have been able to identify a new class of transfection enhancers, the tricyclic antidepressants (i.e. doxepin, maprotiline, desipramine and amoxapine). All positive drugs enhanced gene transfer in both yeast and human cell lines, but lower concentrations were sufficient for mammalian cells. With a triple combination of doxepin, amoxapine and chloroquine we obtained a transfection efficiency that exceeded that of chloroquine, one of the best-known transfection enhancers of mammalian cells, by nearly one order of magnitude. CONCLUSIONS: Non-viral gene transfer efficiency can be increased significantly using new transfection enhancers that are identified by a novel, semi-automated two-stage screening system employing yeast cells in the first and specific human target cells in the second round.     

The pattern of gene expression and gene dose profiles of 6-Mercaptopurine- and 6-Thioguanine-resistant human leukemia cells

Exposure of MOLT4 human T-cell leukemia cells to 6-Mercaptopurine (6-MP) and 6-Thioguanine (6-TG) resulted in acquired resistance associated with attenuated expression of the genes encoding concentrative nucleoside transporter 3 (CNT3) and equilibrative nucleoside transporter 2 (ENT2). To identify other alterations at the RNA and DNA levels associated with 6-MP- and 6-TG resistance, we compared here the patterns of gene expression and DNA copy number profiles of resistant sublines to those of the parental wild-type cells. The mRNA levels for two nucleoside transporters were down-regulated in both of the thiopurine-resistant sublines. Moreover, both of these cell lines expressed genes encoding the enzymes of purine nucleotide composition and synthesis, including adenylate kinase 3-like 1 and guanosine monophosphate synthetase at significantly lower levels than wild-type cells. In addition, expression of the mRNA for a specialized DNA polymerase, human terminal transferase encoded by the terminal deoxynucleotidyl transferase (DNTT) gene, was 122- and 93-fold higher in 6-TG- and 6-MP-resistant cells, respectively. The varying responses to 6-MP- and 6-TG observed here may help identify novel cellular targets and modalities of resistance to thiopurines, as well as indicating new potential approaches to individualization therapy with these drugs.     

An improved method of electroporation for introducing biologically active foreign genes into cultured mammalian cells

We have developed a modified, reproducible, and efficient method for introducing cloned genes into mammalian cells by using an electric field followed by treatment with sodium butyrate. Transfection frequencies with plasmid pSV2-neo, consisting of an antibiotic (G418) resistance gene and simian virus 40 (SV40) early promoter, by electroporation were higher than those by calcium phosphate DNA precipitation. Treatment with sodium butyrate following electroporation significantly increased the frequency of transfection in various types of cell lines and primary cultured cells including human skin fibroblasts. Treatment with sodium butyrate also increased the transient expression of the gene for chloramphenicol acetyltransferase (acetyl-CoA; chloramphenicol O3-acetyltransferase, CAT, EC 2.3.1.28) when the gene was introduced into BALB/c 3T3 cells by electroporation. Electroporation combined with sodium butyrate treatment is an improved method for stable and transient biochemical transformation of foreign genes in cultured mammalian cells.     

Poly-L-ornithine-mediated transformation of mammalian cells.

Poly-L-ornithine has been used to introduce DNA and RNA into mammalian cells in culture. Ornithine-mediated DNA transfer has several interesting and potentially useful properties. The procedure is technically straightforward and is easily applied to either small or large numbers of recipient cells. The efficiency of transformation is high. Under optimal conditions, 1 to 2% of recipient mouse L cells take up and continue to express selectable marker genes. DNA content of transformants can be varied reproducibly, yielding cells with just one or two copies of the new gene under one set of conditions, while under a different set of conditions 25 to 50 copies are acquired. Cotransformation and expression of physically unlinked genes occur at high efficiency under conditions favoring multiple-copy transfer. Polyornithine promotes gene transfer into cell lines other than L cells. These include Friend erythroleukemia cells and NIH 3T3 cells. Both are transformed about 1 order of magnitude more efficiently by this procedure than by standard calcium phosphate products. However, the method does not abolish the large transformation efficiency differences between these cell lines that have been observed previously by other techniques. (vi) mRNA synthesized in vitro was also introduced into cells by this method. The RNA was translated resulting in a transient accumulation of the protein product.     

