Functional analysis of the residues C770 and G771 of E. coli 16S rRNA implicated in forming the intersubunit bridge B2c of the ribosome

Structural analyses have shown that nucleotides at the positions 770 and 771 of Escherichia coli 16S rRNA are implicated in forming one of highly conserved intersubunit bridges of the ribosome, B2c. To examine a functional role of these residues, base substitutions were introduced at these positions and mutant ribosomes were analyzed for their protein synthesis ability using a specialized ribosome system. The results showed requirement of a pyrimidine at the position 770 for ribosome function regardless of the nucleotide identity at the position 771. Sucrose gradient profiles of ribosomes revealed that the loss of protein-synthesis ability of mutant ribosome bearing a base substitution from C to G at the position 770 stems from its inability to form 70S ribosomes. These findings indicate involvement of nucleotide at the position 770, not 771, in ribosomal subunit association and provide a useful rRNA mutation that can be used as a target to investigate the physical interaction between 16S and 23S rRNA.     

The involvement of base 1054 in 16S rRNA for UGA stop codon dependent translational termination.

The deletion of the highly conserved cytidine nucleotide at position 1054 in E. coli 16S rRNA has been characterized to confer an UGA stop codon specific suppression activity which suggested a functional participation of small subunit rRNA in translational termination. Based on this structure-function correlation we constructed the three point mutations at site 1054, changing the wild-type C residue to an A, G or U base. The mutations were expressed from a complete plasmid encoded rRNA operon (rrnB) using a conditional expression system with the lambda PL-promoter. All three altered 16S rRNA molecules were expressed and incorporated into 70S ribosomal particles. Structural analysis of the protein and 16S rRNA moieties of the mutant ribosomes showed no differences when compared to wild-type particles. The phenotypic analysis revealed that only the 1054G base change led to a significantly reduced generation time of transformed cells, which could be correlated with the inability of the mutant ribosomes to specifically stop at UGA stop codons in vivo. The response towards UAA and UAG termination codons was not altered. Furthermore, in vitro RF-2 termination factor binding experiments indicated that the association behaviour of mutant ribosomes was not changed, enforcing the view that the UGA stop codon suppression is a direct consequence of the rRNA mutation. Taken together, these results argue for a direct participation of that 16S rRNA motif in UGA dependent translational termination and furthermore, suggest that termination factor binding and stop codon recognition are two separate steps of the termination event.     

A mutation at the universally conserved position 529 in Escherichia coli 16S rRNA creates a functional but highly error prone ribosome.

A base substitution of G to U was constructed at position 529 in Escherichia coli 16S rRNA. The U529 mutant ribosomes were functional and present on polysomes but were highly error prone and caused a progressive loss of cell viability. They displayed elevated levels of readthrough of stop codons and frameshifting, and an increase in thermal sensitivity of beta-galactosidase, suggestive of missense errors. These results demonstrate that the university conserved G529 is involved in tRNA selection at the A site during protein synthesis.     

Mutants with base changes at the 3'-end of the 16S RNA from Escherichia coli. Construction, expression and functional analysis

The functionally important 3' domain of the ribosomal 16S RNA was altered by in vitro DNA manipulations of a plasmid-encoded 16S RNA gene. By in vitro DNA manipulations two double mutants were constructed in which C1399 was converted to A and G1401 was changed to either U or C and a single point mutant was made wherein G1416 was changed to U. Only one of the mutated rRNA genes could be cloned in a plasmid under the control of the natural rrnB promoters (U1416) whereas all three mutations were cloned in a plasmid under the control of the lambda PL promoter. In a strain coding for the temperature-sensitive lambda repressor cI857 the mutant RNAs could be expressed conditionally. We could show that all three mutant rRNAs were efficiently incorporated into 30S ribosomes. However, all three mutants inhibited the formation of stable 70S particles to various degrees. The amounts of mutated rRNAs were quantified by primer extension analysis which enabled us to assess the proportion of the mutated ribosomes which are actively engaged in in vivo protein biosynthesis. While ribosomes carrying the U1416 mutation in the 16S RNA were active in vivo a strong selection against ribosomes with the A1399/U1401 mutation in the 16S RNA from the polysome fraction is apparent. Ribosomes with 16S RNA bearing the A1399/C1401 mutation did not show a measurable protein biosynthesis activity in vivo. The growth rate of cells harbouring the different mutations reflected the in vivo translation capacities of the mutant ribosomes. The results underline the importance of the highly conserved nucleotides in the 3' domain of the 16S RNA for ribosomal function.     

