Selection for intragenic suppressors of lethal 23S rRNA mutations in Escherichia coli identifies residues important for ribosome assembly and function

Mutations in several functionally important regions of the 23S rRNA of E. coli increase the levels of frameshifting and readthrough of stop codons. These mutations include U2555A, U2555G, ΔA1916 and U2493C. The mutant rRNAs are lethal when expressed at high levels from a plasmid, in strains also expressing wild type rRNA from chromosomal rrn operons. The lethal phenotype can be suppressed by a range of second-site mutations in 23S rRNA. However, analysis of the functionality of the double mutant rRNAs in heterogeneous ribosome populations shows that in general, the second site mutations do not restore function. Instead, they prevent the assembly, or entry of the mutant 50S subunits into the functioning 70S ribosome and polysome pools, by affecting the competitiveness of the mutant subunits for association with 30S particles. The second-site mutations lie in regions of the 23S rRNA involved in subunit assembly, intersubunit bridge formation and interactions of the ribosome with tRNAs and factors. These second site suppressor mutations thus define functionally important rRNA nucleotides and this approach may be of general use in the functional mapping of large RNAs.     

Mutations in conserved helix 69 of 23S rRNA of Thermus thermophilus that affect capreomycin resistance but not posttranscriptional modifications

Translocation during the elongation phase of protein synthesis involves the relative movement of the 30S and 50S ribosomal subunits. This movement is the target of tuberactinomycin antibiotics. Here, we describe the isolation and characterization of mutants of Thermus thermophilus selected for resistance to the tuberactinomycin antibiotic capreomycin. Two base substitutions, A1913U and mU1915G, and a single base deletion, DeltamU1915, were identified in helix 69 of 23S rRNA, a structural element that forms part of an interribosomal subunit bridge with the decoding center of 16S rRNA, the site of previously reported capreomycin resistance base substitutions. Capreomycin resistance in other bacteria has been shown to result from inactivation of the TlyA methyltransferase which 2'-O methylates C1920 of 23S rRNA. Inactivation of the tlyA gene in T. thermophilus does not affect its sensitivity to capreomycin. Finally, none of the mutations in helix 69 interferes with methylation at C1920 or with pseudouridylation at positions 1911 and 1917. We conclude that the resistance phenotype is a consequence of structural changes introduced by the mutations.     

A single mutation in 16S rRNA that affects mRNA binding and translation-termination.

A single base change in 16S rRNA (C726 to G) has previously been shown to have a dramatic effect on protein synthesis in E. coli (1). This paper more specifically details the effects of the mutation on mRNA binding and translation-termination. The in vitro technique of toeprinting (2) was used to demonstrate that 30S subunits containing the mutation 726G had an altered binding affinity for mRNA by comparison to the wild type. In addition, expression of the mutant ribosomes in vivo resulted in exclusive suppression of the UGA nonsense codon. This effect was supported by in vitro studies that showed the mutant ribosomes to have an altered binding affinity for Release Factor-2.     

Neurospora crassa cytoplasmic ribosomes: cold-sensitive mutant defective in ribosomal ribonucleic acid synthesis.

Experiments were conducted to characterize further the biochemical defects of crib-1 (PJ30201), a coldsensitive mutant strain of Neurospora crassa with a defect in ribosome biosynthesis. The results are as follows. (i) The critical temperature for the expression of the mutant growth and ribosome phenotypes is in the range of 18 to 20 C. (ii) No preferential breakdown of 37S cytoplasmic ribosomal subunits synthesized by crib-1 at 25 C occurs after a shift to 10 C. (iii) Ribosomal subunits synthesized by crib-1 at 25 C function normally in in vivo protein synthesis at 10 C. (iv) Whereas wild type synthesizes both ribosomal subunits in a coordinate manner after either a temperature shift-down (25 to 10 C) of a shift-up (10 to 25 C), noncoordinate synthesis of ribosomal subunits owing to underproduction of 37S subunits occurs in the crib-1 strain immediately after a temperature shift-down. (v) After a shift from 10 to 25 C crib-1 exhibits a 12-h lag before the growth rate and the rate of synthesis of 37S subunits begin to increase significantly. (vi) At 10 C crib-1 synthesizes unequal amounts of 25S and 17S ribosomal ribonucleic acid (rRNA) molecules, resulting from a greatly reduced accumulation of stable 17S rRNA. The mutant phenotypes of crib-1 are proposed to be the result of a defect in rRNA processing.     

