Employment of adult mammalian primary cells in toxicology: in vivo and in vitro genotoxic effects of environmentally significant N-nitrosodialkylamines in cells of the liver, lung, and kidney.

This report focuses on the use of freshly isolated primary mammalian cells from different tissues and organs of the rat for the rapid and efficient analysis of toxic and genotoxic chemicals. The cells are either treated in vitro or they are isolated from treated animals. Viability by trypan blue exclusion and DNA damage as single-strand breaks are monitored in either case. Therefore, it is possible to compare in vitro and in vivo results directly. N-nitrosamines with unique organ-specific modes in carcinogenesis were studied in vitro using hepatocytes derived from three species (rat, hamster, and pig) and in rat lung and kidney cells. The sensitive detection of all carcinogenic nitrosamines was achieved, although a pattern of cell-specific activation was not observable. The new modification of the in vivo approach allowed the sensitive detection of NDMA genotoxicity in hepatic and in extrahepatic tissues. It is important to point out that the method is an efficient tool for toxicokinetic studies with genotoxic carcinogens in vivo.

Organ specific genotoxicity and carcinogenicity.

1. The in vitro studies showed that organ specific metabolic activation does not appear to play a predominant role for the in vivo activities of the studied nitrosamines 2. The in vivo studies following 1 h exposure of rats with the nitrosamines can differentiate between organs susceptible for genotoxicity and and those which are not. Nontarget organs in carcinogenicity can not be identified exclusively. 3. The additional study of persistence of genotoxicity may identify organs susceptible for carcinogenicity. Presently, we are working on new techniques to detect DNA SSB and other events with microscale methods. This is necessary to allow a more complete elucidation of genotoxicity in remote target organs and with other carcinogens which may not induce DNA SSB. Accordingly in the near future we expect to have even more versatile tools available to study toxicokinetics of foreign compound. Meanwhile our work with N-nitrosamines is continuing in order to better understand their in vivo modes of action and to better evaluate their burden and risk for man.

Assay-specific genotoxicity of N-nitrosodibenzylamine to the rat liver in vivo.

N-Nitrosodibenzylamine (NDBzA) is mutagenic to Salmonella typhimurium and induces DNA strand breaks in isolated rat hepatocytes, yet it is reported to be non-carcinogenic to the rat. Here we report that it is inactive in both the rat and mouse bone marrow micronucleus assays and in a rat liver autoradiographic assay for unscheduled DNA synthesis. It is, however, clearly active as a micronucleus-inducing agent and mitogen in the rat liver and is capable of inducing single-strand breaks in the DNA of rat liver. The origin and implications of this curious conflict of in vivo genotoxicity data are discussed. Irrespective of that discussion, it is concluded that NDBzA is genotoxic to the rat liver in vivo.

DNA amplification in genetic toxicology.

Chemical compounds can cause amplification of specific DNA sequences. DNA amplification may result in an enhanced production of gene products which help cells to cope with the chemicals. This may lead to a resistance of the cells toward the agent. Additionally, initiation of transformation or progression of transformed cells to tumorigenicity may also involve DNA amplification. Therefore, it is of interest to study the potential of chemicals to induce DNA amplification. This report focuses on the investigation of a variety of chemicals in 2 systems with which the amplification of viral DNA is measured within cells in culture. One model system comprises the measurement of SV40 DNA content in an SV40-transformed Chinese hamster cell line following chemical treatment. Antitumor agents as well as genotoxic and non-genotoxic compounds were studied in this system as a first step to determine the DNA amplification-inducing potential of a variety of differently acting chemical compounds. Also, a novel assay based on adeno-associated virus infection of cells is described. This system may offer the possibility of studying DNA amplification in a variety of different target cells. For the future, the need is stressed to develop and analyze versatile systems to study amplification of specific target genes in untransformed cells and in tumor cells.

Assessment of the preclinical activity of budotitane in three different transplantable tumor systems, its lack of mutagenicity, and first results of clinical phase I studies.