A single base change at 726 in 16S rRNA radically alters the pattern of proteins synthesized in vivo.

A single base change in 16S rRNA (C-726 to G) was constructed by site-directed mutagenesis and cloned into the multicopy plasmid pKK3535 (generating pKK726G) which contains the complete rrnB operon from Escherichia coli. The mutant 16S rRNA was found predominantly in the 30S subunit fraction but was present in the 70S ribosomes. Protein analyses of the free 30S subunits revealed a decrease in the levels of ribosomal proteins S2 and S21 while the composition of the 70S ribosomes was as the wild-type. Transformants of pKK726G were temperature sensitive for growth, although the mutant ribosomes themselves were translationally active in vivo at 37 and 42 degrees C. Two-dimensional gel electrophoresis of the proteins translated in vivo revealed an altered protein profile which included novel proteins, changes in the levels of normal proteins, and the presence of heat shock proteins (HSPs) at 30 degrees C. Inactivation of the host encoded wild-type ribosomes coincided with a significant decrease in the synthesis of the HSPs. We therefore believe the induction of the HSPs to be a secondary response by the cells to the presence of the abnormal proteins.     

Mutations in the Escherichia coli 23S rRNA increase the rate of peptidyl-tRNA dissociation from the ribosome

We have studied in vivo the phenotypes of 23S rRNA mutations G2582A, G2582U, G2583C, and U2584C, which are located at the A site of Escherichia coli 50S ribosomal subunit. All mutant rRNAs incorporated into 50S ribosomal subunits. Upon sucrose gradient fraction of cell lysates, 23S rRNAs mutated at G2582 to A and G2583 to C accumulated in the 50S and 70S fractions and were under-represented in the polysome fraction. Induction of 23S rRNAs mutated at G2582 and G2583 lead to a drastic reduction in cell growth. In addition, mutations G2582A and G2583C reduced to one-third the total protein synthesis but not the RNA synthesis. Finally, we show that 23S rRNA mutations G2582A, G2582U, and G2583C cause a significant increase in peptidyl-tRNA drop-off from ribosomes, thereby reducing translational processivity. The results clearly show that tRNA-23S rRNA interaction has an essential role in maintaining the processivity of translation.     

A single base substitution in 16S ribosomal RNA suppresses streptomycin dependence and increases the frequency of translational errors

A C to U substitution at position 1469 of 16S ribosomal RNA (rRNA) from Escherichia coli suppresses streptomycin dependence and causes increased translational error frequencies. Strains containing the rpsL252 or StrM287 streptomycin-dependent alleles are able to grow in the absence of streptomycin when transformed with plasmids containing the U1469 mutation in 16S rRNA. Ribosomes containing wild-type proteins and U1469 mutant 16S rRNA misincorporate leucine in vitro at elevated levels, comparable to that of some typical S4 ram ribosomes. These results provide additional support for the participation of 16S rRNA in maintaining translational accuracy.     

A single base mutation at position 2661 in E. coli 23S ribosomal RNA affects the binding of ternary complex to the ribosome.

A single base substitution mutation from guanine to cytosine was constructed at position 2661 of Escherichia coli 23S rRNA and cloned into the rrnB operon of the multi-copy plasmid pKK3535. The mutant plasmid was transformed into E.coli to determine the effect of the mutation on cell growth as well as the structural and functional properties of the mutant ribosomes in vivo and in vitro. The results show that the mutant ribosomes have a slower elongation rate and an altered affinity for EF-Tu-tRNA-GTP ternary complex. This supports previous findings which indicated that position 2661 is part of a region of 23S rRNA that forms a recognition site for binding of the ternary complex in the ribosomal A site. Combinations of the 2661 mutation with various mutations in ribosomal protein S12 also demonstrate that elements of both ribosomal subunits work in concert to form this binding site.     

Mutations in the Escherichia coli23S rRNA Increase the Rate of Peptidyl-tRNA Dissociation from the Ribosome

We have studied in vivothe phenotypes of 23S rRNA mutations G2582A, G2582U, G2583C, and U2584C, which are located at the A site of Escherichia coli50S ribosomal subunit. All mutant rRNAs incorporated into 50S ribosomal subunits. Upon sucrose gradient fractionation of cell lysates, 23S rRNAs mutated at G2582 to A and G2583 to C accumulated in the 50S and 70S fractions and were underrepresented in the polysome fraction. Induction of 23S rRNAs mutated at G2582 and G2583 lead to a drastic reduction in cell growth. In addition, mutations G2582A and G2583C reduced to one-third the total protein synthesis but not the RNA synthesis. Finally, we show that 23S rRNA mutations G2582A, G2582U, and G2583C cause a significant increase in peptidyl-tRNA drop-off from ribosomes, thereby reducing translational processivity. The results clearly show that tRNA–23S rRNA interaction has an essential role in maintaining the processivity of translation.     