Amplification of portions of the genome in mammalian somatic cells resistant to colchicine. II. Marker chromosomes with long homogeneously staining regions in colchicine-resistant cells of the Djungarian hamster

The series of sublines 170-750 times more resistant to colchicine were obtained from 10 independent clones of Djungarian hamster cells possessing 16-22-fold resistance to the drug. From each clone, several sublines with different levels of colchicine-resistance were developed. The drug resistance was unstable. 2,7-4,0% of cells per population doubling lost resistance to selective dosages of colchicine. The loss of resistance was stepwise. The chromosomes stained by trypsin G-banding technique were studied in 17 sublines. 15 sublines derived from 9 independent clones contained chromosomes with long homogeneously staining regions (HSRs). These were, as a rule, primarily localized in the long arm of chromosome 4. During cultivation, HSRs were transferred from chromosome 4 into other chromosomes. Evidently, transposition of HSRs was due to translocations of different chromosomes of HSRs in the chromosome 4 and to subsequent breakages of the resulting dicentrics within HSRs. A great number of different chromosomal rearrangements was also found in the cells containing HSRs. Possibly, formation of HSR leads to destabilization of the karyotype and to the variability of the genome. The length of HSRs varied in different cells of each subline. The levels of colchicine-resistance in different sublines did not correlate with the average length of HSRs in their cells. The lack of connection between the lengths of HSRs and the levels of drug resistance as well as the existence of highly resistant sublines with gene amplification, but without HSRs, suggest that amplified genes are localized in Djungarian hamster colchicine-resistant cells both in chromosomes and extrachromosomally.     

Transfection of EK-3, a subline of NIH 3T3, with the oncogene Ha-ras does not abolish its anchorage dependence

EK-3 cells, previously isolated by us from cultures of NIH 3T3, require both ras and myc oncogenes for efficient transformation, while their parent cells are readily transformed by ras alone. We transfected the EK-3 cells with the v-Ha-ras oncogene and obtained several sublines which integrated this gene and transcribed it successfully. The ras-NIH 3T3 formed foci of multilayered cells that were piling up in culture, while the ras-EK-3 cells remained contact inhibited. Furthermore, when the growth of the cells in soft agar was examined, a clear difference was observed. Cells of the ras-NIH 3T3 clonal lines showed high efficiency of growth (10%), while the ras-EK-3 cells exhibited low efficiency (0.2%). The latter being quite similar to that of the non-transfected NIH 3T3 and EK-3 cells (0.05%). The results presented now, showing that ras-EK-3 cells are more anchorage dependent than the ras-NIH 3T3 cells, clearly indicate that differences, previously shown to exist between EK-3 and NIH 3T3 cells, persist in their daughter cell lines derived following transfection with the Ha-ras oncogene.     

Efficient correction of mismatched bases in plasmid heteroduplexes injected into cultured mammalian cell nuclei.

Heteroduplexes were prepared from two plasmids, pRH4-14/TK and pRH5-8/TK, containing different amber mutations in the neomycin resistance gene (Neor). The Neor gene was engineered to be expressed in both bacterial and mammalian cells. A functional Neor gene conferred kanamycin resistance to bacteria and resistance to the drug G418 to mammalian cells. In addition, the plasmids contained restriction site polymorphisms which did not confer a selectable phenotype but were used to follow the pattern of correction of mismatched bases in the heteroduplexes. In a direct comparison of the efficiency of transforming mouse LMtk- cells to G418r, the injection of heteroduplexes of pRH4-14/TK-pRH5-8/TK was 10-fold more efficient than the coinjection of pRH4-14/TK and pRH5-8/TK linear plasmid DNA. In fact, injection of 5 to 10 molecules of heteroduplex DNA per cell was as efficient in transforming LMtk- cells to G418r as the injection of 5 to 10 molecules of linear plasmid DNA per cell containing a wild-type Neor gene. To determine the pattern of mismatch repair of the injected heteroduplexes, plasmids were "rescued" from the G418r cell lines. From this analysis we conclude that the generation of wild-type Neor genes from heteroduplex DNA proceeds directly by correction of the mismatched bases, rather than by alternative mechanisms such as recombination between the injected heteroduplexes. Our finding that a cell can efficiently correct mismatched bases when confronted with preformed heteroduplexes suggests that this experimental protocol could be used to study a wide range of DNA repair mechanisms in cultured mammalian cells.     

Molecular cytogenetics of multiple drug resistance

The refractory nature of many human cancers to multi-agent chemotherapy is termed multidrug resistance (MDR). In the past several decades, a major focus of clinical and basic research has been to characterize the genetic and biochemical mechanisms mediating this phenomenon. To provide model systems in which to study mechanisms of multidrug resistance,in vitro studies have established MDR cultured cell lines expressing resistance to a broad spectrum of unrelated drugs. In many of these cell lines, the expression of high levels of multidrug resistance developed in parallel to the appearance of cytogenetically-detectable chromosomal anomalies resulting from gene amplification. This review describes cytogenetic and molecular-based studies that have characterized DNA amplification structures in MDR cell lines and describes the important role gene amplification played in the cloning and characterization of the mammalian multidrug resistance genes (mdr). In addition, this review discusses the genetic selection generally used to establish the MDR cell lines, and how drug selections performed in transformed cell lines generally favor the genetic process of gene amplification, which is still exploited to identify drug resistance genes that may play an important role in clinical MDR.     

