Smart vs conventional motorways: Environmental impact assessment under realistic traffic conditions.

This research aims at assessing the environmental impacts exerted by a smart motorway compared to those of a traditional motorway. The study has global policy implications: it takes into account the impacts due to the construction and maintenance of the infrastructure and the environmental effects produced by the traffic emissions, taking into account smart technologies and truck platooning regulation. Through a classical LCA approach, 1 km-long smart motorway with 2 m-high embankment was assumed as the functional unit for the analysis. A realistic traffic condition has been considered. A comparison between environmental effects produced by the use of virgin material and by Reclaimed Asphalt Pavement was made by assuming two maintenance plans. Thanks to C-ITS systems the greater safety featured by smart motorways has a significant effect on the environmental impact, compared to conventional motorways. The impact produced by safety barriers during the life cycle was also estimated. For smart motorways the impact categories GWP, POCP, AP and EP are observed to be considerably reduced in the maintenance phase of zinc-coated steel safety barriers and in those associated to traffic emissions. It must be noted that in smart motorways vehicle emissions are markedly influenced by the percentage of heavy vehicles travelling in Truck Platooning mode. The results show that concomitant use of lime stabilization and RAP leads to a significant reduction in energy consumption (up to 35%) and pollutant emissions (up to 34% of CO2) than in case of exclusive use of virgin material. The accidents reduction produce a 30% decrease of GWP, POCP, AP and EP related to safety barriers maintenance phase than the corresponding values of traditional motorway. Truck platooning mode generates GWP reduction close to 4%. The environmental advantages of a smart motorway increase progressively with the increase of AADT, platooning truck percentage and heavy vehicles percentage.

Identification and sequencing of the Syrian Golden hamster (Mesocricetus auratus) p16(INK4a) and p15(INK4b) cDNAs and their homozygous gene deletion in cheek pouch and pancreatic tumor cells.

Previous studies have shown that the p16(INK4a) tumor suppressor gene is inactivated in up to 98% of human pancreatic cancer specimens and 83% of oral squamous cell carcinomas. Inactivation of the related p15(INK4b) gene has also been identified in a number of tumors and cell lines, however, its role as an independent tumor suppressor remains to be elucidated. Chemically-induced tumors in the Syrian Golden hamster (Mesocricetus auratus) have been shown to be excellent representative models for the comparative development and progression of a number of human malignancies. The purpose of this study was to determine the importance of the p16(INK4a) and p15(INK4b) genes in two experimental hamster models for human pancreatic and oral carcinogenesis. First, hamster p16(INK4a) and p15(INK4b) cDNAs were cloned and sequenced. The hamster p16(INK4a) cDNA open reading frame (ORF) shares 78%, 80%, and 81% identity with the human, mouse, and rat p16(INK4a) sequences, respectively. Similarly, the hamster p15(INK4b) cDNA ORF shares 82% and 89% sequence identity with human and mouse p15(INK4b), respectively. Second, a deletion analysis of hamster p16(INK4a) and p15(INK4b) genes was performed for several tumorigenic and non-tumorigenic hamster cell lines and revealed that both p16(INK4a) and p15(INK4b) were homozygously deleted in a cheek pouch carcinoma cell line (HCPC) and two pancreatic adenocarcinoma cell lines (KL5B, H2T), but not in tissue matched, non-tumorigenic cheek pouch (POT2) or pancreatic (KL5N) cell lines. These data strongly suggest that homozygous deletion of the p16(INK4a) and p15(INK4b) genes plays a prominent role in hamster pancreatic and oral tumorigenesis, as has been well established in correlative studies in comparable human tumors. Furthermore, this study supports the comparative importance of the hamster pancreatic and cheek pouch models of carcinogenesis in subsequent mechanistic-, therapeutic-, and preventive-based studies aimed at providing important translational data applicable to pancreatic adenocarcinoma and oral squamous cell carcinoma in humans.

Effects of 10-hydroxycamptothecin, delivered from locally injectable poly(lactide-co-glycolide) microspheres, in a murine human oral squamous cell carcinoma regression model.

