Involvement of ribosomal protein L7/L12 in control of translational accuracy

Immunization with a combination of recombinant Brucella abortus proteins induces T helper immune response and confers protection against wild-type challenge in BALB/c mice

Protective efficiency of a combination of four recombinant Brucella abortus (B. abortus) proteins, namely, ribosomal protein L7/L12, outer membrane protein (OMP) 22, OMP25 and OMP31, was evaluated as a combined subunit vaccine (CSV) against B. abortus infection in RAW 264.7 cell line and murine model. Four proteins were cloned, expressed and purified, and their immunocompetence was analysed. BALB/c mice were immunized subcutaneously with single subunit vaccines (SSVs) or CSV. Cellular and humoral immune responses were determined by ELISA. Results of immunoreactivity showed that these four recombinant proteins reacted with Brucella‐positive serum individually but not with Brucella‐negative serum. A massive production of IFN‐γ and IL‐2 but low degree of IL‐10 was observed in mice immunized with SSVs or CSV. In addition, the titres of IgG2a were heightened compared with IgG1 in SSV‐ or CSV‐immunized mice, which indicated that SSVs and CSV induced a typical T‐helper‐1‐dominated immune response in vivo. Further investigation of the CSV showed a superior protective effect in mice against brucellosis. The protection level induced by CSV was significantly higher than that induced by SSVs, which was not significantly different compared with a group immunized with RB51. Collectively, these antigens of Brucella could be potential candidates to develop subunit vaccines, and the CSV used in this study could be a potential candidate therapy for the prevention of brucellosis.

Immunization With a Combination of Four Recombinant Brucella abortus Proteins Omp16, Omp19, Omp28, and L7/L12 Induces T Helper 1 Immune Response Against Virulent B. abortus 544 Infection in BALB/c Mice

Protective efficiency of a combination of four recombinant Brucella abortus (B. abortus) proteins, namely outer membrane protein (Omp) 16, Omp19, Omp28, and 50S ribosomal protein L7/L12 was evaluated as a combined subunit vaccine (CSV) against B. abortus infection in RAW 264.7 cell line and murine model. The immunoreactivity of these four recombinant proteins as well as pCold-TF vector reacted with Brucella-positive serum individually, but not with Brucella-negative serum by immunoblotting assay. CSV-treated RAW 264.7 cells significantly induced production of IFN-γ and IL-12 while decreased IL-10 production at the late stage of infection compared to PBS-treated control cells. In addition, the enhancement of nitric oxide production together with cytokines secretion profile in CSV-treated cells proved that CSV notably activated bactericidal mechanisms in macrophages. Consistently, mice immunized with CSV strongly elicited production of pro-inflammatory cytokines TNF-α, IL-6 and MCP-1 compared to PBS control group. Moreover, the concentration of IFN-γ was >IL-10 and titers of IgG2a were also heightened compared to IgG1 in CSV-immunized mice which suggest that CSV induced predominantly T helper 1 T cell. These results suggest that the CSV used in the present study is a potential candidate as a preventive therapy against brucellosis.

Acetylation of translation machinery affected protein translation in E. coli

Reversible lysine acetylation (RLA) of translation machinery components, such as ribosomal proteins (RPs) and translation factors (TFs), was identified in many microorganisms, while knowledge of its function and effect on translation remains limited. Herein, we show that translation machinery is regulated by acetylation. Using the cell-free translation system of E. coli, we found that AcP-driven acetylation significantly reduced the relative translation rate, and deacetylation partially restored the translation activity. Hyperacetylation caused by intracellular AcP accumulation or carbon/nitrogen fluctuation (carbon overflow or nitrogen limitation) modulated protein translation in vivo. These results uncovered a critical role of acetylation in translation regulation and indicated that carbon/nitrogen imbalance induced acetylation of ribosome in E. coli and dynamically affected translation rate via a global, uniform manner. KEY POINTS: • Acetylation of translation machinery directly regulated global translation. • K618 of EF-G, K411, and K464 of S1 are the key points influencing translation rate. • Carbon/nitrogen imbalance triggers AcP-dependent acetylation.

