Abstract
The circularly permuted GTPase YlqF is essential for cell viability and is broadly conserved from Gram-positive bacteria to eukaryotes. We previously reported that YlqF participates in the late step of 50 S ribosomal subunit assembly in Bacillus subtilis. Here, we demonstrate that an N-terminal deletion mutant of YlqF (YlqFDeltaN10) inhibits cell growth even in the presence of wild-type YlqF. In contrast to the wild-type protein, the GTPase activity of this mutant was not stimulated by the 50 S subunit and did not dissociate from the premature 50 S subunit. Thus, YlqFDeltaN10 acts as a competitive inhibitor of wild-type YlqF. Premature 50 S subunit lacking ribosomal protein L27 and with a reduced amount of L16 accumulated in YlqFDeltaN10-overexpressing cells and in YlqF-depleted cells, suggesting that YlqFDeltaN10 binds to the premature 50 S subunit. Moreover, premature 50 S subunit from both YlqFDeltaN10-overexpressing and YlqF-depleted cells more strongly enhanced the GTPase activity of YlqF than the mature 50 S subunit of the 70 S ribosome. Collectively, our results indicate that YlqF is targeted to the premature 50 S subunit lacking ribosomal proteins L16 and L27 to assemble functional 50 S subunit through a GTPase activity-dependent conformational change of 23 S rRNA.
Highlights
Most of these GTP-binding proteins, except for Ffh and FtsY, which are involved in protein secretion, and FtsZ, which is involved in cell division, play important roles in ribosome function, including translation and biogenesis
The GTPase activity of these mutants is not stimulated by ribosome binding, and they remain bound to the ribosome after formation of 70 S initiation complex, demonstrating that GTP hydrolysis is coupled with its dissociation from the 70 S initiation complex and is important for translation initiation and the recycling of IF-2
The bacterial ribosome consists of two subunits, 30 S and 50 S, which are composed of three rRNAs and more than 50 ribosomal proteins [33]
Summary
Unit from YlqF⌬N10-overexpressing and YlqF-depleted cells greatly enhanced the GTPase activity of wild-type YlqF compared with mature 50 S subunit purified from 70 S ribosome particles. We found that the free 50 S fraction separated by sucrose density gradient centrifugation caused a similar degree of YlqF GTPase activation as the premature subunits. We found that the mature 50 S subunit activates the GTPase activity of YlqF in low magnesium conditions. Based on these results, we propose a revised model of the role of YlqF in the biogenesis of the 50 S subunit
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