The antitumor activity of budotitane was investigated in three different tumor systems--the transplantable murine ascitic-colon-adenocarcinoma MAC 15A, the TD-osteosarcoma of the rat, and the intramuscularly transplanted murine sarcoma 180. Marked inhibition of tumor growth was observed in the intramuscularly transplanted sarcoma 180, and cure rates of 50-80% were achieved in the colon adenocarcinoma MAC 15A. In contrast to these findings, bulotitane was inactive in the transplantable TD-osteosarcoma of the rat. Preliminary mutagenicity studies with the Salmonella typhimurium/mammalian microsome assay of Ames did not show any evidence of mutagenicity for the compound. The first results of the phase I clinical trials showed mild hepatotoxicity at a dose level of 15 mg/kg, dose-limiting nephrotoxicity at 21 mg/kg, and a reversible impairment of the sense of taste, beginning at a dose of 9 mg/kg.

Effect of long-term inhalation of N-nitroso-dimethylamine (NDMA) and SO2/NOx in rats.

This report focusses on preliminary results of a long-term inhalation assay with N-nitroso-dimethylamine (NDMA) at low concentrations. Chronic inhalation of 1 ppm of NDMA (4 h/day, 5 days/week) was found to be toxic in rats and diminished life expectancy by about 8 months compared to the control group. Mostly tumors of the nasal region (25/36) were observed. Inhalation of 0.2 ppm of NDMA lead to a high tumor yield in rats (20/36). At a concentration of 0.04 ppm (= 0.12 mg/m3 in air) 3 tumors of the nasal region have been found until now. In addition, a combined inhalation study of other air pollutants SO2 or NOx together with NDMA at the 0.2 ppm level is being performed. Tumors of the nasal region have been observed in the groups with SO2 + NDMA and NOx + NDMA as well as with NDMA alone. Differences in tumor response of the groups treated with NDMA alone or in combination with SO2/NOx cannot be assessed yet. The additional treatment with the air pollutants SO2 or NOx has not affected the body weight gain or any other observable parameters of the life quality of the rats.

Anticancer activity of bisphosphonic acids in methylnitrosourea-induced mammary carcinoma of the rat--benefit of combining bisphosphonates with cytostatic agents.

This study primarily describes the cytostatic activity of a bisphosphonate and of an alkylating agent linked bisphosphonate toward mammary carcinomas in vivo. Bisphosphonates had been shown to be therapeutically active in bone metastases. There is no animal tumor model available in which both primary mammary carcinomas and bone metastases can be studied simultaneously. Therefore, the Walker carcinosarcoma model, which was used as a model for bone metastasis in earlier studies, was combined with the M-methyl-N-nitrosourea (MNU) induced mammary carcinoma as a model for the primary tumor. Four-, or six-week treatment of MNU-induced mammary carcinomas in Sprague-Dawley rats with the new aromatic bisphosphonate 4[4-[bis(2-chloroethyl)-amino]-phenyl]-1-hydroxybutane-1, 1-bisphosphonate (BAD) showed higher antitumor activity than treatment with melphalan or with 3-amino-1-hydroxypropylidene-1,1-bisphosphonate (APD) alone. BAD is the APD moiety covalently bound to a molecule derived from melphalan. A combination therapy with 11.75 mg/kg/day APD and 0.6 mg/kg/day melphalan showed the best therapeutic efficacy in this tumor model. In comparison to monotherapy with BAD, APD, or melphalan, a significantly higher rate of complete remissions was achieved. APD, itself, was not genotoxic in 3 employed short term assays. Since bisphosphonates had been shown to be therapeutically active in bone metastases, the antitumor potency of these compounds against experimental primary mammary carcinomas, coupled with the non-genotoxicity of APD and the inhibition of osteolytic bone metastases, might be an important advancement for adjuvant chemotherapy of human mammary carcinomas.

Effects of SO2 or NOx on toxic and genotoxic properties of chemical carcinogens. II. Short term in vivo studies.