This study investigated whether local delivery of 10-hydroxycamptothecin provides effective inductive chemotherapy as assessed by significant tumor reduction. Established tumorigenic human oral squamous cell carcinoma cells were used for these experiments. The experimental groups were comprised of: control (blank (no drug) poly(lactide-co-glycolide) (PLGA) microspheres), intraperitoneal 10-hydroxycamptothecin delivery + blank microspheres, local bolus 10-hydroxycamptothecin + blank microspheres, and PLGA controlled-release microspheres. The 10-hydroxycamptothecin dose administered was 12 mg/kg (bolus-intraperitoneal, local) or controlled-release over 10 days. Regardless of delivery route, 10-hydroxycamptothecin significantly reduces tumor volume. However, PLGA microspheres provide significantly higher intratumor-drug concentrations (approximately 10 and 100 fold higher) relative to local bolus and intraperitoneal routes, respectively. Also, only the PLGA microspheres significantly reduced tumor weights. Camptothecin clinical applications are limited by drug inactivation at physiological pH and the need for sustained infusions. However, due to their acidic, camptothecin-stabilizing microclimate, PLGA microspheres could provide a novel delivery system for camptothecin-based induction chemotherapy.

Responsiveness to transforming growth factor-beta (TGF-beta)-mediated growth inhibition is a function of membrane-bound TGF-beta type II receptor in human breast cancer cells.

Transforming growth factor-beta (TGF-beta) is a potent inhibitor of growth and proliferation of breast epithelial cells, and loss of sensitivity to its effects has been associated with malignant transformation and tumorigenesis. The biological effects of TGF-beta are mediated by the TGF-beta receptor complex, a multimer composed of TGF-beta receptor type I (TbetaR-I) and TGF-beta receptor type II (TbetaR-II) subunits. Evidence suggests that loss of expression of Tbeta3R-II is implicated in the loss of sensitivity of tumorigenic breast cell lines to TGF-beta-mediated growth inhibition. A panel of human breast cell lines, including the immortalized MCF-10F and tumorigenic MCF-7, ZR75-1, BT474, T47-D, MDA-MB231, BT20, and SKBR-3 cell lines, was characterized for responsiveness to TGF-beta-induced G1 growth arrest. Only the nontumorigenic MCF-10F and the tumorigenic MDA-MB231 cell lines demonstrated a significant inhibitory response to TGF-beta1 and a significant binding of 125I-labeled TGF-beta ligand. While expression of TbetaR-I mRNA was similar across the panel of cell lines, TbetaR-II mRNA expression was decreased significantly in all seven tumorigenic cell lines in comparison with the nontumorigenic MCF- 10F cell line. When total cellular protein was fractionated by centrifugation, TbetaR-I protein was observed in both the cytosolic and membrane fractions at similar levels in all cell lines; however, TbetaR-II protein was present in the cytosolic fraction in all cell lines, but was observed in the membrane fraction of only the TGF-beta-responsive MCF-10F and MDA-MB231 cells. Thus, lack of membrane-bound TbetaR-II protein appears to be an important determinant of resistance to TGF-beta-mediated growth inhibition in this group of breast cell lines.

Analysis of TGF-beta type I receptor for mutations and polymorphisms in head and neck cancers.

Transforming growth factor-beta receptor (TbetaR)-dependent signals are critical for cell growth and differentiation and are often disrupted during tumorigenesis. The entire coding region of TbetaR-I and flanking intron sequences from 30 head and neck carcinomas were examined for alterations using "Cold" SSCP and direct sequencing. No somatic point mutations were found in the TbetaR-I gene. In contrast, 14 polymorphic sequence changes were detected in TbetaR-I in 13 (43%) of the samples, including eight (27%) nucleotide alterations identified as polymorphisms in an exon-1 (GCG)(9) microsatellite repeat, a previously reported tumor susceptibility allele. A nine base pair deletion was found in 23% of the samples including five heterozygous and two homozygous deletions as well as single homozygous 12bp deletion. Additionally, six heterozygous polymorphisms in intronic sequences were determined, including one heterozygous C/A genotype at the +82 nucleotide position of the intron-5 intervening sequence (IVS), and five heterozygous G/A genotypes within intron-7 at the +24 nucleotide position. Exon-1 polymorphisms in the (GCG)(9) microsatellite region of the TbetaR-I gene and their association with head/neck cancers, suggest that development of these cancers may be a direct consequence of loss of responsiveness to TGF-beta mediated growth inhibition.

Somatic INK4a-ARF locus mutations: a significant mechanism of gene inactivation in squamous cell carcinomas of the head and neck.