Alterations in the ribosomal protein bL12 of E. coli affecting the initiation, elongation and termination of protein synthesis

In bacteria, ribosomal protein bL12 forms the prominent stalk structure on the ribosome and binds to multiple, distinct translational GTPase factors during the sequential steps of translation. Using a genetic selection in E. coli for altered readthrough of UGA stop codons, we have isolated seven different mutations affecting the C-terminal domain of the protein that forms the interaction surface with translation factors. Analysis of these altered proteins, along with four additional alterations previously shown to affect IF2-ribosome interactions, indicates that multiple steps of translation are affected, consistent with bL12's interaction with multiple factors. Surprisingly, deletion of the release factor GTPase, RF3, has relatively little effect on bL12-promoted stop codon readthrough, suggesting that other steps in termination are also influenced by bL12.

Fail-safe genetic codes designed to intrinsically contain engineered organisms

One challenge in engineering organisms is taking responsibility for their behavior over many generations. Spontaneous mutations arising before or during use can impact heterologous genetic functions, disrupt system integration, or change organism phenotype. Here, we propose restructuring the genetic code itself such that point mutations in protein-coding sequences are selected against. Synthetic genetic systems so-encoded should fail more safely in response to most spontaneous mutations. We designed fail-safe codes and simulated their expected effects on the evolution of so-encoded proteins. We predict fail-safe codes supporting expression of 20 or 15 amino acids could slow protein evolution to ∼30% or 0% the rate of standard-encoded proteins, respectively. We also designed quadruplet-codon codes that should ensure all single point mutations in protein-coding sequences are selected against while maintaining expression of 20 or more amino acids. We demonstrate experimentally that a reduced set of 21 tRNAs is capable of expressing a protein encoded by only 20 sense codons, whereas a standard 64-codon encoding is not expressed. Our work suggests that biological systems using rationally depleted but otherwise natural translation systems should evolve more slowly and that such hypoevolvable organisms may be less likely to invade new niches or outcompete native populations.

Investigation of Structure of the Ribosomal L12/P Stalk

This review contains recent data on the structure of the functionally important ribosomal domain, L12/P stalk, of the large ribosomal subunit. It is the most mobile site of the ribosome; it has been found in ribosomes of all living cells, and it is involved in the interaction between ribosomes and translation factors. The difference between the structures of the ribosomal proteins forming this protuberance (despite their general resemblance) determines the specificity of interaction between eukaryotic and prokaryotic ribosomes and the respective protein factors of translation. In this review, works on the structures of ribosomal proteins forming the L12/P-stalk in bacteria, archaea, and eukaryotes and data on structural aspects of interactions between these proteins and rRNA are described in detail.

Alterations in ribosomal protein L19 that decrease the fidelity of translation

Ribosomal protein L19 is an essential ribosomal protein and is a component of bridge B8, one of the protein-RNA bridges linking the large and small ribosomal subunits. Bridge B8 also contributes to the accuracy of translation by affecting GTPase activation by ribosome-bound aminoacyl tRNA-EF-Tu•GTP ternary complexes. Previous work has identified a limited number of accuracy-altering alterations in protein L19 of Salmonella enterica and Thermus thermophilus. Here, we have targeted the Escherichia coli rplS gene encoding L19 for mutagenesis and have screened for mutants with altered levels of miscoding. We have recovered 14 distinct L19 mutants, all of which promote increased stop codon readthrough, but do not have major effects on subunit association or cell growth. Examination of the E. coli 70S ribosome structure indicates that the amino acid substitutions cluster in three distinct regions of L19 and thereby potentially affect its interactions with L14 and 16S rRNA.

A novel fluorescent reporter system for monitoring and identifying RNase III activity and its target RNAs

Bacteriophage vectors for achieving single-copy gene expression linked to a colorigenic reporter assay have been used successfully for genetic screening applications. However, the limited number of cloning sites in these vectors, combined with the requirement for lac- strains and the time- and/or media-dependence of the chemical-based colorimetric reaction, have limited the range of applications for these vectors. An alternative approach using a fluorescent reporter gene such as green fluorescent protein (GFP) or GFP derivatives could overcome some of these technical issues and facilitate real-time monitoring of promoter and/or protein activity. Here, we report the development of a novel translational bacteriophage fusion vector encoding enhanced GFP (eGFP) that can be incorporated into the chromosome as a single-copy gene. We identified a Bacillus promoter (BP) that is stably expressed in Escherichia coli and drives ~6-fold more expression of eGFP than the T7 promoter in the absence of inducer. Incorporating this BP and RNase III target signals into a single system enabled clear detection of the absence or downregulation of RNase III activity in vivo, thereby establishing a system for screening and identifying novel RNase III targets in a matter of days. An RNase III target signal identified in this manner was confirmed by post-transcriptional analysis. We anticipate that this novel translational fusion vector will be used extensively to study activity of both interesting RNases and related complex or to identify or validate targets of RNases that are otherwise difficult to study due to their sensitivity to environmental stresses and/or autoregulatory processes.