Short term in vivo studies were performed to study biological effects of the common air pollutants SO2 or NOx and their influence on the genotoxic activities of nitrosamines. Hepatocytes and lung cells were isolated from Sprague-Dawley rats which had inhaled 50 p.p.m. of SO2 or NOx for 2 weeks. After incubating the cells for 1 h, genotoxicity was determined in hepatocytes by measuring DNA single-strand breaks induced by N-nitroso-acetoxymethylmethylamine, N-nitrosodimethylamine and N-nitrosomethylbenzylamine. Parameters of toxicity (trypan blue exclusion and leakage of serum enzymes) were determined in both liver and lung cells also following 1 h incubation. The activities of aryl hydrocarbon hydroxylase (AHH), nitrosodimethylamine demethylase (NDMA-D) and glutathione-S-transferase (GST) were determined in subcellular microsomal fractions isolated from lung and liver tissues. Finally, as a measure of overall toxicity, the activities of various serum enzymes were determined in the blood serum of the rats. It was found that the induction of DNA single-strand breaks by three nitrosamines was decreased in hepatocytes from SO2-treated animals. The viability of rat hepatocytes and of rat lung cells, as determined by trypan blue exclusion, was similar in all three treatment groups immediately after isolation, as well as after 1 h incubation with DMSO or with the nitrosamines. In contrast, the leakage of enzymes was different in hepatocytes of SO2-treated rats, since lactate dehydrogenase activity was decreased. Leakage of enzymes from the lung cells did not differ from group to group, but was lower than from hepatocytes. Foreign compound metabolizing enzymes were mainly decreased in NOx-treated animals, namely AHH, NDMA-D and GST in liver and GST in the lung. For SO2-treated animals NDMA-D was increased in liver and GST was decreased in lung. Blood serum enzyme levels were not greatly different from each other, except for lactate dehydrogenase which was elevated in SO2-exposed animals.

Effects of SO2 or NOx on toxic and genotoxic properties of chemical carcinogens. I. In vitro studies.

This paper describes in vitro studies on the effects of environmental pollutants (SO2/NOx) in biological systems. Basic physical, chemical and biochemical parameters were analyzed to establish the rate of SO2/NOx absorption by the culture medium. It was shown that the pH remains constant for 24 h of exposure to gas concentrations up to 50 p.p.m. The concentration of ions resulting from absorption of each pollutant in the liquid phase is dependent on their concentration in the gas phase and on exposure time. Short exposure times and high gas dosages resulted in similar doses in the medium as long exposure periods and low gas dosages. The activities of a human serum standard (alkaline phosphatase, ALP; aspartate amino transferase, AST; alanine amino transferase, ALT; gamma-glutamyltransferase, gamma-GT; lactate dehydrogenase, LDH) were determined after gaseous exposure to SO2 and NOx. The results revealed a distinct decrease in the activity of LDH after 1, 3 and 5 h exposure to 200 p.p.m. SO2. The effects of the pollutants were assayed in vitro using fetal hamster lung cells (FHLC), rat hepatocytes and the cell line CO60. For the determination of toxic effects, it was shown that the plating efficiency was a more sensitive parameter than the assay for trypan blue exclusion. Toxicity indicated as an increase of LDH leakage was not observed from FHLC in culture. Instead, a decrease of LDH was found following SO2 exposition. This decrease was similar to that observed for the human serum standard. The induction of DNA single-strand breaks was determined as a measure of genotoxic effects. SO2 application decreased the rate of DNA single-strand breaks induced by N-nitroso-acetoxymethyl-methylamine in both FHLC and in rat hepatocytes. SO2 or NOx treatment of CO60 cells for 1 h did not result in the induction of DNA amplification. HSO3- added directly to the medium as the sodium salt, however, distinctly induced the amplification of SV40 DNA. The amplification rates induced by benzo[a]pyrene or dimethylbenzanthracene were neither influenced by SO2, NOx nor HSO3-. An additive effect of HSO3- with either benzo[a]pyrene or dimethylbenzanthracene for this biological parameter was therefore not observed.