16S ribosomal RNA modification drives transcript-specific translation efficiency

Bacterial ribosomal RNAs (rRNAs) are decorated with conserved nucleotide modifications, but the functionality of these modifications is often underexplored. MraW (RsmH) is a 16S rRNA methyltransferase that fine-tunes ribosomal function. We identified a loss-of-function allele in mraW that corrected a late-stage sporulation defect in Bacillus subtilis by bypassing a key sporulation checkpoint via altered translational regulation. Purified ribosomes isolated from {Delta}mraW cells displayed a [~]2-fold decrease in translation efficiency; in vivo, {Delta}mraW cells produced decreased levels of the sporulation checkpoint protein CmpA. This regulation was mediated by sequences from the 5 untranslated region and the coding sequence of cmpA, which form a step-loop structure that occlude early codons of the mRNA. Proteomic analysis revealed that MraW directly or indirectly regulates the production of multiple proteins, some of which form similar structural elements as the cmpA transcript. We propose that MraW modification of 16S rRNA enhances translation efficiency in general, and that specific transcripts, whose gene products are likely required in limiting quantities, have evolved structural features that act as a regulatory mechanism to govern protein levels. This type of regulation may be most apparent in bacteria which exhibit uncoupled transcription and translation. HIGHLIGHTSO_LIA conserved 16S rRNA modification enhances translation of structured mRNAs C_LIO_LIEarly mRNA stem-loops impose translational control dependent on ribosome modification C_LIO_LImRNA structure and rRNA modifications likely co-evolved to fine-tune protein dosage C_LI