Translational fidelity mutations in 18S rRNA affect the catalytic activity of ribosomes and the oxidative balance of yeast cells

The function of mutations rdn1A, rdn1T, and rdn2 in 18S rRNA of Saccharomyces cerevisiae is investigated. The mutations correspond to substitutions C1054A, C1054U in helix 34, and G517A in helix 18 of 16S rRNA in Escherichia coli, respectively, in which the first and third mutations caused nonsense suppression, while C1054U caused no suppression. In yeast, rdn1A caused phenotypic suppression at nonsense codons, whereas rdn1T and rdn2 caused antisuppression. We provide in vitro evidence that, in addition, rdn1A decreases translational accuracy at sense codons as well, by a factor of 8, accompanied by extreme sensitivity to paromomycin, compatible with its error-prone character. Mutations rdn1T andrdn2 exhibit hyperaccuracy and paromomycin resistance. Thus, mutations in conserved rRNA regions may affect the same functions in the various species but in opposite directions. Mutation rdn1A, but not rdn1T or rdn2, affected also the catalytic activity of the ribosome, a 60S subunit activity. The rate of peptide bond formation was reduced to half its normal value, indicating a communication between the two subunits. Moreover, error-prone mutation rdn1A was less susceptible to oxidative modifications than wild type, indicated by decreased lipid peroxidation and nonprotein/protein disulfides, as well as by increased protein thiols. In contrast, hyperaccurate mutations rdn1T and rdn2 displayed increased oxidative stress. Our results suggest that the cells may consume more energy to achieve hyperaccuracy leading to increased oxidative modifications.     

Purification of 30S ribosomal subunit by streptavidin affinity chromatography

Preparation of pure ribosomal subunits carrying lethal mutations is necessary for studying every essential functional region of ribosomal RNA. Affinity purification via a tag, inserted into rRNA proved to be procedure of choice for purification of such ribosomal subunits. Here we describe fast and simple purification method for the 30S ribosomal subunits using affinity chromatography. Streptavidin-binding tag was inserted into functionally neutral helix 33a of the 16 S rRNA from Escherichia coli. Tagged ribosomal subunits were shown to be expressed in E. coli and could be purified. Purified subunits with affinity tag behave similarly to the wild type subunits in association with the 50S subunits, toe-printing and tRNA binding assays. Tagged 30S subunits could support cell growth in the strain lacking wild type 30S subunits and only marginally change the growth rate of bacteria. The presented purification method is thus suitable for further use in purification of 30S subunits carrying any lethal mutations.     

The structure of helix III in Xenopus oocyte 5 S rRNA: an RNA stem containing a two-nucleotide bulge

The solution structure of an oligonucleotide containing the helix III sequence from Xenopus oocyte 5 S rRNA has been determined by NMR spectroscopy. Helix III includes two unpaired adenosine residues, flanked on either side by G:C base-pairs, that are required for binding of ribosomal protein L5. The consensus conformation of helix III in the context provided by this oligonucleotide has the two adenosine residues located in the minor groove and stacked upon the 3' flanking guanosine residue, consistent with biochemical studies of free 5 S rRNA in solution. A distinct break in stacking that occurs between the first adenosine residue of the bulge and the flanking 5' guanosine residue exposes the base of the adenosine residue in the minor groove and the base of the guanosine residue in the major groove. The major groove of the helix is widened at the site of the unpaired nucleotides and the helix is substantially bent; nonetheless, the G:C base-pairs flanking the bulge are intact. The data indicate that there may be conformational heterogeneity centered in the bulge region. The corresponding adenosine residues in the Haloarcula marismortui 50 S ribosomal subunit form a dinucleotide platform, which is quite different from the motif seen in solution. Thus, the conformation of helix III probably changes when 5 S rRNA is incorporated into the ribosome.     