Bacterial ribosome requires multiple L12 dimers for efficient initiation and elongation of protein synthesis involving IF2 and EF-G

The ribosomal stalk in bacteria is composed of four or six copies of L12 proteins arranged in dimers that bind to the adjacent sites on protein L10, spanning 10 amino acids each from the L10 C-terminus. To study why multiple L12 dimers are required on the ribosome, we created a chromosomally engineered Escherichia coli strain, JE105, in which the peripheral L12 dimer binding site was deleted. Thus JE105 harbors ribosomes with only a single L12 dimer. Compared to MG1655, the parental strain with two L12 dimers, JE105 showed significant growth defect suggesting suboptimal function of the ribosomes with one L12 dimer. When tested in a cell-free reconstituted transcription–translation assay the synthesis of a full-length protein, firefly luciferase, was notably slower with JE105 70S ribosomes and 50S subunits. Further, in vitro analysis by fast kinetics revealed that single L12 dimer ribosomes from JE105 are defective in two major steps of translation, namely initiation and elongation involving translational GTPases IF2 and EF-G. Varying number of L12 dimers on the ribosome can be a mechanism in bacteria for modulating the rate of translation in response to growth condition.

Characterization of Streptococcus salivarius growth and maintenance in artificial saliva

AIMS

To help gain a better understanding of factors influencing the establishment within the oral cavity of Streptococcus salivarius K12, a commensal oral bacterium, we characterized its behaviour in artificial saliva.

METHODS AND RESULTS

Streptococcus salivarius K12 was grown in artificial saliva complemented with a representative meal, under oral pH and temperature conditions. Exponential growth phase was characterized by a high specific growth rate (2.8 h(-1)). During maintenance phase, an uncoupling between growth and lactic acid production occurred, which allowed maintaining viability (95%), intracellular pH (6.6) and membrane polarisation (95%), and thus proton motive force. However, in late stationary phase, viability (64%) and vitality were degraded as a result of lower synthesis of energetic and glycogen-related proteins as compared to a richer medium.

CONCLUSIONS

Streptococcus salivarius was able to rapidly grow in complemented artificial saliva. Nevertheless, a degradation of its physiological state was observed in late-stationary phase.

SIGNIFICANCE AND IMPACT OF THE STUDY

This work demonstrates, for the first time, that artificial saliva was a convenient medium that permitted Strep. salivarius to grow in oral conditions (physico-chemical environment, addition of meals) but not to maintain cellular viability and vitality in starvation conditions.

Human ribosomal protein L13a is dispensable for canonical ribosome function but indispensable for efficient rRNA methylation

Previously, we demonstrated that treatment of monocytic cells with IFN-gamma causes release of ribosomal protein L13a from the 60S ribosome and subsequent translational silencing of Ceruloplasmin (Cp) mRNA. Here, evidence using cultured cells demonstrates that Cp mRNA silencing is dependent on L13a and that L13a-deficient ribosomes are competent for global translational activity. Human monocytic U937 cells were stably transfected with two different shRNA sequences for L13a and clonally selected for more than 98% abrogation of total L13a expression. Metabolic labeling of these cells showed rescue of Cp translation from the IFN-gamma mediated translational silencing activity. Depletion of L13a caused significant reduction of methylation of ribosomal RNA and of cap-independent translation mediated by Internal Ribosome Entry Site (IRES) elements derived from p27, p53, and SNAT2 mRNAs. However, no significant differences in the ribosomal RNA processing, polysome formation, global translational activity, translational fidelity, and cell proliferation were observed between L13a-deficient and wild-type control cells. These results support the notion that ribosome can serve as a depot for releasable translation-regulatory factors unrelated to its basal polypeptide synthetic function. Unlike mammalian cells, the L13a homolog in yeast is indispensable for growth. Thus, L13a may have evolved from an essential ribosomal protein in lower eukaryotes to having a role as a dispensable extra-ribosomal function in higher eukaryotes.

