Aryl sulfotransferase IV deficiency in rat liver carcinogenesis initiated with diethylnitrosamine and promoted with N-2-fluorenylacetamide or its C-9-oxidized metabolites.

Down regulation of aryl sulfotransferase IV (AST IV) in promotion/progression of liver carcinogenesis by N-2-fluorenylacetamide (2-FAA) has been established. This study examined whether the C-9 oxidized metabolites of 2-FAA, which have recently been shown to promote diethylnitrosamine (DEN)-initiated liver carcinogenesis in male Sprague-Dawley rats, effect the above change. Hence, in DEN-initiated rats, the effects of promoting regimens of 9-OH-2-FAA or 9-oxo-2-FAA, 15 oral doses at 50 and 100 mumol/kg of body weight, were compared to those of 2-FAA at 50 mumol/kg of body weight and of the vehicle on the activity of N-hydroxy(OH)-2-FAA sulfotransferase (ST), an isozyme of AST IV and AST IV expression and distribution. Relative to the vehicle, treatment with the fluorenyl compounds led to decreased levels in hepatic N-OH-2-FAA ST activity and development of hepatic nodules and tumors which had still lower levels of the ST activity than the respective remnant livers. At approximately 8 months after treatment with the C-9-oxidized compounds at doses twice that of 2-FAA, the extents of decreases in the hepatic N-OH-2-FAA ST activity and cytosolic AST IV protein in tumors were comparable to those with 2-FAA. Immunocytochemical analysis showed close association of AST IV deficiency with neoplastic liver lesions. In comparison to N-OH-2-FAA, 9-OH-2-FAA had only low and 9-oxo-2-FAA lacked sulfate acceptor activity in the presence of male rat liver cytosol or AST IV. At 3.3-fold greater concentration than N-OH-2-FAA, 9-oxo-2-FAA inhibited (27%) the sulfate acceptor activity of N-OH-2-FAA in the presence of AST IV, which suggested interference by 9-oxo-2-FAA at the active site. Although the C-9-oxidized compounds do not appear to be substrates for N-OH-2-FAA ST, their ability to cause a decrease in N-OH-2-FAA ST activity and protein similar to that of 2-FAA supports their role in hepatocarcinogenesis. Whereas 9-OH-2-FAA had a 3.9-fold greater sulfate acceptor activity in the presence of female than male rat liver cytosol and inhibited dehydroepiandrosterone ST activity of female rat liver, N-OH-2-FAA and 9-oxo-2-FAA inhibited estrone ST activity of male rat liver, suggesting that the C-9-oxidized compounds as well as N-OH-2-FAA are substrates for STs other than AST IV.

Homodimeric and heterodimeric aryl sulfotransferases catalyze the sulfuric acid esterification of N-hydroxy-2-acetylaminofluorene.

Three aryl sulfotransferases (ASTs) isolated from rat liver catalyze the sulfuric acid esterification of the carcinogen N-hydroxy-2-acetylaminofluorene (N-OH-2AAF). These three ASTs were separated by high resolution anion exchange chromatography and were designated Q1, Q2, and Q3. Q1 and Q2 had high N-OH-2AAF sulfonation activity, whereas Q3 showed low activity. Reversed phase high performance liquid chromatography/mass spectrometry analysis showed Q1-Q3 to be comprised of 33,945- and 35,675-Da protein subunits. Q1 contained only the 35,675-Da protein subunit, Q2 contained equal quantities of 33,945- and 35,675-Da subunits, and Q3 contained only the 33,945-Da subunit. The subunit compositions of Q1-Q3 were confirmed by immunochemical analysis. Size exclusion high performance liquid chromatography confirmed that the active quaternary structure of the three isoenzymes was dimeric. Analysis of liver cytosols for the relative contributions of Q1-Q3 to total cytosolic N-OH-2AAF sulfotransferase activity indicated the Q1, Q2, and Q3 accounted for 44, 46, and 10% of the activity, respectively. These results demonstrate the existence of both homodimeric and heterodimeric aryl sulfotransferases and show that two ASTs, a homodimer of 35,675-Da subunits and a heterodimer of a 33,945- and a 35,675-Da subunit, are primarily responsible for hepatic N-OH-2AAF sulfotransferase activity.

Changes in levels of ADP-ribose polymers in rat liver during 2-acetylaminofluorene-induced hepatocarcinogenesis.

The exposure of rats to the carcinogen 2-acetylaminofluorene (2-AAF) results in the accumulation of DNA-damaging adducts. The inability of cells to repair such damage adequately is a putative causal event in chemical carcinogenesis. It has been shown that one cellular response to DNA damage that leads to DNA repair is poly(ADP-ribosyl)ation of nuclear proteins. To examine the possible existence of an altered poly(ADP-ribosyl)ation response to 2-AAF-mediated damage of rat liver DNA, tissue ADP-ribose polymer levels were determined during various stages of 2-AAF-mediated carcinogenesis. 2-AAF was administered to rats in a discontinuous feeding regimen comprised of five consecutive cycles, each cycle consisting of 3 weeks on 2-AAF diet followed by 1 week of recovery on a control diet without 2-AAF. During cycle one of 2-AAF administration, rat liver ADP-ribose polymer levels increased 3-fold over that found in livers of rats fed only the control diet. In contrast, when rats were administered the non-genotoxic liver mitogen 4-AAF for one cycle, no significant elevation occurred in ADP-ribose polymer levels. Elevated ADP-ribose polymer production was also observed during cycles two and three of 2-AAF administration. However, during cycles four and five of 2-AAF administration, a period when rats administered 2-AAF acquire a high risk for hepatocarcinogenesis, an altered pattern of ADP-ribose polymer production occurred in rat livers. ADP-ribose polymer levels in these rat livers remained low, similar to levels found in control rat livers, despite the administration of 2-AAF. When the livers from rats fed either one or five cycles of 2-AAF were analyzed for possible decreases in the levels of tissue NAD+, the substrate for poly(ADP-ribose) polymerase, no changes in relative abundance were found. In addition, analysis of poly(ADP-ribose) polymerase activity showed no decrease at five cycles of 2-AAF administration. These results indicated that at late stages of 2-AAF-induced hepatocarcinogenesis, 2-AAF does not induce an expected increase in ADP-ribose polymer levels, and suggested that significant changes in DNA repair may occur at a time just preceding an increased risk for developing liver cancer.

High resolution fractionation and characterization of ADP-ribose polymers.

Methods are described for the high resolution fractionation and characterization of ADP-ribose polymers. Polymers prepared in vitro using purified poly(ADP-ribose) polymerase were isolated free from interfering nucleic acids and salts using dihydroxyboronyl-Bio-Rex 70 chromatography and fractionated using anion exchange high-pressure liquid chromatography. The homogeneity of isolated polymer fractions was characterized by gel electrophoresis and polymer size was determined by analysis following enzymatic digestion to nucleosides. The method allows isolation of oligomers up to 50 mer as single species and larger polymers can be isolated free from oligomers according to size and branching frequency. The ability to isolate individual species of ADP-ribose polymers should prove useful for the study of the polymers and their noncovalent interactions with other components of chromatin. Microheterogeneity of individual oligomers was studied and shown to be due to differences at the protein proximal ends resulting from the chemical method of release of polymers from protein. The method also was applied to fractionate polymers generated in intact cultured mouse cells in response to treatment with the carcinogen N-methyl-N'-nitro-N-nitrosoguanidine.