Interaction between the ribosomal subunits: 16S rRNA suppressors of the lethal ΔA1916 mutation in the 23S rRNA of <Emphasis Type="Italic">Escherichia coli</Emphasis>

A1916 in 23S rRNA is located in one of the major intersubunit bridges of the 70S ribosome. Deletion of A1916 disrupts the intersubunit bridge B2a, promotes misreading of the genetic code and is lethal. In a genetic selection for suppressor mutations, two base substitutions in 16S rRNA were recovered that restored viability and also allowed expression of ΔA1916-associated capreomycin resistance. These mutations were G1048A in helix 34 and U1471C in helix 44. Restoration of function is incomplete, however, and the double mutants are slow-growing, defective in subunit association and support high levels of translational errors. In contrast, none of these parameters is affected by the single 16S suppressor mutations. U1471C likely affects another intersubunit contact, bridge B6, suggesting that interactions between different bridges and cross-talk between subunits contributes to ribosomal function.     

Separation of mutant and wild-type ribosomes based on differences in their anti Shine-Dalgarno sequence.

We describe a system to isolate 30S ribosomal subunits which contain targeted mutations in their 16S rRNA. The mutations of interest should be present in so-called specialized 30S subunits which have an anti-Shine-Dalgarno sequence that is altered from 5' ACCUCC to 5' ACACAC. These plasmid-encoded specialized 30S subunits are separated from their chromosomally encoded wild-type counterparts by affinity chromatography that exploits the different Shine-Dalgarno complementarity. An oligonucleotide complementary to the 3' end of wild-type 16S rRNA and attached to a solid phase matrix retains the wild-type 30S subunits. The flow-through of the column contains close to 100% mutant 30S subunits. Toeprinting assays demonstrate that affinity column treatment does not cause significant loss of activity of the specialized particles in initiation complex formation, whereas elongation capacity as determined by poly(Phe) synthesis is only slightly decreased. The method described offers an advantage over total reconstitution from in vitro transcribed mutant 16S rRNA since our 30S subunits contain the naturally occurring base modifications in their 16S rRNA.     

Assembly of 5S ribosomal RNA is required at a specific step of the pre-rRNA processing pathway.

A collection of yeast strains surviving with mutant 5S RNA has been constructed. The mutant strains presented alterations of the nucleolar structure, with less granular component, and a delocalization of the 25S rRNA throughout the nucleoplasm. The 5S RNA mutations affected helix I and resulted in decreased amounts of stable 5S RNA and of the ribosomal 60S subunits. The shortage of 60S subunits was due to a specific defect in the processing of the 27SB precursor RNA that gives rise to the mature 25S and 5.8S rRNA. The processing rate of the 27SB pre-rRNA was specifically delayed, whereas the 27SA and 20S pre-rRNA were processed at a normal rate. The defect was partially corrected by increasing the amount of mutant 5S RNA. We propose that the 5S RNA is recruited by the pre-60S particle and that its recruitment is necessary for the efficient processing of the 27SB RNA precursor. Such a mechanism could ensure that all newly formed mature 60S subunits contain stoichiometric amounts of the three rRNA components.     

Identification of a single base change in ribosomal RNA leading to erythromycin resistance.