Compensatory evolution reveals functional interactions between ribosomal proteins S12, L14 and L19

Certain mutations in S12, a ribosomal protein involved in translation elongation rate and translation accuracy, confer resistance to the aminoglycoside streptomycin. Previously we showed in Salmonella typhimurium that the fitness cost, i.e. reduced growth rate, due to the amino acid substitution K42N in S12 could be compensated by at least 35 different mutations located in the ribosomal proteins S4, S5 and L19. Here, we have characterized in vivo the fitness, translation speed and translation accuracy of four different L19 mutants. When separated from the resistance mutation located in S12, the three different compensatory amino acid substitutions in L19 at position 40 (Q40H, Q40L and Q40R) caused a decrease in fitness while the G104A change had no effect on bacterial growth. The rate of protein synthesis was unaffected or increased by the mutations at position 40 and the level of read-through of a UGA nonsense codon was increased in vivo, indicating a loss of translational accuracy. The mutations in L19 increased sensitivity to aminoglycosides active at the A-site, further indicating a perturbation of the decoding step. These phenotypes are similar to those of the classical S4 and S5 ram (ribosomal ambiguity) mutants. By evolving low-fitness L19 mutants by serial passage, we showed that the fitness cost conferred by the L19 mutations could be compensated by additional mutations in the ribosomal protein L19 itself, in S12 and in L14, a protein located close to L19. Our results reveal a novel functional role for the 50 S ribosomal protein L19 during protein synthesis, supporting published structural data suggesting that the interaction of L14 and L19 with 16 S rRNA could influence function of the 30 S subunit. Moreover, our study demonstrates how compensatory fitness-evolution can be used to discover new molecular functions of ribosomal proteins.

Control of phosphate release from elongation factor G by ribosomal protein L7/12

Ribosomal protein L7/12 is crucial for the function of elongation factor G (EF-G) on the ribosome. Here, we report the localization of a site in the C-terminal domain (CTD) of L7/12 that is critical for the interaction with EF-G. Single conserved surface amino acids were replaced in the CTD of L7/12. Whereas mutations in helices 5 and 6 had no effect, replacements of V66, I69, K70, and R73 in helix 4 increased the Michaelis constant (KM) of EF-G.GTP for the ribosome, suggesting an involvement of these residues in EF-G binding. The mutations did not appreciably affect rapid single-round GTP hydrolysis and had no effect on tRNA translocation on the ribosome. In contrast, the release of inorganic phosphate (Pi) from ribosome-bound EF-G.GDP.Pi was strongly inhibited and became rate-limiting for the turnover of EF-G. The control of Pi release by interactions between EF-G and L7/12 appears to be important for maintaining the conformational coupling between EF-G and the ribosome for translocation and for timing the dissociation of the factor from the ribosome.

Structural insights into translational fidelity

The underlying basis for the accuracy of protein synthesis has been the subject of over four decades of investigation. Recent biochemical and structural data make it possible to understand at least in outline the structural basis for tRNA selection, in which codon recognition by cognate tRNA results in the hydrolysis of GTP by EF-Tu over 75 A away. The ribosome recognizes the geometry of codon-anticodon base pairing at the first two positions but monitors the third, or wobble position, less stringently. Part of the additional binding energy of cognate tRNA is used to induce conformational changes in the ribosome that stabilize a transition state for GTP hydrolysis by EF-Tu and subsequently result in accelerated accommodation of tRNA into the peptidyl transferase center. The transition state for GTP hydrolysis is characterized, among other things, by a distorted tRNA. This picture explains a large body of data on the effect of antibiotics and mutations on translational fidelity. However, many fundamental questions remain, such as the mechanism of activation of GTP hydrolysis by EF-Tu, and the relationship between decoding and frameshifting.