The INK4a-ARF locus is located on human chromosome 9p21 and is known to encode two functionally distinct tumor-suppressor genes. The p16(INK4a) (p16) tumor-suppressor gene product is a negative regulator of cyclin-dependent kinases 4 and 6, which in turn positively regulate progression of mammalian cells through the cell cycle. The p14(ARF) tumor-suppressor gene product specifically interacts with human double minute 2, leading to the subsequent stabilization of p53 and G(1) arrest. Previous investigations analyzing the p16 gene in squamous cell carcinomas of the head and neck (SCCHNs) have suggested the predominate inactivating events to be homozygous gene deletions and hypermethylation of the p16 promoter. Somatic mutational inactivation of p16 has been reported to be low (0-10%, with a combined incidence of 25 of 279, or 9%) and to play only a minor role in the development of SCCHN. The present study examined whether this particular mechanism of INK4a/ARF inactivation, specifically somatic mutation, has been underestimated in SCCHN by determining the mutational status of the p16 and p14(ARF) genes in 100 primary SCCHNs with the use of polymerase chain reaction technology and a highly sensitive, nonradioactive modification of single-stranded conformational polymorphism (SSCP) analysis termed "cold" SSCP. Exons 1alpha, 1beta, and 2 of INK4a/ARF were amplified using intron-based primers or a combination of intron- and exon-based primers. A total of 27 SCCHNs (27%) exhibited sequence alterations in this locus, 22 (22%) of which were somatic sequence alterations and five (5%) of which were a single polymorphism in codon 148. Of the 22 somatic alterations, 20 (91%) directly or indirectly involved exon 2, and two (9%) were located within exon 1alpha. No mutations were found in exon 1beta. All 22 somatic mutations would be expected to yield altered p16 proteins, but only 15 of them should affect p14(ARF) proteins. Specific somatic alterations included microdeletions or insertions (nine of 22, 41%), a microrearrangement (one of 22, 5%), and single nucleotide substitutions (12 of 22, 56%). In addition, we analyzed the functional characteristics of seven unique mutant p16 proteins identified in this study by assessing their ability to inhibit cyclin-dependent kinase 4 activity. Six of the seven mutant proteins tested exhibited reduced function compared with wild-type p16, ranging from minor decreases of function (twofold to eightfold) in four samples to total loss of function (29- to 38-fold decrease) in two other samples. Overall, somatic mutation of the INK4a/ARF tumor suppressor locus, resulting in functionally deficient p16 and possibly p14(ARF) proteins, seems to be a prevalent event in the development of SCCHN. Mol. Carcinog. 30:26-36, 2001.

Modulation of Ki67, p53 and RARbeta expression in normal, premalignant and malignant human oral epithelial cells by chemopreventive agents.

BACKGROUND: Aberrant expression of Ki67, p53 and RARbeta are characteristic of many tumor types including those of the oral cavity. Chemopreventive agents may act by modulating their expression to more normal levels. MATERIALS AND METHODS: The effects of 21 chemopreventive agents on the expression of Ki67, p53 and RARbeta were determined using a human in vitro model of normal, premalignant and malignant oral epithelial cell lines. RESULTS: Ki67 and mutant p53 (mtp53) were overexpressed in both the premalignant and malignant cell lines, whereas expression of RARbeta was high in the normal, low in the premalignant and not detectable in the malignant cell lines. Most of the agents selectively inhibited the expression of Ki67 in the premalignant and malignant cell lines. Eight of the 21 agents increased, while four agents decreased, the levels of mtp53 protein in the premalignant cell line. In the malignant cell line, five of the agents increased, while ten agents decreased mtp53 protein levels. The agents increased RARbeta expression to near normal levels in the premalignant cell line. CONCLUSION: The data suggest that the suppression of Ki67 and mtp53 are good indicators of the effectiveness of agents in premalignant and malignant oral cells, whereas the enhancement of RARbeta is a measure of effectiveness in premalignant oral cells.

Differential response of normal, premalignant and malignant human oral epithelial cells to growth inhibition by chemopreventive agents.