The molecular basis of a mutation conferring an erythromycin-resistance phenotype was explored, as an approach to the role of 23 S rRNA in the peptidyl-transferase activity of 50 S ribosomal subunits. Mutagenization of an Escherichia coli strain, which carried the multicopy plasmid pLC7-21 containing the rrnH operon, led to the production of an erythromycin-resistant strain. Plasmid pBFL1 isolated from this mutant was able to transform the sensitive RecA- strain EM4 and to induce a "dissociated" type of antibiotic resistance. Two ribosome populations occurred in EM4/pBFL1: normal particles coded for by the seven rrn chromosomal genes and mutated particles containing rRNA of plasmid origin. The latter particles displayed in vitro lower affinity and susceptibility to erythromycin than wild type particles. The mutation within plasmid pBFL1 was mapped by a multiple primer extension technique. Three synthetic primers were used to sequence the central loop in domain V of 23 S rRNA, leading to identification of a C to U transition at position 2611. This base change was proved to be responsible for the erythromycin-resistance phenotype by the plasmid-plasmid marker rescue technique. A molecular explanation for the rrn mutations leading, respectively, to undissociated and to dissociated types of resistance to the MLSb (macrolide-lincosamide-synergimycin B) group of antibiotics is proposed. These results and some literature data support the notion that rRNA bases involved in antibiotic resistance play a conformational role in the ribosomal binding sites for the MLSb antibiotics.     

Construction and functional analysis of ribosomal 5S RNA from Escherichia coli with single base changes in the ribosomal protein binding sites

The ribosomal 5S RNA gene from E. coli was altered by oligonucleotide-directed mutagenesis at positions A66 and U103. The mutant genes were cloned into an expression vector and selectively transcribed in an UV-sensitive E. coli strain using a modified maxicell system. The mutant 5S RNA genes were found to be transcribed and processed normally. The 5S RNA molecules were assembled into 50S ribosomal subunits. Under in vitro conditions the stability of the mutant 70S ribosomes seemed, however, to be reduced, since they dissociated into their subunits more easily than those of the wild type. The isolated mutated 5S RNAs with base changes in the ribosomal protein binding sites for L18 and L25, together with a point mutant at G41 (G to C), constructed earlier, were tested for their capacity to bind the 5S RNA binding proteins L5, L18 and L25. The following effects were observed: The base change A66 to C within the L18 binding site did not affect the binding of the ribosomal protein L18 but enhanced the stability of the L25-5S RNA complex considerably. The base changes U103 to G and G41 to C slightly reduced the binding of L5 and L25 whereas the binding of L18 to the mutant 5S RNAs was not altered. In addition 70S ribosomes with the single point mutations in their 5S RNAs were tested in their tRNA binding capacity. Mutants containing a C41 in their 5S RNA showed a reduction in the poly(U)-dependent Phe-tRNA binding, whereas the mutations to C66 and G 103 lead to completely inactive ribosomes in the same assay. Based on previous results a spatial model of the 5S RNA molecule is presented which is consistent with the findings reported in this paper.     

Conformational dynamics of a 5S rRNA hairpin domain containing loop D and a single nucleotide bulge

Molecular modeling and molecular dynamics have been employed to study the conformation and flexibility of a 15-nucleotide fragment of the plant 5S rRNA containing loop D and a single uridine bulge. Two different model built initial structures were used: one with the bulge localized inside the helical stem and another with the bulge pointing out from the helix. Several independent 700-ps-long trajectories in aqueous solution with Na(+) conterions were produced for each starting structure. The bulge nucleotide inside the helix stayed in two main conformations, both of which affected the geometry of the stem part opposite the bulge. When the bulge nucleotide was located outside the helix, we found high base mobility and local backbone flexibility. The dynamics of the hydrogen bond network and conformational changes from a direct to a water mediated hydrogen bond in the sheared G-A basepair in the tetraloop was described. Our results correlate with lead ion induced cleavage patterns in 5S rRNA. Sites resistant to nonspecific lead cleavage appeared in all our simulations as the most rigid fragments independent of the localization of the bulge nucleotide.     

Different conformational forms of Escherichia coli and rat liver 5S rRNA revealed by Pb(II)-induced hydrolysis.