Discrimination between defects in elongation fidelity and termination efficiency provides mechanistic insights into translational readthrough

The suppression of stop codons (termed translational readthrough) can be caused by a decreased accuracy of translation elongation or a reduced efficiency of translation termination. In previous studies, the inability to determine the extent to which each of these distinct processes contributes to a readthrough phenotype has limited our ability to evaluate how defects in the translational machinery influence the overall termination process. Here, we describe the combined use of misincorporation and readthrough reporter systems to determine which of these mechanisms contributes to translational readthrough in Saccharomyces cerevisiae. The misincorporation reporter system was generated by introducing a series of near-cognate mutations into functionally important residues in the firefly luciferase gene. These constructs allowed us to monitor the incidence of elongation errors by monitoring the level of firefly luciferase activity from a mutant allele inactivated by a single missense mutation. In this system, an increase in luciferase activity should reflect an increased level of misincorporation of the wild-type amino acid that provides an estimate of the overall fidelity of translation elongation. Surprisingly, we found that growth in the presence of paromomycin stimulated luciferase activity for only a small subset of the mutant proteins examined. This suggests that the ability of this aminoglycoside to induce elongation errors is limited to a subset of near-cognate mismatches. We also found that a similar bias in near-cognate misreading could be induced by the expression of a mutant form of ribosomal protein (r-protein) S9B or by depletion of r-protein L12. We used this misincorporation reporter in conjunction with a readthrough reporter system to show that alterations at different regions of the ribosome influence elongation fidelity and termination efficiency to different extents.

Interaction of helix D of elongation factor Tu with helices 4 and 5 of protein L7/12 on the ribosome

Elongation factor Tu (EF-Tu) promotes binding of aminoacyl-tRNA to the A site of the ribosome. Here, we report the effects of mutations in helix D of EF-Tu and in the C-terminal domain of L7/12 on the kinetics of A-site binding. Reaction rates were measured by stopped-flow and quench-flow techniques. The rates of A-site binding were decreased by mutations at positions 144, 145, 148, and 152 in helix D of EF-Tu as well as at positions 65, 66, 69, 70, 73, and 84 in helices 4 and 5 of L7/12. The effect was due primarily to the lower association rate constant of ternary complex binding to the ribosome. These results suggest that helix D of EF-Tu is involved in an initial transient contact with helices 4 and 5 of L7/12 that promotes ternary complex binding to the ribosome. By analogy to the interaction of helix D of EF-Tu with the N-terminal domain of EF-Ts, the contact area is likely to consist of a hydrophobic patch flanked by two salt-bridges.

Construction of an in vivo nonsense readthrough assay system and functional analysis of ribosomal proteins S12, S4, and S5 in Bacillus subtilis

To investigate the function of ribosomal proteins and translational factors in Bacillus subtilis, we developed an in vivo assay system to measure the level of nonsense readthrough by utilizing the LacZ-LacI system. Using the in vivo nonsense readthrough assay system which we developed, together with an in vitro poly(U)-directed cell-free translation assay system, we compared the processibility and translational accuracy of mutant ribosomes with those of the wild-type ribosome. Like Escherichia coli mutants, most S12 mutants exhibited lower frequencies of both UGA readthrough and missense error; the only exception was a mutant (in which Lys-56 was changed to Arg) which exhibited a threefold-higher frequency of readthrough than the wild-type strain. We also isolated several ribosomal ambiguity (ram) mutants from an S12 mutant. These ram mutants and the S12 mutant mentioned above (in which Lys-56 was changed to Arg) exhibited higher UGA readthrough levels. Thus, the mutation which altered Lys-56 to Arg resulted in a ram phenotype in B. subtilis. The efficacy of our in vivo nonsense readthrough assay system was demonstrated in our investigation of the function of ribosomal proteins and translational factors.

Growth phase dependent stop codon readthrough and shift of translation reading frame in Escherichia coli

Nonsense codon readthrough and changed translational reading frame were measured in different growth phases in E. coli. The strains used carry plasmid constructs with a translation assay reporter gene. This reporter gene contains an internal stop codon or a run of U-residues. Termination or frameshifting give rise to stable proteins that can be physically quantified on gels along with the complete protein products. Readthrough of the stop codon UGA by a nearcognate tRNA is several fold higher in active growth than in late exponential phase. In early exponential phase, about 7% of -1 frameshift at a U9 slippery sequence is detectable; upon entry to stationary phase this frameshifting increases to about 40% followed by a decrease in stationary phase. A similar increase is observed in the case of +1 reading frameshift at the U9 sequence, which increases from 13% in early exponential growth phase up to 38% at the beginning of stationary phase followed by a decrease. Thus, the levels of both stop codon readthrough and frameshifting are growth phase dependent, though not in an identical fashion.