Squamous cell carcinoma (SCC) of the oral cavity is a multistep process, progressing through a series of discrete, irreversible and complementary alterations in genes that control cell growth, death, and differentiation. In the premalignant state, the oral mucosa progresses through various grades of epithelial dysplasia, with the potential to convert to SCC. Chemopreventive strategies are designed to suppress, reverse, or prevent the formation of premalignant lesions and their subsequent progression to SCC. In the present study, we determined the growth inhibitory effect of 21 chemopreventive agents in a cell culture model using normal, premalignant, and malignant human oral mucosal cell lines. There were significant differences in the growth inhibitory responses of these cell lines to selected retinoids and non-retinoid analogs. Among the retinoids tested, the synthetic retinamides, as a class, showed selective growth inhibition of both premalignant and malignant cells compared to normal human oral epithelial cells in culture. Within the retinamide class, 2CPR exhibited the greatest selectivity in the growth inhibition of premalignant and malignant cells. Among the non-retinoids analyzed, DFMO was a moderate to potent inhibitor of malignant and premalignant oral cell growth, respectively, and stimulated normal oral cell growth at low concentrations. Using this in vitro approach, we have identified several potential chemopreventive agents for oral cancer as selective growth inhibitors of premalignant ahd malignant human oral mucosa cells.

Changes in levels of normal ML-1 gene transcripts associated with the conversion of human nontumorigenic to tumorigenic phenotypes.

Evaluation of malignant human tumors in a xenobiotic nude mouse system has demonstrated that not all cells in tumors exhibit the capacity to form progressively growing tumors. However, nontumorigenic cells isolated from human tumors can be converted to a tumorigenic phenotype in nude mice by treatment with chemical carcinogens or by transfection with antisense to tumor suppressor genes. A newly discovered gene, designated ML-1, appears to be associated with tumorigenesis, because an ML-1 antisense cDNA construct, transfected into nontumorigenic, anchorage-independent growth (AIG) cells, was sufficient to convert these cells into a tumorigenic phenotype. The AIG cells transfected with ML-1 antisense cDNA constructs and converted to tumorigenic cells did not exhibit expression of normal ML-1 mRNA transcripts in the converted cells when evaluated by Northern analysis, whereas premalignant and normal cells expressed ML-1 transcripts at a high level. The converted cells exhibited a loss of growth control and produced tumors in a surrogate nude mouse that were greater than 2.0 cm in less than 2 months. The ML-1 gene has a DNA sequence that is 2177 bp in size and is located on chromosome number 13 on the q arm at site 12-14. Sequence analysis and investigation of GenBank sequences indicate that this is a newly described human gene.

Validation of a rat pheochromocytoma (PC12)-based cell survival assay for determining biological potency of recombinant human nerve growth factor.

A method has been validated, according to the Guidelines of the International Conference on Harmonization (ICH), for precise quantitation of the biological activity of recombinant human nerve growth factor (rhNGF) for lot release testing. The assay is based on the survival of a subclone of rat pheochromocytoma PC12 cells (PC12-CF) in response to rhNGF. Cell survival is measured by monitoring the reduction, by living cells, of the alamarBlue dye into a red form which is highly fluorescent. The assay is simple, has high throughput (performed in 96-well microtiter plates) and shows reproducible dose-response curves in the concentration range of 0.2-50 ng/ml. The method was validated for its linearity, accuracy, precision, robustness, and to meet current regulatory requirements. The assay demonstrated good linearity, yielding a coefficient of determination of 0.9902. Sample recovery studies demonstrated an accuracy ranging from 96 to 98%. The repeatability of the assay and intermediate precision had coefficients of variation (CV) of <9%. The assay was stability-indicating since it was able to detect changes in rhNGF samples degraded by protease treatment and in a number of isolated rhNGF variants. Robustness was demonstrated by the relative insensitivity of the assay to small deliberate changes in key method parameters. The validation data, provided in this manuscript, indicate that the newly described bioassay for rhNGF is robust, accurate, precise, and suitable for lot release potency testing of rhNGF.

Metastatic conversion of chemically transformed human cells.

