Differential display identified changes in mRNA levels in regenerating livers from chloroform-treated mice.

The nongenotoxic-cytotoxic carcinogen chloroform induces liver necrosis, regenerative cell proliferation, and, eventually, liver tumors in female B6C3F1 mice when administered by gavage at doses of 238 or 477 mg/kg/d. Administration of 1800 ppm of chloroform in the drinking water results in similar daily doses but does not produce liver toxicity or cancer. The differential-display technique was used to compare the expression of a subset of mRNAs in normal (control) and regenerating liver after chloroform-induced toxicity to define the proportion of genes whose expression changes under hepatotoxic conditions and to identify the genes that might play a role in regeneration and perhaps cancer. RNA was purified from the livers of female B6C3F1 mice after 4 d or 3 wk of gavage treatment with 3, 238, or 477 mg/kg/d of chloroform or treatment with 1800 ppm chloroform in drinking water. There was a remarkably high degree of consistency of gene expression among the animals and across dose and treatment groups as visualized by the differential-display technique. Of the 387 bands observed, only four (about 1%) changed expression in regenerating liver. The genes were assigned locus names by GenBank after sequence submission. The genes with increased mRNA levels as confirmed by northern blot analysis were MUSTIS21, a mouse primary response gene induced by growth factors and tumor promoters; MUSMRNAH, a gene highly homologous to a human gene isolated from a prostate carcinoma cell line; and MUSFRA, a novel gene. The novel gene MUSFRB exhibited decreased mRNA levels. No change in expression was seen among control mice given the nontoxic regimens of 3 mg/kg/d chloroform or 1800 ppm chloroform in drinking water, indicating that changes in expression were associated with toxicity and regeneration rather than chloroform per se. These genes and others that may be identified by expanding this approach may play a role in regeneration and perhaps in the process of chloroform-induced carcinogenesis in rodent liver.

The role of O6-alkylguanine in cell killing and mutagenesis in Chinese hamster ovary cells.

Chinese hamster ovary cells with no detectable (less than 200 molecules/cell) O6-methylguanine-DNA methyltransferase (EC 2.1.1.63) were transfected with human cell DNA and pSV2neo plasmid by electroporation. Two stable transformant clones, GC-1 and GC-2, containing 4 X 10(4) and 4-6 X 10(3) methyltransferase molecules/cell respectively were isolated by successive screening in the presence of G418 and 2-chloroethyl-N-nitrosourea (CNU). Only three or four copies of pSV2neo DNA and no repetitive human DNA sequence were detected in these isolates. Secondary transfection of parent cells with GC-1 DNA yielded several clones containing 2-10 X 10(3) methyltransferase molecules/cell. The rate of removal of O6-methylguanine in GC-1, GC-2 and parent cells in vivo reflected their methyltransferase levels, while the N-methylpurines were removed at similar rates in all three cell lines. The differential sensitivity of these cells to several alkylating agents, namely CNU, N-methyl-N-nitrosourea, N-methyl-N'-nitro-N-nitrosoguanidine and methyl-methane sulfonate (MMS), known to yield different proportions of O6-alkylguanine among the alkyl adducts in DNA, varied widely. The largest and smallest differences in toxic response were observed with CNU and MMS respectively. These cell lines showed no difference in sensitivity to the DNA cross-linking agent psoralen. These data strongly suggest that alkylating agents produce two classes of lethal lesions, one of which is O6-alkylguanine. Induction of mutations at the hypoxanthine-phosphoribosyltransferase locus in these cells lines suggests that, regardless of its relative yield, O6-methylguanine is the major mutagenic lesion for all alkylating agents.