Abstract
Steady-state dihydrofolate reductase (dhfr) mRNA levels were decreased as a result of nonsense mutations in the dhfr gene. Thirteen DHFR-deficient mutants were isolated after treatment of Chinese hamster ovary cells with UV irradiation. The positions of most point mutations were localized by RNA heteroduplex mapping, the mutated regions were isolated by cloning or by enzymatic amplification, and base changes were determined by DNA sequencing. Two of the mutants suffered large deletions that spanned the entire dhfr gene. The remaining 11 mutations consisted of nine single-base substitutions, one double-base substitution, and one single-base insertion. All of the single-base substitutions took place at the 3' position of a pyrimidine dinucleotide, supporting the idea that UV mutagenesis proceeds through the formation of pyrimidine dimers in mammalian cells. Of the 11 point mutations, 10 resulted in nonsense codons, either directly or by a frameshift, suggesting that the selection method favored a null phenotype. An examination of steady-state RNA levels in cells carrying these mutations and a comparison with similar data from other dhfr mutants (A. M. Carothers, R. W. Steigerwalt, G. Urlaub, L. A. Chasin, and D. Grunberger, J. Mol. Biol., in press) showed that translation termination mutations in any of the internal exons of the gene gave rise to a low-RNA phenotype, whereas missense mutations in these exons or terminations in exon 6 (the final exon) did not affect dhfr mRNA levels. Nuclear run-on experiments showed that transcription of the mutant genes was normal. The stability of mature dhfr mRNA also was not affected, since (i) decay rates were the same in wild-type and mutant cells after inhibition of RNA synthesis with actinomycin D and (ii) intronless minigene versions of cloned wild-type and nonsense mutant genes were expressed equally after stable transfection. We conclude that RNA processing has been affected by these nonsense mutations and present a model in which both splicing and nuclear transport of an RNA molecule are coupled to its translation. Curiously, the low-RNA mutant phenotype was not exhibited after transfer of the mutant genes, suggesting that the transcripts of transfected genes may be processed differently than are those of their endogenous counterparts.
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