Accumulation of a mRNA decay intermediate by ribosomal pausing at a stop codon

A RNA fragment which is protected from degradation by ribosome pausing at a stop codon has been identified in growing Escherichia coli. The fragment is 261 nt long and corresponds to the 3'-end of the mRNA expressed from a semi-synthetic model gene. The 5'-end of the RNA fragment, denoted rpRNA (ribosomal pause RNA), is located 13 bases upstream of the stop codon. In vivo decay of the complete mRNA and accumulation of rpRNA are dependent on the nature of the stop codon and its codon context. The data indicate that the rpRNA fragment arises from interrupted decay of the S3A'mRNA in the 5'-->m3'direction, in connection with a ribosomal pause at the stop codon. RF-2 decoding of UGA is less efficient than RF-1 decoding of UAG in identical codon contexts, as judged from rpRNA steady-state levels. The half-life of UGA-containing rpRNAs is at least 5 min, indicating that ribosomal pausing can be a major factor in stabilising downstream regions of messenger RNAs.

The accuracy center of a eukaryotic ribosome

Mutations in yeast ribosomal proteins and ribosomal RNAs have been shown to affect translational fidelity. These mutations include: proteins homologous to Escherichia coli's S4, S5, and S12; a eukaryote specific ribosomal protein; yeast ribosomal rRNA alterations at positions corresponding to 517, 912, and 1054 in 16S E. coli rRNA and to 2658 in the sarcin-ricin domain of 23S E. coli rRNA. Overall there appears to be a remarkable conservation of the accuracy center throughout evolution.

Alterations in ribosomal protein RPS28 can diversely affect translational accuracy in Saccharomyces cerevisiae

Three small-subunit ribosomal proteins shown to influence translational accuracy in Saccharomyces cerevisiae are conserved in structure and function with their procaryotic counterparts. One of these, encoded by RPS28A and RPS28B (RPS28), is comparable to bacterial S12. The others, encoded by sup44 (RPS4) or, sup46 and YS11A (RPS13), are homologues of procaryotic S5 and S4, respectively. In Escherichia coli, certain alterations in S12 cause hyperaccurate translation or antibiotic resistance that can be counteracted by other changes in S5 or S4 that reduce translational accuracy. Using site-directed and random mutagenesis, we show that different changes in RPS28 can have diametrical influences on translational accuracy or antibiotic sensitivity in yeast. Certain substitutions in the amino-terminal portion of the protein, which is diverged from the procaryotic homologues, cause varying levels of nonsense suppression or antibiotic sensitivity. Other alterations, found in the more conserved carboxyl-terminal portion, counteract SUP44- or SUP46-associated antibiotic sensitivity, mimicking E. coli results. Although mutations in these different parts of RPS28 have opposite affects on translational accuracy or antibiotic sensitivity, additive phenotypes can be observed when opposing mutations are combined in the same protein.

Eukaryotic acidic phosphoproteins interact with the ribosome through their amino-terminal domain

Variable-size fragments of the four yeast acidic ribosomal protein genes rpYP1 alpha, rpYP1 beta, rpYP2 alpha and rpYP2 beta were fused to the LacZ gene in the vector series YEp356-358. The constructs were used to transform wild-type Saccharomyces cerevisiae and several gene-disrupted strains lacking different acidic ribosomal protein genes. The distribution of the chimeric proteins between the cytoplasm and the ribosomes, tested as beta-galactosidase activity, was estimated. Hybrid proteins containing around a minimum of 65-75 amino acids from their amino-terminal domain are able to bind to the ribosomes in the presence of the complete native proteins. Hybrid proteins containing no more than 36 amino terminal amino acids bind to the ribosomes in the absence of a competing native protein. The fused YP1-beta-galactosidase proteins are also able to form a complex with the native YP2 type proteins, promoting their binding to the ribosome. The stability of the hybrid polypeptides seems to be inversely proportional to the size of their P protein fragment. These results indicate that only the amino-terminal domain of the eukaryotic P proteins is needed for the P1-P2 complex formation required for interaction with the ribosome. The highly conserved P protein carboxyl end is not implicated in the binding to the particles and is exposed to the medium.

