Distances between 3' ends of ribosomal ribonucleic acids reassembled into Escherichia coli ribosomes

The three ribonucleic acids (RNAs) from Escherichia coli ribosomes were isolated and then labeled at their 3' ends by oxidation with periodate followed by reaction with thiosemicarbazides of fluorescein or eosin. Ribosomal subunits reconstituted with the labeled RNAs were active for polyphenylalanine synthesis. The distances between the 3' ends of the RNAs in 70S ribosomes were estimated by nonradiative energy transfer from fluorescein to eosin. The percentage of energy transfer was calculated from the decrease in fluorescence lifetime of fluorescein in the quenched sample compared to the unquenched sample. Fluorescence lifetime was measured in real time by using a mode-locked laser for excitation and a high-speed electrostatic photomultiplier tube for detection of fluorescence. The distances between fluorophores attached to the 3' ends of 16S RNA and 5S RNA or 23S RNA were estimated to be about 55 and 71 A, respectively. The corresponding distance between the 5S RNA and 23S RNA was too large to be measured reliably with the available probes but was estimated to be greater than 65 A. Comparison of the quantum yields of the labeled RNAs free in solution and reconstituted into ribosomal subunits suggests that the 3' end of 16S RNA does not interact appreciably with other ribosomal components and may be in a relatively exposed position, whereas the 3' ends of the 5S RNA and 23S RNA may be buried in the 70S ribosomal subunit.     

Intermolecular base-paired interaction between complementary sequences present near the 3'' ends of 5S rRNA and 18S (16S) rRNA might be involved in the reversible association of ribosomal subunits.

Highly conserved sequences present at an identical position near the 3' ends of eukaryotic and prokaryotic 5S rRNAs are complementary to the 5' strand of the m2(6)A hairpin structure near the 3' ends of 18S rRNA and 16S rRNA, respectively. The extent of base-pairing and the calculated stabilities of the hybrids that can be constructed between 5S rRNAs and the small ribosomal subunit RNAs are greater than most, if not all, RNA-RNA interactions that have been implicated in protein synthesis. The existence of complementary sequences in 5S rRNA and small ribosomal subunit RNA, along with the previous observation that there is very efficient and selective hybridization in vitro between 5S and 18S rRNA, suggests that base-pairing between 5S rRNA in the large ribosomal subunit and 18S (16S) rRNA in the small ribosomal subunit might be involved in the reversible association of ribosomal subunits. Structural and functional evidence supporting this hypothesis is discussed.     

Localization of L11 on the Escherichia coli ribosome by singlet-singlet energy transfer

Isolated Escherichia coli ribosomal protein L11 was labeled with maleimidyl derivatives of coumarin or fluorescein at the thiol group of its single cysteine, then reconstituted singly or in pairs with other fluorescently labeled ribosomal components. The characteristics of fluorescence from the labeled protein were studied and its distance to other components was determined by non-radiative energy transfer. The distance between probes on L11 and cysteine residues on other proteins or the 3' end of the ribosomal RNAs were found to be: S1, 7.4-8.3 nm; S21, 7.6 nm; 23S RNA, 6.9 nm; 5S RNA, 7.6 nm; 16S RNA, greater than 8.5 nm. Considered together with previously published results these distances indicate that the location of L11 in the 50S subunit is below the lateral protuberance characterized by L7/L12.     

Initiation factor 3-induced structural changes in the 30 S ribosomal subunit and in complexes containing tRNA(f)(Met) and mRNA

Initiation factor 3 (IF3) acts to switch the decoding preference of the small ribosomal subunit from elongator to initiator tRNA. The effects of IF3 on the 30 S ribosomal subunit and on the 30 S.mRNA. tRNA(f)(Met) complex were determined by UV-induced RNA crosslinking. Three intramolecular crosslinks in the 16 S rRNA (of the 14 that were monitored by gel electrophoresis) are affected by IF3. These are the crosslinks between C1402 and C1501 within the decoding region, between C967xC1400 joining the end loop of a helix of 16 S rRNA domain III and the decoding region, and between U793 and G1517 joining the 790 end loop of 16 S rRNA domain II and the end loop of the terminal helix. These changes occur even in the 30 S.IF3 complex, indicating they are not mediated through tRNA(f)(Met) or mRNA. UV-induced crosslinks occur between 16 S rRNA position C1400 and tRNA(f)(Met) position U34, in tRNA(f)(Met) the nucleotide adjacent to the 5' anticodon nucleotide, and between 16 S rRNA position C1397 and the mRNA at positions +9 and +10 (where A of the initiator AUG codon is +1). The presence of IF3 reduces both of these crosslinks by twofold and fourfold, respectively. The binding site for IF3 involves the 790 region, some other parts of the 16 S rRNA domain II and the terminal stem/loop region. These are located in the front bottom part of the platform structure in the 30 S subunit, a short distance from the decoding region. The changes that occur in the decoding region, even in the absence of mRNA and tRNA, may be induced by IF3 from a short distance or could be caused by the second IF3 structural domain.     