A linear model for human cell metastasis has been developed in vitro from chemically transformed normal human cells. The chemically transformed cells are nontumorigenic in nude mice, but can be converted to a tumorigenic phenotype by transfection with a nondirectional cDNA library or antisense cDNA to the ML-1 gene. The primary transfected cell line (TR1T) forms localized, progressively growing tumors in nude mice that do not invade into the surrounding tissue. This tumorigenic TR1T cell line could be advanced into a metastatic stage following an additional transfection (TR2M cell line) with the cDNA expression library or antisense cDNA to the ML-1 gene. Metastatic cells, selected from tumors that were attached to internal organs, exhibited an increase in invasiveness as measured in vitro using an invasion chamber. The metastatic cells also exhibited an increased expression of matrix metalloproteinase-1 (MMP-1), although MMP-1 was not part of the cDNA that was transfected into either the TR1T cells or the doubly transfected metastatic TR2M cells. These data suggest that the increase in MMP-1 expression was a secondary downstream event responding to an upstream genetic change that initiated the conversion of cells from a tumorigenic to a metastatic stage. In summary, human cell lines representing premalignant, malignant, and metastatic phenotypes have been established in culture that can be used to identify gene changes that occur as normal human cells progress to a metastatic stage during tumor development. One gene, ML-1, that is found in the expression library appears to be involved in malignant progression, because ML-1 antisense cDNA will convert chemically transformed cells to both tumorigenic and metastatic stages, and cells from both local and metastatic tumors have a reduced or complete loss of expression of the ML-1 gene.

Genetic alterations in the transforming growth factor receptor complex in sporadic endometrial carcinoma.

Cellular responses to the transforming growth factor beta (TGFbeta) ligand, including inhibition of cell proliferation, are mediated by a heteromeric receptor complex composed of TGFbeta types I and II receptors (TbetaR-I and TbetaR-II). Loss of responsiveness to TGFbeta, attributed to inactivation of the TbetaR complex, has been implicated in the development of tumors in a number of human epithelial and lymphoid tissues. To gain a better understanding of TGFbeta signal transduction pathways in endometrial carcinogenesis, we have investigated the role of the TbetaR complex by evaluating the TbetaR-I and TbetaR-II genes for mutations throughout the entire coding region in human sporadic endometrial tumors. Using reverse transcription-PCR, "Cold" single-strand conformation polymorphism analysis, and direct DNA sequencing, it was found that 1 of 39 (2.6%) and 7 of 42 samples (17%) contained code-altering changes in the kinase domain of TbetaR-I and TbetaR-II, respectively. In 7betaR-I, a 3-bp deletion was found resulting in replacement of Arg and Glu at codon 237 and 238 by Lys. With TbetaR-II, mutations were found in the kinase, the extracellular, and the C-terminal domains. No frameshift mutations were detected; however, a silent population polymorphism (AAC-->AAT at codon 389) in TbetaR-II was found in 19 of 42 (44%) tumor samples. These results suggest that alteration in TbetaR-II, but not TbetaR-I, has an important role in the development of endometrial carcinoma.

Epstein-Barr virus growth-transformed cells are converted to malignancy following transfection of a 1.3-kb CATR1 antisense construct independent of a change in the level of c-myc expression followed by a 8;14 chromosomal translocation.

The AGLCL Epstein-Barr virus (EBV) growth-transformed cell line is incapable of inducing tumors in nude mice. When the cells were transfected with a 1.3-kb CATR1 antisense cDNA construct, progressively growing lymphomas could be induced in nude mice. Chromosome analysis of the parental, transfected, and tumor cells revealed that a chromosomal translocation t(8;14)(q24.1;q32) had occurred in the transfected cells and was retained in cells derived from tumors. Moreover, enhanced c-myc expression, usually associated with this translocation, was either unchanged or under-expressed. These data suggest that the malignant transformation of the EBV growth-transformed cells was independent of c-myc expression and suggest that the CATR1 gene may act synergistically with the chromosomal translocation facilitating the conversion of AGLCL cells from a growth-transformed state to a malignant phenotype.

Ineffectiveness of the presence of H-ras/p53 combination of mutations in squamous cell carcinoma cells to induce a conversion of a nontumorigenic to a tumorigenic phenotype.

