Chromosomal changes in cell lines from mouse tumors induced by nickel sulfide and methylcholanthrene

Mutagenicity of soluble and insoluble nickel compounds at the gpt locus in G12 Chinese hamster cells

Nickel is an established human and animal carcinogen, but efforts to demonstrate its mutagenicity in a number of cell types have not been successful. In this report we describe the mutational response to nickel compounds in the G12 cell line, an hprt deficient V79 cell line containing a single copy of the E. coli gpt gene. This cell line has a low spontaneous background, making it suitable for assessment of mutagenic responses to environmental contaminants. When G12 cells were treated with insoluble particles of crystalline nickel sulfide < 5 microns in diameter, a strong, dose-dependent mutagenic response was observed up to 80 times the spontaneous background. Of 48 mutant gpt(-) clones isolated that were induced by insoluble nickel, all were capable of DNA amplification of the gpt sequences by polymerase chain reaction (PCR). The ability to produce full-length PCR products is an indication that large deletions of gene sequences have not occurred. When G12 cells were treated with soluble nickel sulfate, the mutational response was not significantly increased over the spontaneous background. This difference in mutagenic response reflects a large difference in the mutagenic potential of soluble and insoluble nickel compounds, which reflects the carcinogenic potential of these forms of nickel.

The effect of Ni(II) on DNA replication

The cellular regulation of DNA replication is governed in part by the availability of essential metal ions. A continuous supply of Mg(II) ions is necessary for the efficient and faithful replication of parental strands during S-phase as well as during the repair of DNA damage. A metal ion such as Ni(II) may interfere with the replication process by binding to sites on proteins at which essential ions normally bind. Binding at these sites by a toxic metal ion may produce inappropriate responses from the replication proteins and thus alter the normal balance in one or more of the microsteps comprising DNA synthesis. We have studied the effect of Ni(II) on DNA replication in a reconstituted in vitro system using a HeLa cell extract as a source of polymerase activity on a template of activated calf thymus DNA. Ni(II) has an initial stimulatory effect that is followed by an overall inhibition of the incorporation of DNA precursors. These results suggest that Ni(II), similar to Mg(II) may have more than one binding site, but that the binding of Ni(II) to replication proteins may significantly alter the timing of events in DNA synthesis.