Localization of the elongation factor Tu binding site on Escherichia coli ribosomes

Fluorescent techniques were used to study binding of peptide elongation factor Tu (EF-Tu) to Escherichia coli ribosomes and to determine the distances of the bound factor to points on the ribosome. Thermus thermophilus EF-Tu was labeled with 3-(4-maleimidylphenyl)-4-methyl-7-(diethyl-amino)coumarin (CPM) without loss of activity. In the presence of Phe-tRNA and a nonhydrolyzable analogue of GTP, 70S ribosomes bind the CPM-EF-Tu [Kb = (3 +/- 1.2) X 10(6) M-1] causing a decrease of CPM fluorescence. Binding of CPM-EF-Tu to 50S subunits was at least 1 order of magnitude lower than with 70S ribosomes, and binding to 30S subunits could not be detected. Reconstituted 70S ribosomes containing either S1 labeled with fluoresceinmaleimide or ribosomal RNAs labeled at their 3' ends with fluorescein thiosemicarbazide were used for energy transfer from CPM-EF-Tu. The distances between CPM-EF-Tu bound to the ribosomes and the 3' ends of 16S RNA, 5S RNA, 23S RNA, and the closest sulfhydryl group of S1 were calculated to be 82, 70, 73, and 62-68 A, respectively.     

Organization of the 16S rRNA around its 5' terminus determined by photochemical crosslinking in the 30S ribosomal subunit

The organization of the 5' terminus region in the 16S rRNA was investigated using a series of RNA constructs in which the 5' terminus was extended by 5 nt or was shortened to give RNA molecules that started at positions -5, +1, +5, +8, +14, or +21. The structural and functional effects of the 5' extension/truncations were determined after the RNAs were reconstituted. 30S subunits containing 16S rRNA with 5' termini at -5, +1, +5, +8 and +14 had similar structures (judged by UV-induced crosslinking) and exhibited a gradual reduction in tRNA binding activity compared to that seen with 30S subunits reconstituted with native 16S rRNA. To create the 5' terminal site-specific photocrosslinking agent, the reagent azidophenacylbromide (APAB) was attached to the 5' terminus of 16S rRNA through a guanosine monophosphorothioate and the APA-16S rRNAs were reconstituted. Crosslinking carried out with the APA revealed sites in six regions around positions 300-340, 560, 900, 1080, the 16S rRNA decoding region, and at 1330. Differences in the pattern and efficiency of crosslinking for the different constructs allow distance estimates for the crosslinked sites from nucleotide G9. These measurements provide constraints for the arrangement of the RNA elements in the 30S subunit. Similar experiments carried out in the 70S ribosome resulted in a five- to tenfold lower frequency of crosslinking. This is most likely due to a repositioning of the 5' terminus upon subunit association.     

A snapshot of the 30S ribosomal subunit capturing mRNA via the Shine-Dalgarno interaction

In the initiation phase of bacterial translation, the 30S ribosomal subunit captures mRNA in preparation for binding with initiator tRNA. The purine-rich Shine-Dalgarno (SD) sequence, in the 5' untranslated region of the mRNA, anchors the 30S subunit near the start codon, via base pairing with an anti-SD (aSD) sequence at the 3' terminus of 16S rRNA. Here, we present the 3.3 A crystal structure of the Thermus thermophilus 30S subunit bound with an mRNA mimic. The duplex formed by the SD and aSD sequences is snugly docked in a "chamber" between the head and platform domains, demonstrating how the 30S subunit captures and stabilizes the otherwise labile SD helix. This location of the SD helix is suitable for the placement of the start codon AUG in the immediate vicinity of the mRNA channel, in agreement with reported crosslinks between the second position of the start codon and G1530 of 16S rRNA.     

Using a targeted chemical nuclease to elucidate conformational changes in the E. coli 30S ribosomal subunit

Determining the detailed tertiary structure of 16S rRNA within 30S ribosomal subunits remains a challenging problem. The particular structure of the RNA which allows tRNA to effectively interact with the associated mRNA during protein synthesis remains particularly ambiguous. This study utilizes a chemical nuclease, 1, 10-o-phenanthroline-copper, to localize regions of 16S rRNA proximal to the decoding region under conditions in which tRNA does not readily associate with the 30S subunit (inactive conformation), and under conditions which optimize tRNA binding (active conformation). By covalently attaching 1,10-phenanthroline-copper to a DNA oligomer complementary to nucleotides in the decoding region (1396-1403), we have determined that nucleotides 923-929, 1391-1396, and 1190-1192 are within approximately 15 A of the nucleotide base-paired to nucleotide 1403 in inactive subunits, but in active subunits only cleavages (1404-1405) immediately proximal to the 5' end of the hybridized probe remain. These results provide evidence for dynamic movement in the 30S ribosomal subunit, reported for the first time using a targeted chemical nuclease.     

Reading frame switch caused by base-pair formation between the 3'' end of 16S rRNA and the mRNA during elongation of protein synthesis in Escherichia coli.