Human tumor cells have properties in vitro or in surrogate hosts that are distinct from those of normal cells, such as immortality, anchorage independence, and tumor formation in nude mice. However, different cells from individual tumors may exhibit some, but not all of these features. In previous years, human tumor cell lines derived from different tumor and tissue types have been studied to determine those molecular changes that are associated with the in vitro properties listed above and with tumorigenicity in nude mice. In the present study, seven cell lines derived from human tumors were characterized for p53 and ras mutations that may occur in SCC tumor phenotypes and for tumor formation in nude mice. This investigation was designed to examine whether co-occurrence of mutated ras and p53 lead to a malignant stage in the progression process. None of the seven cell lines contained mutations in the recognized "hot spots" of the p53 tumor suppressor gene, but four had a nonsense/splice mutation in codon 126 and a mutation in codon 12 of the H-ras gene. The remaining three cell lines had p53 mutations in intron 5, in codon 193, and a missense mutation in codon 126, respectively. Four of seven cell lines were nontumorigenic; two of these cell lines contained a nonsense p53-126 mutation and mutated ras; one had a missense mutation at codon 126 but no mutated ras; the the fourth had only a p53 mutation at codon 193. Two of the nontumorigenic cell lines were converted to tumorigenicity after treatment with methyl methanesulfonate or N-methyl-N'-nitro-N-nitrosoguanidine with no apparent additional mutations in either gene. Our analysis revealed that there was a high frequency of genetic diversity and mutations in both p53 and H-ras. There was also a lack of a causal relationship in the presence of mutations in p53 and the cells' ability to exhibit a malignant potential in nude mice.

Malignant conversion of human cells by antisense cDNA to a putative tumor suppressor gene.

A cell line, SCC83-01-82, derived from a human oral squamous carcinoma, was non-tumorigenic in nude mice, a characteristic of premalignant cells. Conversion of these cells to a tumorigenic phenotype with chemical mutagens did not increase mutations in hot spots or other conserved regions of p53 or H-ras genes. Investigation of the tumorigenic conversion using an expression library resulted in isolation of a previously unidentified gene, CATR1, located on the long arm of chromosome 7 at band approximately q31-32. Evidence for the involvement of this gene in conversion to tumorigenicity was demonstrated by introduction of a eukaryotic expression CATR1 construct into SCC83-01-82 cells. Transfection with the antisense construct reduced the expression of CATR1 in tumors formed by the transfected cells, suggesting that the antisense suppression of endogenous CATR1 expression appeared to be sufficient for tumorigenic conversion. These results are consistent with previous reports of cytogenetic analyses of tumors, that 7q31-32 contains a gene(s) with tumor suppressor activity; CATR1 is a candidate for this putative suppressor gene.

Malignant conversion of chemically transformed normal human cells.

Two structurally unrelated chemicals, aflatoxin B1 and propane sultone, transformed human foreskin cells to a stage of anchorage-independent growth. Isolation from agar and repopulation in monolayer culture of these transformed cells was followed by transfection with a cDNA library, which resulted in cells that exhibited an altered epithelioid morphology. Chemically transformed/nontransfected cells and transfected normal cells did not undergo a significant morphological change. These epithelioid-appearing, transfected cells, when inoculated into nude mice, form progressively growing tumors. The tumors are histopathologically interpreted as carcinomas. All of the first generation tumors in the surrogate hosts exhibited characteristic rates of growth similar to those of transplants of spontaneous human tumors. In the second generation of tumor xenografts, the progressively growing tumors derived from the transfected cells exhibited a more rapid rate of growth. Southern analysis and reverse transcription PCR confirmed that a 1.3-kb genetic element was integrated into the genome and was actively being transcribed. Examination of the metaphase chromosomes in normal human cells revealed that the genetic element responsible for this conversion was located at site 31-32 of the q arm of chromosome 7. The DNA sequence of this 1.3-kb genetic element contains a coding region for 79 amino acids and a long 3'-untranslated region and appears to be identical to CATR1.3 isolated from tumors produced by methyl methanesulfonate-converted, nontransplantable human tumor cells.

A conundrum in molecular toxicology: molecular and biological changes during neoplastic transformation of human cells.