Base 2661 in Escherichia coli 23S rRNA influences the binding of elongation factor Tu during protein synthesis in vivo.

The binding of the EF-Tu.GTP.aminoacyl-tRNA ternary complex (EF, elongation factor) to the ribosome is known to be strengthened by a 2661G-to-C mutation in 23S ribosomal RNA, whereas the binding to normal ribosomes is weakened if the factor is in an appropriate mutant form (Aa). In this report we describe the mutual effects by the 2661C alteration in 23S rRNA and EF-Tu(Aa) on bacterial viability and translation efficiency in strains with normal or mutationally altered ribosomes. The rrnB(2661C) allele on a multicopy plasmid was introduced by transformation into Escherichia coli K-12 strains, harbouring either the wild-type or the mutant gene (tufA) for EF-Tu as well as normal or mutant ribosomal protein S12 (rpsL). Together with wild-type EF-Tu, the 2661C mutant ribosomes decreased the translation elongation rate in a rpsL+ strain or a non-restrictive rpsL224 strain. This reduction was not seen in strains which harbored EF-Tu(Aa) instead of EF-Tu(As) (As, wild-type form). Nonsense codon suppression by tyrT(Su3) suppressor tRNA was reduced by 2661C in a rpsL224 strain in the presence of EF-Tu(As) but not in the presence of EF-Tu(Aa). The lethal effect obtained by the combination of 2661C and a restrictive ribosomal protein S12 mutation (rpsL282) disappeared if EF-Tu(As) was replaced by EF-Tu(Aa) in the strain. In such a viable strain, 2661C had no effect on either the translation elongation rate or nonsense codon suppression. Our data suggest that the G base at position 2661 in 23S rRNA is important for binding of EF-Tu during protein synthesis in vivo. The interaction between this base and EF-Tu is strongly influenced by the structure of ribosomal protein S12.     

Formation of the central pseudoknot in 16S rRNA is essential for initiation of translation.

The postulated central pseudoknot formed by regions 9-13/21-25 and 17-19/916-918 of 16S rRNA of Escherichia coli is phylogenetically conserved in prokaryotic as well eukaryotic species. This pseudoknot is located at the center of the secondary structure of the 16S rRNA and connects the three major domains of this molecule. We have introduced mutations into this pseudoknot by changing the base-paired residues C18 and G917, and the effect of such mutations on the ribosomal activity was studied in vivo, using a 'specialized' ribosome system. As compared with ribosomes having the wild-type pseudoknot, the translational activity of ribosomes containing an A, G or U residue at position 18 was dramatically reduced, while the activity of mutant ribosomes having complementary bases at positions 18 and 917 was at the wild-type level. The reduced translational activity of those mutants that are incapable of forming a pseudoknot was caused by their inability to form 70S ribosomal complexes. These results demonstrate that the potential formation of a central pseudoknot in 16S rRNA with any base-paired residues at positions 18 and 917 is essential to complete the initiation process.     

Modulation of 16S rRNA function by ribosomal protein S12

Ribosomal protein S12 is a critical component of the decoding center of the 30S ribosomal subunit and is involved in both tRNA selection and the response to streptomycin. We have investigated the interplay between S12 and some of the surrounding 16S rRNA residues by examining the phenotypes of double-mutant ribosomes in strains of Escherichia coli carrying deletions in all chromosomal rrn operons and expressing total rRNA from a single plasmid-borne rrn operon. We show that the combination of S12 and otherwise benign mutations at positions C1409-G1491 in 16S rRNA severely compromises cell growth while the level and range of aminoglycoside resistances conferred by the G1491U/C substitutions is markedly increased by a mutant S12 protein. The G1491U/C mutations in addition confer resistance to the unrelated antibiotic, capreomycin. S12 also interacts with the 912 region of 16S rRNA. Genetic selection of suppressors of streptomycin dependence caused by mutations at proline 90 in S12 yielded a C912U substitution in 16S rRNA. The C912U mutation on its own confers resistance to streptomycin and restricts miscoding, properties that distinguish it from a majority of the previously described error-promoting ram mutants that also reverse streptomycin dependence.     