Different stable forms of Escherichia coli and rat liver 5S rRNA have been probed by Pb(II)-induced hydrolysis. In the native A forms of 5S rRNA, Pb2+ reveal single-stranded RNA stretches and regions of increased conformational flexibility or distorted by the presence of bulged nucleotides. Hydrolysis of urea/EDTA-treated E. coli 5S rRNA (B form) shows the presence of two strong helical domains; helix A retained from the A form and a helix composed of RNA regions G33-C42 and G79-C88. Other RNA regions resistant to hydrolysis may be involved in alternative base pairing, causing conformational heterogeneity of that form. Pb(II)-induced hydrolysis distinguishes two different forms of rat liver 5S rRNA; the native A form and the form obtained by renaturation of 5S rRNA in the presence of EDTA. Pb(II)-hydrolysis data suggest that both forms are highly structured. In the latter form, the orientation of the bulged C66 is changed with respect to helix B. At the same time, a new helical segment is possibly formed, composed of nucleotides from helix C and loop c on one side and from helix E and loop d' on the other.     

A functional relationship between helix 1 and the 900 tetraloop of 16S ribosomal RNA within the bacterial ribosome

The conserved 900 tetraloop that caps helix 27 of 16S ribosomal RNA (rRNA) interacts with helix 24 of 16S rRNA and also with helix 67 of 23S rRNA, forming the intersubunit bridge B2c, proximal to the decoding center. In previous studies, we investigated how the interaction between the 900 tetraloop and helix 24 participates in subunit association and translational fidelity. In the present study, we investigated whether the 900 tetraloop is involved in other undetected interactions with different regions of the Escherichia coli 16S rRNA. Using a genetic complementation approach, we selected mutations in 16S rRNA that compensate for a 900 tetraloop mutation, A900G, which severely impairs subunit association and translational fidelity. Mutations were randomly introduced in 16S rRNA, using either a mutagenic XL1-Red E. coli strain or an error-prone PCR strategy. Gain-offunction mutations were selected in vivo with a specialized ribosome system. Two mutations, the deletion of U12 and the U12C substitution, were thus independently selected in helix 1 of 16S rRNA. This helix is located in the vicinity of helix 27, but does not directly contact the 900 tetraloop in the crystal structures of the ribosome. Both mutations correct the subunit association and translational fidelity defects caused by the A900G mutation, revealing an unanticipated functional interaction between these two regions of 16S rRNA.     

The central pseudoknot in 16S ribosomal RNA is needed for ribosome stability but is not essential for 30S initiation complex formation.

To examine the function of the central pseudoknot in 16S rRNA, we have studied Escherichia coli 30S subunits with the A18 mutation in this structure element. Previously, this mutation, which changes the central base pair of helix 2, C18--G917, to an A18xG917 mismatch, was shown to inhibit translation in vivo and a defect in initiation was suggested. Here, we find that the mutant 30S particles are impaired in forming 70S tight couples and predominantly accumulate as free 30S subunits. Formation of a 30S initiation complex, as measured by toeprinting, was almost as efficient for mutant 30S subunits, derived from the tight couple fraction, as for the wild-type control. However, the A18 mutation has a profound effect on the overall stability of the subunit. The mutant ribosomes were inactivated by affinity chromatography and high salt treatment, due to easy loss of ribosomal proteins. Accordingly, the particles could be reactivated by partial in vitro reconstitution with 30S ribosomal proteins. Mutant 30S subunits from the free subunit fraction were already inactive upon isolation, but could also be reactivated by reconstitution. Apparently, the inactivity in initiation of these mutant 30S subunits is, at least in part, also due to the lack of essential ribosomal proteins. We conclude that disruption of helix 2 of the central pseudoknot by itself does not affect the formation of a 30S initiation complex. We suggest that the in vivo translational defect of the mutant ribosomes is caused by their inability to form 70S initiation complexes.