The process of multistage carcinogenesis lends itself to the concept that the effects of carcinogens are mediated through dose-related, multi-hit, linear changes. Multiple in vitro model systems have been developed that are designed to examine the cellular changes associated with the progression of cells through the different stages in the process; however, these systems may have inherent limitations due to the cell lines used for these studies, the manner of assessing the effects of the carcinogens, and the subsequent growth and differentiation of the exposed cells. Each of these variables results in increasing levels of uncertainty relative to the correlation of the events with the actual process of human tumor development. Therefore, the prediction of the ultimate effect of any carcinogen is difficult. Moreover, relationships between individual biological endpoints resulting from carcinogen treatment appear at best to be approximations. The presence of an activated carcinogen inside the cell can give rise to multiple outcomes, only some of which may be critical events. For example, site-specific modification of the 12th and 13th codons of H-ras is different than that in the adjacent 14th and 15th codons. It is interesting to speculate what effect these differences might have on a biological outcome, e.g., transformation to anchorage-independent growth. The use of different model systems to examine the effects of activated carcinogens also creates additional problems. Comparisons of in vitro transformed cells with similar cells isolated from human tumors indicate that the culture environment appears to influence the expression of a particular phenotype, in that human tumor cells in culture express many of the same parameters as those found in cells transformed with carcinogens in vitro. If the process of transformation is linear, then less aggressive phenotypes should progress to a more aggressive transformed stage. However, in carcinogen-transformed human cells, the populations exhibit phenotypic diversity in that many of the transformed cells differentiate and fail to continue to divide in culture. Historically, we have assumed only a limited role for epigenetic modulation of molecular changes that occur during progression; however, our data suggest quite strongly that nonmalignant tumor populations can be converted to a more malignant phenotype without additional mutations taking place and, conversely, malignant populations can be downregulated to a nontumorigenic phenotype. Tumor cell plasticity is not only a fundamental characteristic of diverse types of human tumors, but also appears as an integral characteristic of carcinogen-transformed cells in vitro.

Comparison of features of carcinogen-transformed human cells in vitro with sarcoma-derived cells.

To define characteristics of chemically transformed phenotypes during and after progression to neoplasia and to assess their relationship to those phenotypes expressed by surgically removed sarcoma lesions, we compared the characteristics in the following manner. We investigated: (1) alterations in growth patterns; (2) anchorage-independent growth; (3) reactivity with monoclonal antibodies directed against surface antigen; (4) invasiveness in embryonic chick skin; (5) tumorigenicity in nude mice; and (6) karyology. Fifty different sarcoma cell lines were examined which exhibited different rates and absolute numbers of population doublings. With one exception, all sarcoma cell lines exhibited a finite life span ranging from 60 to 100 population doublings. Populations of these cells that exhibited anchorage-independent growth in soft agar also reacted positively with a monoclonal antibody (MoAb) 345.134S directed against a 115K-GP cell surface glycoprotein. Similarly, chemically transformed cells that grew in soft agar also reacted with the MoAb 345.134S, whereas cells with an inability to grow in soft agar did not. Cell lines established from human sarcoma and from chemically transformed human fibroblasts that reacted positively with the MoAb 345.134S were invasive for embryonic chick skin and formed tumors in nude mice. The selection medium used during culture of the carcinogen-treated cells resulted in the appearance of an altered phenotype that after at least 16 population doublings exhibited characteristics common to those cells derived from human sarcomas.

Results of toxicological testing of Jefferson Parish pilot plant samples.

Five toxicological tests were performed using concentrated drinking water samples collected at a pilot-scale drinking water treatment plant that had streams treated with different disinfectants (no disinfectant, ozone, chlorine dioxide, monochloramine, or chlorine) before treatment with granular activated carbon (GAC). The toxicological tests used in this study were the Ames Salmonella assay, a subchronic in vivo toxicity assay in mice, the SENCAR mouse skin initiation-promotion assay, a rat liver foci assay, and the lung adenoma assay in strain A mice. These tests were conducted to determine the general toxicity and the mutagenic/carcinogenic potential associated with the use of disinfection and/or GAC in the treatment of drinking water. The stability of the mutagenic activity of the samples tested was determined by repeated analysis using the Ames Salmonella assay. Results indicated that the samples remained mutagenic for the duration of the tests. All the drinking water concentrates (4000 X) prepared by the XAD resin adsorption procedure failed to provide statistically significant indication of carcinogenic activity in the SENCAR mouse, rat liver foci, and the lung adenoma assays. However, concentrates of the chlorine, chlorine dioxide, and monochloramine treated waters gave consistent mutagenic responses in the Ames Salmonella assay. GAC was effective for 6 months in removing both the mutagenicity of chlorine-treated water and the potential of water to become mutagenic when treated with chlorine. In the in vivo, subchronic 30-day toxicity test in mice, some statistically significant differences in organ weights and body weights of animals exposed to different concentrates of some of the samples were observed. However, a consistent pattern of these differences indicating overt toxicity was not detected.