Effect of benzo[a]pyrene-diolepoxide on infectivity and in vitro translation of phage MS2 RNA.

Abstract

Previous studies have shown that alkylation of MS2 RNA by certain derivatives of polycyclic aromatic hydrocarbons renders it noninfectious. Since phage RNA serves as a template for translation and transcription, either of these RNA-directed processes, or both, could be responsible in vivo for the inhibition of phage replication by metabolically activated hydrocarbons. The present study correlates the degree of inhibition of MS2 RNA infectivity, at various levels of alkylation by (+/-)-trans, 7,8-dihydroxy-anti-9,10-epoxy-7,8,9,10-tetrahydrobenzol[a]pyrene, with the translation efficiency in vitro of the same alkylated RNA for the synthesis of viral synthetase and of maturation and coat proteins. The results indicate that dihydroxyepoxy-tetrahydrobenzo[a]pyrene modification of MS2 RNA impairs its template capacity for the synthesis of phage-specific proteins; this inhibition is insufficient, however, to account for the loss of RNA infectivity at lower molar ratios of alkylation. For the three viral proteins synthesized in vitro, the translation of RNA synthetase is much more sensitive to MS2 RNA modification than either coat or maturation protein synthesis. Our results also indicate that the loss of viral RNA infectivity follows a single-hit inactivation mechanism, whereas several alkylation events in the viral RNA synthetase cistron may be necessary to block translation of this gene product.