Transfer RNA shields specific nucleotides in 16S ribosomal RNA from attack by chemical probes

Binding of tRNAPhe to ribosomes shields a set of highly conserved nucleotides in 16S rRNA from attack by a combination of structure-specific chemical probes. The bases can be classified according to whether or not their protection is strictly poly(U)-dependent (G529, G530, U531, A1408, A1492, and A1493) or poly(U)-independent (A532, G693, A794, C795, G926, 2mG966, G1338, A1339, U1381, C1399, C1400, and G1401). A third class (A790, G791, and A909) is shielded by both tRNA and 50S ribosomal subunits. Similar results are obtained when the protecting ligand is tRNAPhe E. Coli, tRNAPhe yeast, tRNAPhe E. Coli lacking its 3' terminal CA, or the 15 nucleotide anticodon stem-loop fragment of tRNAPhe yeast. Implications for structural correlates of the classic ribosomal A- and P-sites and for the possible involvement of 16S rRNA in translational proofreading are discussed.     

Ribosome activity and modification of 16S RNA are influenced by deletion of ribosomal protein S20

A spontaneous mutant of Escherichia coli K-12 was isolated that shows an increased misreading ability of all three nonsense codons together with an inability to grow at 42° C. It is demonstrated that the mutation is a deletion of the gene rpsT, coding for ribosomal protein S20. The loss of this protein not only influences the decoding properties of the ribosome; the modification pattern of 16S ribosomal RNA is also changed. This leads to a deficiency in the ability of the mutant to associate its 30S subunits with 50S subunits to form 70S ribosomes. It is suggested that two modified bases, m⁵C and m⁶₂A, are directly or indirectly essential for association of subunits to functional ribosomes in the rpsT mutant strain. Two other modifications were also studied; m²G which is not affected at all and m³U which is undermodified in both active and inactive subunits and, therefore, not involved in subunit association.     

Structural changes in the 530 loop of Escherichia coli 16S rRNA in mutants with impaired translational fidelity.

The higher order structure of the functionally important 530 loop in Escherichia coli 16S rRNA was studied in mutants with single base changes at position 517, which significantly impair translational fidelity. The 530 loop has been proposed to interact with the EF-Tu-GTP-aatRNA ternary complex during decoding. The reactivity at G530, U531 and A532 to the chemical probes kethoxal, CMCT and DMS respectively was increased in the mutant 16S rRNA compared with the wild-type, suggesting a more open 530 loop structure in the mutant ribosomes. This was supported by oligonucleotide binding experiments in which probes complementary to positions 520-526 and 527-533, but not control probes, showed increased binding to the 517C mutant 70S ribosomes compared with the non-mutant control. Furthermore, enzymatic digestion of 70S ribosomes with RNase T1, specific for single-stranded RNA, substantially cleaved both wild-type and mutant rRNAs between G524 and C525, two of the nucleotides involved in the 530 loop pseudoknot. This site was also cleaved in the 517C mutant, but not wild-type rRNA, by RNase V1. Such a result is still consistent with a more open 530 loop structure in the mutant ribosomes, since RNase V1 can cut at appropriately stacked single-stranded regions of RNA. Together these data indicate that the 517C mutant rRNA has a rather extensively unfolded 530 loop structure. Less extensive structural changes were found in mutants 517A and 517U, which caused less misreading. A correlation between the structural changes in the 530 loop and impaired translational accuracy is proposed.     

Site-directed mutagenesis of Escherichia coli 23 S ribosomal RNA at position 1067 within the GTP hydrolysis centre

Site-directed mutagenesis has been used to change, specifically, residue 1067 within 23 S ribosomal RNA of Escherichia coli. This nucleoside (adenosine in the wild-type sequence) lies within the GTPase centre of the larger ribosomal subunit and is normally the target for the methylase enzyme responsible for resistance to the antibiotic thiostrepton. The performance of the altered ribosomes was not impaired in cell-free protein synthesis nor in GTP hydrolysis assays (although the 3 mutant strains grew somewhat more slowly than wild-type) but their responses to thiostrepton did vary. Thus, ribosomes containing the A to C or A to U substitution at residue 1067 of 23 S rRNA were highly resistant to the drug, whereas the A to G substitution resulted in much lesser impairment of thiostrepton binding and the ribosomes remained substantially sensitive to the antibiotic. These data reinforce the hypothesis that thiostrepton binds to 23 S rRNA at a site that includes residue A1067. They also exclude any possibility that the insensitivity of eukaryotic ribosomes to the drug might be due solely to the substitution of G at the equivalent position within eukaryotic rRNA.     

