Albiana Pino

Negative evidence in vivo of DNA-damaging, mutagenic and chromosomal effects of eugenol

The DNA-damaging, mutagenic and chromosomal effects of eugenol were assayed by the DNA alkaline elution technique, the granuloma pouch assay and the bone marrow micronucleus test in rats. With all the techniques used, eugenol did not show any genotoxic activity.

Formation of DNA‐damaging nitroso compounds by interaction of drugs with nitrite. A preliminary screening for detecting potentially hazardous drugs

Fifty-seven theoretically nitrosatable widely used drugs that are commonly administered orally have been screened to determine the formation of nitroso compounds by drug-nitrite interaction and to evaluate the genotoxicity of their nitrosation products against Chinese hamster ovary (CHO) cells, measured as DNA-damaging potency by the alkaline elution technique. The drug (0.1 mmol) was reacted with NaNO2 (0.4 mmol) at pH 3-3.5 for 1 h. Nitroso compounds were present in varying yield in the nitrosation mixture of 47 drugs. Twenty-two drugs formed direct-acting nitroso compounds capable of producing DNA fragmentation, i.e., a statistically significant (p less than 0.01) increase in the elution rate of CHO cell DNA. On a molar basis, their DNA-damaging potency varied over a 570-fold range, with 12 exhibiting greater potency than that of N-nitroso-N-methylurea.

DNA damage in stomach, kidney, liver and lung of rats treated with atrazine

The genotoxic activity of atrazine, a widely used triazine herbicide, was assayed by the DNA alkaline elution technique in rats given orally a single high dose or repeated daily doses. DNA breaks (and/or alkali-labile lesions) were detected in cell suspensions obtained from stomach, kidney and liver, but not in those from lung.

DNA Alkaline Elution: Physical Basis of the Elution Process and Validation of this Method as a Screening Procedure to Identify Chemical Carcinogens

The alkaline elution technique, developed by Kohn and coworkers (Kohn and Ewig, 1973; Kohn et al., 1976; Kohn, 1979), provides a sensitive measurement of DNA single-strand size distribution in mammalian cells and represents an advanced alternative to the technique of alkaline sucrose gradient sedimentation. Alkaline elution of DNA from cell lysates allows size measurement of DNA single strands longer than the sizes that can be measured by sedimentation in alkaline sucrose gradients. The elution technique requires relatively simple and not expensive apparatuses, and is less time-consuming in comparison with the latter. Moreover, it gives more repeatable results and is more suitable to assess DNA damage from various tissues following in vivo exposure to DNA interacting agents. In the last few years, this technique has been widely applied by different groups of researchers to the study of various DNA lesions induced by several physical or chemical agents (ranging from carcinogens to antineoplastic agents), and a large series of results have been collected. The aims of this review are: to discuss the physical basis that governs DNA elution, to summarize the possible application of this method, to revise the use of alkaline elution and its reliability in the assessment of DNA fragmentation in various organs of mice and rats following in vivo exposure to chemical agents, and to evaluate critically its role as a screening procedure for carcinogenic compounds.

DNA fragmentation by N-nitrosodimethylamine and methyl methanesulfonate in human hepatocyte primary cultures.

The ability of N-nitrosodimethylamine (DMN) and methyl methanesulfonate (MMS) to induce DNA damage in primary cultures of human hepatocytes was examined by the alkaline elution technique. Both the agents induced a dose-dependent increase in DNA elution rate, but appreciable differences in the degree of response to the procarcinogen DMN were observed among cultures obtained from the livers of four patients. A comparative analysis of DNA fragmentation indicated a substantial similarity between human and concurrently studied rat hepatocytes in their response to both DMN and MMS.

Evaluation of DNA damage induced by norfloxacin in liver and kidney of adult rats and in fetal tissues after transplacental exposure

Norfloxacin, a recently developed antimicrobial fluoroquinolone, was investigated for DNA-damaging activity in rat liver and kidney. After oral administration of single doses ranging from 1 to 8 mmole/kg, DNA fragmentation was absent in liver and kidney both 2 and 6 h after treatment. However, when administered to pregnant rats, the highest doses produced a detectable amount of DNA damage in fetal tissues. This damage appears to be an aspecific consequence of maternal and fetal toxicity rather than a specific genotoxic effect.

Genotoxic activity of five antidepressant hydrazines in a battery of in vivo and in vitro short-term tests.

Five antidepressant agents (monoamine oxidase inhibitors) having a hydrazino group--phenelzine, nialamide, mebanazine, isocarboxazid, and iproniazid--were assayed in four in vivo or in vitro short-term tests predictive of the potential carcinogenicity of chemicals. (1) All the compounds tested except iproniazid, produced DNA fragmentation, as evaluated by the alkaline elution technique, in liver and/or lung cells of mice treated ip or po. (2) All the compounds except mebanazine (which was no longer available for testing) were weak inducers of sister chromatid exchanges in bone marrow cells of mice treated ip. (3) Phenelzine and nialamide elicited base-pair substitutions and mebanazine elicited frameshift errors in his- Salmonella typhimurium. S9 mix containing rat liver, mouse liver, or mouse lung S9 fractions had variable effects on mutagenicity. (4) The same three compounds were positive in a DNA repair bacterial test with five trp- Escherichia coli strains lacking a variety of repair mechanisms (uvrA, polA, recA, lexA) or incorporating plasmids (R391).

Induction of sperm abnormalities in mice by norfloxacin

Norfloxacin was tested in the mouse sperm morphology test. Data obtained suggest that norfloxacin may have 2 different effects on sperm development: a stimulating effect on spermatogenesis and a possible mutagenic effect that results in an increase in sperm abnormalities. The first effect might be caused by a hormonal action. A dose-response relationship was not observed in sperm morphology changes. Consequently norfloxacin cannot with certainty be judged a positive inducer of abnormal sperm, but further studies are essential to clarify the obtained results.

Dna damage induced by nitrosated ranitidine in cultured mammalian cells

Ranitidine, a new H-2 receptor antagonist more potent than cimetidine in inhibiting gastric secretion, reacted under acid conditions with a twofold molar amount of nitrite (a nitrite/ranitidine ratio about 1000 times that likely to occur in gastric juice of treated humans) yielding a nitroso derivative capable of inducing a dose-dependent DNA fragmentation in cultured Chinese hamster ovary cells.

DNA-damaging activity of tripelennamine in primary cultures of human hepatocytes

The genotoxicity of tripelennamine, an antihistamine used in the treatment of allergic disorders, was examined in human hepatocyte primary cultures derived from 3 different donors, after exposure to non-toxic concentrations ranging from 10 to 100 microM. A modest but statistically significant and dose-related amount of autoradiographic DNA repair was present in cultures from two donors. DNA fragmentation, as measured by alkaline elution, was found to occur in dose-dependent amounts in cultures of all the 3 donors. These findings, which agree with the previously observed capability of tripelennamine to induce DNA repair and fragmentation in rat hepatocytes, strengthen the suspicion of a potential genotoxic risk of this drug to humans.