A specific increase in chloroplast gene mutations following growth of Chlamydomonas in 5-fluorodeoxyuridine.

Summary Growth of Chlamydomonas in the thymidine analog 5-fluorodeoxyuridine (FdUrd) leads to a reduction in the amount of chloroplast DNA and also alters the pattern of chloroplast gene transmission in crosses (Wurtz et al., 1977). We have now found that growth of Chlamydomonas in FdUrd also increases at least 10 to 20 fold the frequency of cells expressing antibiotic resistant or non-photosynthetic mutations in the chloroplast genome with no concomitant increase in nuclear gene mutations with similar phenotypes. Clearly this effect is not locus specific since the non-photosynthetic chloroplast mutations thus far isolated comprise 9 recombinationally separate loci in the chloroplast genome (Shepherd et al., 1977, 1979). Only with the use of FdUrd has isolation of this important class of non-photosynthetic mutations been possible. The efficiency of recovery of chloroplast gene mutations rises as FdUrd concentration increases from 0.1 to 1.0 mM. At higher concentrations of FdUrd, growth rates and mutant yields are reduced. We propose the analog increases the yield of chloroplast mutations by a two-step process in which mutations are first induced as a result of thymidine starvation and then become expressed because the chloroplast DNA has been greatly reduced in ploidy and possibly damaged. FdUrd has its maximal effect on both recovery of chloroplast gene mutations and chloroplast gene transmission in crosses after cells grown in the presence of the analog for several generations remain at stationary phase for about 24 h. These observations suggest that chloroplast DNA metabolism is very active in non-dividing stationary phase cells of Chlamydomonas.