Watson-Crick base pairing is shown to occur between the mRNA and nucleotides near the 3' end of 16S rRNA during the elongation phase of protein synthesis in Escherichia coli. This base-pairing is similar to the mRNA-rRNA interaction formed during initiation of protein synthesis between the Shine and Dalgarno (S-D) nucleotides of ribosome binding sites and their complements in the 1540-1535 region of 16S rRNA. mRNA-rRNA hybrid formation during elongation had been postulated to explain the dependence of an efficient ribosomal frameshift on S-D nucleotides precisely spaced 5' on the mRNA from the frameshift site. Here we show that disruption of the postulated base pairs by single nucleotide substitutions, either in the S-D sequence required for shifting or in nucleotide 1538 of 16S rRNA, decrease the amount of shifting, and that this defect is corrected by restoring complementary base pairing. This result implies that the 3' end of 16S rRNA scans the mRNA very close to the decoding sites during elongation.     

Structural aspects of RbfA action during small ribosomal subunit assembly

Ribosome binding factor A (RbfA) is a bacterial cold shock response protein, required for an efficient processing of the 5' end of the 16S ribosomal RNA (rRNA) during assembly of the small (30S) ribosomal subunit. Here we present a crystal structure of Thermus thermophilus (Tth) RbfA and a three-dimensional cryo-electron microscopic (EM) map of the Tth 30S*RbfA complex. RbfA binds to the 30S subunit in a position overlapping the binding sites of the A and P site tRNAs, and RbfA's functionally important C terminus extends toward the 5' end of the 16S rRNA. In the presence of RbfA, a portion of the 16S rRNA encompassing helix 44, which is known to be directly involved in mRNA decoding and tRNA binding, is displaced. These results shed light on the role played by RbfA during maturation of the 30S subunit, and also indicate how RbfA provides cells with a translational advantage under conditions of cold shock.     

An additional ribosome-binding site on mRNA of highly expressed genes and a bifunctional site on the colicin fragment of 16S rRNA from Escherichia coli: important determinants of the efficiency of translation-initiation.

For various genes of E. coli, three regions (-55 to -1; -35 to -1; -21 to -1) 5' to AUG codon on mRNA were searched for sites of interaction with colicin fragment of 16S rRNA. The detailed sequence comparison points out that apart from Shine-Dalgarno base pairing, an additional ribosome-binding site, a subsequence of 5'-UGAUCC-3' invariably exists in mRNA for highly expressed genes. Poorly expressed genes appear to be controlled by only Shine-Dalgarno base pairing. The analysis indicates that in the initiator region, the -55 to -1 region contains the signal which decides the efficiency of the translation-initiation. The site on 16S rRNA, 5'-GGAUCA-3' at position 1529, that can base pair to the above site, has a recognition site on 23S rRNA at position 2390. In the light of the conserved nature and accessibility of these sites, it is proposed that the site on 16S rRNA plays a bifunctional role--initially it binds to mRNA from highly expressed genes to form a stable 30S initiation complex, and upon association with 50S subunit it exchanges base pairing with 23S rRNA, thus leaving the site on mRNA free.     

The evolutionarily conserved protein Las1 is required for pre-rRNA processing at both ends of ITS2

Ribosome synthesis entails the formation of mature rRNAs from long precursor molecules, following a complex pre-rRNA processing pathway. Why the generation of mature rRNA ends is so complicated is unclear. Nor is it understood how pre-rRNA processing is coordinated at distant sites on pre-rRNA molecules. Here we characterized, in budding yeast and human cells, the evolutionarily conserved protein Las1. We found that, in both species, Las1 is required to process ITS2, which separates the 5.8S and 25S/28S rRNAs. In yeast, Las1 is required for pre-rRNA processing at both ends of ITS2. It is required for Rrp6-dependent formation of the 5.8S rRNA 3' end and for Rat1-dependent formation of the 25S rRNA 5' end. We further show that the Rat1-Rai1 5'-3' exoribonuclease (exoRNase) complex functionally connects processing at both ends of the 5.8S rRNA. We suggest that pre-rRNA processing is coordinated at both ends of 5.8S rRNA and both ends of ITS2, which are brought together by pre-rRNA folding, by an RNA processing complex. Consistently, we note the conspicuous presence of ~7- or 8-nucleotide extensions on both ends of 5.8S rRNA precursors and at the 5' end of pre-25S RNAs suggestive of a protected spacer fragment of similar length.     

Interaction of Era with the 30S ribosomal subunit implications for 30S subunit assembly

Era (E. coliRas-like protein) is a highly conserved and essential GTPase in bacteria. It binds to the 16S ribosomal RNA (rRNA) of the small (30S) ribosomal subunit, and its depletion leads to accumulation of an unprocessed precursor of the 16S rRNA. We have obtained a three-dimensional cryo-electron microscopic map of the Thermus thermophilus 30S-Era complex. Era binds in the cleft between the head and platform of the 30S subunit and locks the subunit in a conformation that is not favorable for association with the large (50S) ribosomal subunit. The RNA binding KH motif present within the C-terminal domain of Era interacts with the conserved nucleotides in the 3' region of the 16S rRNA. Furthermore, Era makes contact with several assembly elements of the 30S subunit. These observations suggest a direct involvement of Era in the assembly and maturation of the 30S subunit.