Effects of translation on degradation of mRNA segments transcribed from the polycistronic puf operon of Rhodobacter capsulatus

Abstract

Previous work has shown that expression of genes within the polycistronic puf operon of Rhodobacter capsulatus is regulated in part by differential degradation of segments of puf transcripts. To understand the role of ribosome coverage in the differential stability of puf mRNA segments, we have studied the effects of mutations that alter translation of specific puf transcript segments on puf mRNA decay. Our results show that stopping translation either within the light-harvesting I (LHI) genes or near the 5' end of the reaction center (RC)-coding region decreased the stability of puf transcript segments downstream from a hairpin loop structure located between the LHI and RC genes but failed to affect the upstream sequences so long as the loop was present. Mutations that allowed translation to proceed through the hairpin structure reduced its ability to protect upstream sequences from accelerated decay. Introduction of translation stops more than 107 bp into the RC-coding region, but still 5' to an mRNA segment containing decay-promoting endonuclease cleavage sites, had no effect on puf mRNA stability. The divergent and location-dependent consequences of translation stops imply that different mechanisms are responsible for the degradation of different puf mRNA segments and indicate that coverage of puf mRNA sequences by ribosomes is insufficient and may in some cases be unnecessary to protect these sequences from degradation.