Showing papers by "Norwegian Institute of Public Health published in 1990"

Metabolic activation of 1,2-dibromo-3-chloropropane to mutagenic metabolites: detection and mechanism of formation of (Z)- and (E)-2-chloro-3-(bromomethyl) oxirane

Abstract: 1,2-Dibromo-3-chloropropane (DBCP), a haloalkane nematocide and soil fumigant, is metabolically activated to chemically reactive species that are direct-acting mutagens in a Salmonella typhimurium TA 100 test system. Studies in vitro with rat liver microsomes indicated that oxidation at carbon 3 resulted in the formation of an unstable gem-chlorohydrin that rearranged with elimination of hydrogen bromide to form (Z)-2-chloro-3-(bromomethyl)oxirane [(Z)-CBPO] and (E)-2-chloro-3-(bromomethyl)oxirane [(E)-CBPO]. Gas chromatography-mass spectrometry (GC-MS) with positive ion chemical ionization (CI) was employed to identify (Z)-CBPO and (E)-CBPO by comparison of characteristic fragment ions in their CI mass spectra with those observed for authentic standards. Quantitative GC-MS methodology was exploited to quantitate the rate of formation of (Z)-CBPO and (E)-CBPO from DBCP and analogues of DBCP specifically deuterated at carbon 1 and carbon 3. The rate of formation of Z- and E-isomers of CBPO was 31 and 33 pmol/(min.mg of protein), respectively, from DBCP; substitution with deuterium at carbon 1 increased the rate of epoxide formation by 50%, whereas CBPO formation could not be detected from a substrate labeled with deuterium at carbon 3. Both epoxides were directly acting mutagens to S. typhimurium TA 100. (Z)-CBPO caused approximately twice as many his+ revertants/nmol compared to (E)-CBPO. Oxidation at carbon 2 of DBCP resulted in the formation of a bifunctional alkylating agent, 1-bromo-3-chloroacetone, presumably via the intermediacy of an unstable gem-bromohydrin.(ABSTRACT TRUNCATED AT 250 WORDS)

Studies on the mitoinhibitory efect of orotic acid on heptocytes in primary culture

Abstract: Orotic acid (OA), a promoter of liver carcinogenesis, inhibited proliferation of primary hepatocytes in culture as monitored by labelling index, mitotic index and total DNA content. The mitoinhibitory effect of OA was seen even in the presence of a strong mitogen such as epidermal growth factor (EGF). The growth inhibitory effect of OA was not due to cell killing. Upon exposure to OA the hepatocytes exhibited an increase in the ratio of uridine nucleotides to adenosine nucleotides, and as this ratio increased the response of hepatocytes to proliferate in the presence or absence of EGF decreased. Washing the hepatocytes free of added OA resulted in a gradual decrease in the ratio of uridine nucleotides to adenosine nucleotides, paralleled by an increase in hepatocytic proliferation. Adenine, an agent that inhibits the metabolism of OA to uridine nucleotides, not only inhibited the increase in the ratio of uridine nucleotides to adenosine nucleotides but also counteracted the OA-induced mitoinhibitory effect. These results, together with our earlier observations, suggest that an imbalance in nucleotide pools composed of an increase in uridine nucleotides and a decrease in adenosine nucleotides appears to be important for OA-induced mitoinhibition.