Mutation of a highly conserved base in the yeast mitochondrial 21S rRNA restricts ribosomal frameshifting

A mutation shown to cause resistance to chloramphenicol in Saccharomyces cerevisiae was mapped to the central loop in domain V of the yeast mitochondrial 21S rRNA. The mutant 21S rRNA has a base pair exchange from U2677 (corresponding to U2504 in Escherichia coli) to C2677, which significantly reduces rightward frameshifting at a UU UUU UCC A site in a +1 U mutant. There is evidence to suggest that this reduction also applies to leftward frameshifting at the same site in a -1 U mutant. The mutation did not increase the rate of misreading of a number of mitochondrial missense, nonsense or frameshift (of both signs) mutations, and did not adversely affect the synthesis of wild-type mitochondrial gene products. It is suggested here that ribosomes bearing either the C2677 mutation or its wild-type allele may behave identically during normal decoding and only differ at sites where a ribosomal stall, by permitting non-standard decoding, differentially affects the normal interaction of tRNAs with the chloramphenicol resistant domain V. Chloramphenicol-resistant mutations mapping at two other sites in domain V are described. These mutations had no effect on frameshifting.

Mutations in the peptidyl transferase region of E. coli 23S rRNA affecting translational accuracy

We have produced mutations in a cloned Escherichia coli 23S rRNA gene at positions G2252 and G2253. These sites are protected in chemical footprinting studies by the 3' terminal CCA of P site-bound tRNA. Three possible base changes were introduced at each position and the mutations produced a range of effects on growth rate and translational accuracy. Growth of cells bearing mutations at 2252 was severely compromised while the only mutation at 2253 causing a marked reduction in growth rate was a G to C transversion. Most of the mutations affected translational accuracy, causing increased readthrough of UGA, UAG and UAA nonsense mutations as well as +1 and -1 frameshifting in a lacZ reporter gene in vivo. C2253 was shown to act as a suppressor of a UGA nonsense mutation at codon 243 of the trpA gene. The C2253 mutation was also found not to interact with alleles of rpsL coding for restrictive forms of ribosomal protein S12. These results provide further evidence that nucleotides localized to the P site in the 50S ribosomal subunit influence the accuracy of decoding in the ribosomal A site.

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 degrees 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 m6(2)A, 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.

Single-base mutations at position 2661 of Escherichia coli 23S rRNA increase efficiency of translational proofreading

Two single-base substitutions were constructed in the 2660 loop of Escherichia coli 23S rRNA (G2661-->C or U) and were introduced into the rrnB operon cloned in plasmid pKK3535. Ribosomes were isolated from bacteria transformed with the mutated plasmids and assayed in vitro in a poly(U)-directed system for their response to the misreading effect of streptomycin, neomycin, and gentamicin, three aminoglycoside antibiotics known to impair the proofreading control of translational accuracy. Both mutations decreased the stimulation of misreading by these drugs, but neither interfered with their binding to the ribosome. The response of the mutant ribosomes to these drugs suggests that the 2660 loop, which belongs to the elongation factor Tu binding site, is involved in the proofreading step of the accuracy control. In vivo, both mutations reduced read-through of nonsense codons and frameshifting, which can also be related to the increased efficiency in proofreading control which they confer to ribosomes.

The length of the interdomain region of the L7/L12 protein is important for its function

Several mutated L7/L12 proteins with changed interdomain regions were obtained. The results showed that the flexible region comprising the 39-52 amino acid residues is functionally important. Its length, but not its amino acid composition, is crucial for the function.

The yeast omnipotent suppressor SUP46 encodes a ribosomal protein which is a functional and structural homolog of the Escherichia coli S4 ram protein

The accurate synthesis of proteins is crucial to the existence of a cell. In yeast, several genes that affect the fidelity of translation have been identified (e.g., omnipotent suppressors, antisuppressors and allosuppressors). We have found that the dominant omnipotent suppressor SUP46 encodes the yeast ribosomal protein S13. S13 is encoded by two similar genes, but only the sup46 copy of the gene is able to fully complement the recessive phenotypes of SUP46 mutations. Both copies of the S13 genes contain introns. Unlike the introns of other duplicated ribosomal protein genes which are highly diverged, the duplicated S13 genes have two nearly identical DNA sequences of 25 and 31 bp in length within their introns. The SUP46 protein has significant homology to the S4 ribosomal protein in prokaryotic-type ribosomes. S4 is encoded by one of the ram (ribosomal ambiguity) genes in Escherichia coli which are the functional equivalent of omnipotent suppressors in yeast. Thus, SUP46 and S4 demonstrate functional as well as sequence conservation between prokaryotic and eukaryotic ribosomal proteins. SUP46 and S4 are most similar in their central amino acid sequences. Interestingly, the alterations resulting from the SUP46 mutations and the segment of the S4 protein involved in binding to the 16S rRNA are within this most conserved region.

