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. 1992 Apr 1;89(7):2531–2535. doi: 10.1073/pnas.89.7.2531

High frequency of single-base transitions and extreme frequency of precise multiple-base reversion mutations in poliovirus.

J C de la Torre 1, C Giachetti 1, B L Semler 1, J J Holland 1
PMCID: PMC48695  PMID: 1313561

Abstract

We employed independent clones of a temperature-sensitive mutant of type 1 poliovirus, 3AB-310/4, to quantitate the frequency of specific U----C transitions at nucleotide 5310, within the genomic region encoding polypeptide 3AB, which is involved in the initiation of RNA replication. Only this U----C base substitution restores the wild-type phenotypic ability to form plaques at 39 degrees C; the other two base substitutions at this site are lethal. The observed frequency of this specific transition averaged 2 x 10(-5), and all revertant viruses forming plaques at 39 degrees C contained the expected cytidine at nucleotide 5310. Incredibly, only 3 of 10 revertants exhibited this one specific U----C transition whereas 7 of 10 exhibited this same transition plus four additional base substitutions that precisely reverted temperature-sensitive 3AB-310/4 to wild-type poliovirus sequence (these latter four mutations had been introduced into 3AB-310/4 as silent third base mutations to provide new restriction sites in infectious cDNAs). No other mutations were detected in this polypeptide 3AB domain in either the single-base or the precise 5-base revertants. No intermediates were seen; all revertants exhibited either the single U----C transition at nucleotide 5310 or the same transition plus four precise reversions to the wild-type sequence at sites 8, 11, 43, and 46 bases distant from nucleotide 5310. Similar results were obtained after transfection of cDNA-derived transcripts. We discuss possible mechanisms for our data. These include (but may not be limited to) error-prone polymerase activity, sequential RNA recombination events joining independent mutations, or some unusual RNA editing process.

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Selected References

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