Transformed Roots of Lupinus mutabilis: Induction, Culture and Isoflavone Biosynthesis

Transformed roots of Lupinus mutabilis cv. Potosi induced by Agrobacterium rhizogenes strain R1601 were cultured on Murashige and Skoog-based medium lacking kanamycin sulphate, or with this antibiotic at 40 mg l⁻¹. The neomycin phosphotransferase gene in the genome of transformed roots was confirmed by non-radioactive Southern hybridisation. Neomycin phosphotransferase protein was detected by ELISA. Transformed roots synthesised isoflavones, but not quinolizidine alkaloids; the latter are typical secondary metabolites of lupin normally produced in aerial parts of the plant. Genistein and 2′-hydroxygenistein, were the main secondary metabolites in cultured, transformed roots, whereas the glycoside genistin was more abundant in roots of non-transformed plants. Wighteone concentrations in transgenic roots were higher than those of non-transformed roots. Transformed roots produced twice the concentration of isoflavones compared with roots from non-transformed plants, indicating that Ri plasmid T-DNA genes modified isoflavone concentration and pattern of biosynthesis.     

Enhancement of methotrexate resistance and dihydrofolate reductase gene amplification by treatment of mouse 3T6 cells with hydroxyurea.

We investigated various parameters associated with the initial selection of mouse 3T6 cells for resistance to single concentrations of methotrexate and characterized resistant colonies for the presence of additional (amplified) copies of the dihydrofolate reductase gene. Our results indicate that the frequency of occurrence of dihydrofolate reductase gene amplification varies with the selecting concentration of methotrexate and is highly variable between clonally derived sublines of mouse 3T6 cells. Second, we increased the frequency of occurrence of cells with amplified dihydrofolate reductase genes by transiently inhibiting DNA synthesis with hydroxyurea before the selection of cells in single concentrations of methotrexate. This effect was dependent on the concentration of hydroxyurea, the time of exposure to the drug, and the time interval between the removal of hydroxyurea and the selection of cells in methotrexate.     

Plasmidial maintenance in rodent fibroblasts of a BPV1-pBR322 shuttle vector without immediately apparent oncogenic transformation of the recipient cells.

A recombinant plasmid was constructed (pV69) which comprises a subgenomic fragment of bovine papilloma virus type 1 (BPV1) DNA, part of plasmid pBR322 DNA and a drug resistance gene expressed in both mammalian fibroblasts and Escherichia coli. This gene (vv2) is a modified form of the bacterial neomycin resistance gene (neo) linked to the herpes simplex virus thymidine kinase (tk) promoter (plasmid pAG60), to which the original bacterial neo promoter from transposon Tn5 was added back, upstream of the eukaryotic promoter. It induced kanamycin resistance in E. coli, as well as resistance to the drug G418 in rat and mouse fibroblasts. Its expression in FR3T3 rat cells was enhanced as compared with the original tk-neo construction. After transfer of plasmid pV69 into C127 mouse cells or FR3T3 rat cells, the number of resistant colonies selected in medium containing G418 was one to two orders of magnitude higher than that of transformed foci in normal medium. In eight independent cell lines selected by drug resistance, pV69 DNA was found to be maintained in a plasmidial state, without any detectable rearrangement or deletion and could be transferred back in E. coli. In contrast, cell lines selected by focus formation in normal medium maintained deleted forms of the original plasmid DNA, and only part of them were resistant to G418. Most of the drug-resistant clones had kept the morphology and growth control of the normal fibroblasts. However, with further passages in culture, these cells spontaneously produced transformed foci with increasing frequencies.     

Glutaraldehyde-fixed transformed and non-transformed cells induce contact-dependent inhibition of growth in non-transformed C3H/10T1/2 mouse fibroblasts, but not in 3-methylcholanthrene-transformed cells

C3H/10T1/2 mouse fibroblasts showed a pronounced inhibition of growth when reaching a critical cell density. The situation of high cell density could be mimicked by the addition of glutaraldehyde-fixed cells to sparsely seeded proliferating cells. Treatment of the C3H/10T1/2 cells with 3-methylcholanthrene led to a high frequency of piled up foci (118 type II and type III foci in 78 cultures). Cells of a type III focus of a treated culture were cloned. These cells grew in soft-agar and reached 10 times higher cell densities when grown in culture dishes, than did their non-transformed counterparts. Glutaraldehyde-fixed transformed cells did not differ from fixed non-transformed cells in the ability to inhibit the growth of sparsely seeded non-transformed cells. On the other hand, both the addition of fixed normal or transformed C3H/10T1/2 cells did not affect the growth rate of transformed cells. In a concept explaining the density-dependent inhibition of growth of non-transformed cells by a specific interaction of plasma membrane-localized effectors with plasma membrane-localized receptors, the present findings would indicate that the transformed cells used express active effectors but are functionally defective in the receptors or in the signal transmission.