Abstract
The ribosomal protein S1, in Escherichia coli, is necessary for the recognition by the ribosome of the translation initiation codon of most messenger RNAs. It also participates in other functions. In particular, it stimulates the T4 endoribonuclease RegB, which inactivates some of the phage mRNAs, when their translation is no longer required, by cleaving them in the middle of their Shine-Dalgarno sequence. In each function, S1 seems to target very different RNAs, which led to the hypothesis that it possesses different RNA-binding sites. We previously demonstrated that the ability of S1 to activate RegB is carried by a fragment of the protein formed of three consecutive domains (domains D3, D4, and D5). The same fragment plays a central role in all other functions. We analyzed its structural organization and its interactions with three RNAs: two RegB substrates and a translation initiation region. We show that these three RNAs bind the same area of the protein through a set of systematic (common to the three RNAs) and specific (RNA-dependent) interactions. We also show that, in the absence of RNA, the D4 and D5 domains are associated, whereas the D3 and D4 domains are in equilibrium between open (noninteracting) and closed (weakly interacting) forms and that RNA binding induces a structural reorganization of the fragment. All of these results suggest that the ability of S1 to recognize different RNAs results from a high adaptability of both its structure and its binding surface.
Highlights
Eral Gram-positive bacteria [1, 2]
These studies were performed on different systems and lead to contradictory results: an extended structure according to SAXS, a compact structure according to sedimentation and electron microscopy
S1 is supposed to interact with mRNA before it enters the ribosome, but S1 seems located in the cleft between the head and the platform of the 30 S subunit, close to the 3Ј end of the 16 S rRNA and, to the 5Ј end of bound mRNA [22, 44]
Summary
Eral Gram-positive bacteria [1, 2]. A shorter form (45 kDa) exists in chloroplasts [3], but S1 is otherwise absent of eukaryotic cells. We demonstrated that an S1 fragment composed of the domains D3, D4, and D5 (F3–5) accelerates the cleavage rate of short RNAs by the endoribonuclease RegB with the same efficiency as the whole S1 protein [17] All of these results emphasize the central role of the region formed of the domains D3, D4, and D5 in these functions. In the light of the particular role played by the region formed of the D3, D4, and D5 domains of S1 and the biological activity of the isolated corresponding F3–5 fragment (activation of the endoribonuclease RegB), we have decided to study its structural organization and its interactions with different RNAs by NMR spectroscopy. They strongly support the hypothesis that all S1 functions are mechanistically related and that RNA binding is associated to structural modifications in the fragment
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