Substrate binding analysis of the 23S rRNA methyltransferase RrmJ

The 23S rRNA methyltransferase RrmJ (FtsJ) is responsible for the 2'-O methylation of the universally conserved U2552 in the A loop of 23S rRNA. This 23S rRNA modification appears to be critical for ribosome stability, because the absence of functional RrmJ causes the cellular accumulation of the individual ribosomal subunits at the expense of the functional 70S ribosomes. To gain insight into the mechanism of substrate recognition for RrmJ, we performed extensive site-directed mutagenesis of the residues conserved in RrmJ and characterized the mutant proteins both in vivo and in vitro. We identified a positively charged, highly conserved ridge in RrmJ that appears to play a significant role in 23S rRNA binding and methylation. We provide a structural model of how the A loop of the 23S rRNA binds to RrmJ. Based on these modeling studies and the structure of the 50S ribosome, we propose a two-step model where the A loop undocks from the tightly packed 50S ribosomal subunit, allowing RrmJ to gain access to the substrate nucleotide U2552, and where U2552 undergoes base flipping, allowing the enzyme to methylate the 2'-O position of the ribose.     

Oligonucleotide directed mutagenesis of Escherichia coli 5S ribosomal RNA: construction of mutant and structural analysis.

The ribosomal 5S RNA gene from the rrnB operon of E. coli was mutagenised in vitro using a synthetic oligonucleotide hybridised to M13 ssDNA containing that gene. The oligonucleotide corresponded to the 5S RNA sequence positions 34 to 51 and changed the guanosine at position 41 to a cytidine. The DNA containing the desired mutation was identified by dot blot hybridisation and introduced back into the plasmid pKK 3535 which contains the total rrnB operon in pBR 322. Plasmid coded 5S rRNA was selectively labeled with 32p using a modified maxi-cell system, and the replacement of guanosine G41 by cytidine was confirmed by RNA sequencing. The growth of cells containing mutant 5S rRNA was not altered by the base change, and the 5S rRNA was processed and incorporated into 50S ribosomal subunits and 70S ribosomes. The structure of wildtype and mutant 5S rRNA was compared by chemical modification of accessible guanosines with kethoxal and limited enzymatic digestion using RNase T1 and nuclease S1. These results showed that the wildtype and mutant 5S rRNA do not differ significantly in their structure. Furthermore, the formation, interconversion and stability of the two 5S rRNA A- and B-conformers are unchanged.     

Ribosomal RNA identity elements for ricin A-chain recognition and catalysis

Ricin is a cytotoxic protein that inactivates ribosomes by hydrolyzing the N-glycosidic bond between the base and the ribose at position A4324 in eukaryotic 28 S rRNA. The requirements for the recognition by ricin A-chain of this nucleotide and for the catalysis of cleavage were examined using a synthetic oligoribonucleotide that reproduces the sequence and the secondary structure of the RNA domain (a helical stem, a bulged nucleotide, and a 17-member single-stranded loop). The wild-type RNA (35mer) and a number of mutants were transcribed in vitro from synthetic DNA templates with phage T7 RNA polymerase. With the wild-type oligoribonucleotide the ricin A-chain catalyzed reaction has a Km of 13.55 microM and a Kcat of 0.023 min-1. Recognition and catalysis by ricin A-chain has an absolute requirement for A at the position that corresponds to 4324. The helical stem is also essential; however, the number of base-pairs can be reduced from the seven found in 28 S rRNA to three without loss of identity. The nature of these base-pairs can affect catalysis. A change of the second set from one canonical (G.C) to another (U.A) reduces sensitivity to ricin A-chain; whereas, a change of the third pair (U.A----G.C) produces supersensitivity. The bulged nucleotide does not contribute to identification. Hydrolysis is affected by altering the nucleotides in the universal sequence surrounding A4324 or by changing the position in the loop of the tetranucleotide GA(ricin)GA: all of these mutants have a null phenotype. If ribosomes are treated first with alpha-sarcin to cleave the phosphodiester bond at G4325 ricin can still catalyze depurination at A4324. This implies that cleavage by alpha-sarcin at the center of what has been presumed to be a 17 nucleotide single-stranded loop in 28 S rRNA produces ends that are constrained in some way. On the other hand, hydrolysis by alpha-sarcin of the corresponding position in the synthetic oligoribonucleotide prevents recognition by ricin A-chain. The results suggest that the loop has a complex structure, affected by ribosomal proteins, and this bears on the function in protein synthesis of the alpha-sarcin/ricin rRNA domain.