A translation-like cycle is a quality control checkpoint for maturing 40S ribosome subunits.

Assembly factors (AFs) prevent premature translation initiation on small (40S) ribosomal subunit assembly intermediates by blocking ligand binding. However, it is unclear how AFs are displaced from maturing 40S ribosomes, if or how maturing subunits are assessed for fidelity, and what prevents premature translation initiation once AFs dissociate. Here we show that maturation involves a translation-like cycle whereby the translation factor eIF5B, a GTPase, promotes joining of large (60S) subunits with pre-40S subunits to give 80S-like complexes, which are subsequently disassembled by the termination factor Rli1, an ATPase. The AFs Tsr1 and Rio2 block the mRNA channel and initiator tRNA binding site, and therefore 80S-like ribosomes lack mRNA or initiator tRNA. After Tsr1 and Rio2 dissociate from 80S-like complexes Rli1-directed displacement of 60S subunits allows for translation initiation. This cycle thus provides a functional test of 60S subunit binding and the GTPase site before ribosomes enter the translating pool.

Cofactor-dependent specificity of a DEAD-box protein.

DEAD-box proteins, a large class of RNA-dependent ATPases, regulate all aspects of gene expression and RNA metabolism. They can facilitate dissociation of RNA duplexes and remodeling of RNA-protein complexes, serve as ATP-dependent RNA-binding proteins, or even anneal duplexes. These proteins have highly conserved sequence elements that are contained within two RecA-like domains; consequently, their structures are nearly identical. Furthermore, crystal structures of DEAD-box proteins with bound RNA reveal interactions exclusively between the protein and the RNA backbone. Together, these findings suggest that DEAD-box proteins interact with their substrates in a nonspecific manner, which is confirmed in biochemical experiments. Nevertheless, this contrasts with the need to target these enzymes to specific substrates in vivo. Using the DEAD-box protein Rok1 and its cofactor Rrp5, which both function during maturation of the small ribosomal subunit, we show here that Rrp5 provides specificity to the otherwise nonspecific biochemical activities of the Rok1 DEAD-domain. This finding could reconcile the need for specific substrate binding of some DEAD-box proteins with their nonspecific binding surface and expands the potential roles of cofactors to specificity factors. Identification of helicase cofactors and their RNA substrates could therefore help define the undescribed roles of the 19 DEAD-box proteins that function in ribosome assembly.

The roles of S1 RNA-binding domains in Rrp5's interactions with pre-rRNA.

RNA-binding proteins mediate the function of all RNAs. Since few distinct RNA-binding domains (RBDs) exist, with most RBDs contacting only a few nucleotides, RNA-binding proteins often combine multiple RNA-binding motifs to achieve a higher affinity and selectivity for their targets. Rrp5, a ribosome assembly factor essential for both 40S and 60S ribosome maturation, is an extreme example as it contains 12 tandem S1 RNA-binding domains. In this study, we use a combination of RNA binding and DMS probing experiments to probe interactions of Rrp5 with pre-rRNA mimics. Our data localize Rrp5's binding site to three distinct regions within internal transcribed spacer 1 (ITS1), the sequence between 18S and 5.8S rRNAs. One of these regions is directly adjacent to a recently uncovered helical structure, which prevents premature cleavage at the 3'-end of 18S rRNA. This finding, together with previous results, suggests a role for Rrp5 in regulating the above-mentioned helical element. Furthermore, we have produced two truncated forms of the protein, Rrp5N and Rrp5C, which together encompass the entire protein and fully restore growth. Quantitative analysis of the RNA affinity of these Rrp5 fragments indicates that the first nine S1 motifs contribute much of Rrp5's RNA affinity, while the last three domains alone provide its specificity for the pre-rRNA. This surprising division of labor is unique, as it suggests that S1 domains can bind RNA both specifically as well as nonspecifically with high affinity; this has important implications for the molecular details of the Rrp5•pre-rRNA complex.