A ribosomal ambiguity mutation in the 530 loop of E. coli 16S rRNA

A series of base substitution and deletion mutations were constructed in the highly conserved 530 stem and loop region of E. coli 16S rRNA involved in binding of tRNA to the ribosomal A site. Base substitution and deletion of G517 produced significant effects on cell growth rate and translational fidelity, permitting readthrough of UGA, UAG and UAA stop codons as well as stimulating +1 and -1 frameshifting in vivo. By contrast, mutations at position 534 had little or no effect on growth rate or translational fidelity. The results demonstrate the importance of G517 in maintaining translational fidelity but do not support a base pairing interaction between G517 and U534.

Novel mutants of 23S RNA: characterization of functional properties

Single point mutations corresponding to the positions G2505 and G2583 have been constructed in the gene encoding E.coli 23S rRNA. These mutations were linked to the second mutation A1067 to T, known to confer resistance to thiostrepton (1). Mutant ribosomes were analyzed in vitro for their ability to direct poly(U) dependent translation, their missence error frequency and in addition their sensitivity to peptidyltransferase inhibitors. It was evident that the mutated ribosomes had an altered dependence on [Mg2+] and an increased sensitivity to chloramphenicol during poly(U) directed poly(Phe) synthesis. In a transpeptidation assay mutated ribosomes were as sensitive to chloramphenicol as wild-type ribosomes. However, the mutant ribosomes exhibited an increased sensitivity to lincomycin. An increase in translational accuracy was attributed to the mutations at the position 2583: accuracy increased in the order G less than A less than U less than C.

Nuclear-encoded chloroplast ribosomal protein L12 of Nicotiana tabacum: characterization of mature protein and isolation and sequence analysis of cDNA clones encoding its cytoplasmic precursor

Poly(A)+ mRNA isolated from Nicotiana tabacum (cv. Petite Havana) leaves was used to prepare a cDNA library in the expression vector lambda gt11. Recombinant phage containing cDNAs coding for chloroplast ribosomal protein L12 were identified and sequenced. Mature tobacco L12 protein has 44% amino acid identity with ribosomal protein L7/L12 of Escherichia coli. The longest L12 cDNA (733 nucleotides) codes for a 13,823 molecular weight polypeptide with a transit peptide of 53 amino acids and a mature protein of 133 amino acids. The transit peptide and mature protein share 43% and 79% amino acid identity, respectively, with corresponding regions of spinach chloroplast ribosomal protein L12. The predicted amino terminus of the mature protein was confirmed by partial sequence analysis of HPLC-purified tobacco chloroplast ribosomal protein L12. A single L12 mRNA of about 0.8 kb was detected by hybridization of L12 cDNA to poly(A)+ and total leaf RNA. Hybridization patterns of restriction fragments of tobacco genomic DNA probed with the L12 cDNA suggested the existence of more than one gene for ribosomal protein L12. Characterization of a second cDNA with an identical L12 coding sequence but a different 3'-noncoding sequence provided evidence that at least two L12 genes are expressed in tobacco.

Amino acid misincorporation during high-level expression of mouse epidermal growth factor in Escherichia coli

To determine whether the high-level expression of foreign proteins in Escherichia coli can lead to frequent translational errors, we analyzed amino acid misincorporation in mouse epidermal growth factor (mEGF) produced as a TrpE fusion protein. The mEGF DNA does not encode phenylalanine and determining the phenylalanine content of the purified protein will measure missense errors. Using this approach, we found an error frequency of about 1 in 40 for codons differing by a single base from those for phenylalanine. This is at least ten times higher than the error rate found for normal E. coli protein synthesis and may be due to limiting supply of charged tRNAs and GTP, brought about by the high-level production of the heterologous protein. The unexpectedly high error rate has implications for the clinical use of E. coli-derived therapeutic proteins.

Sequence and functional similarity between a yeast ribosomal protein and the Escherichia coli S5 ram protein

The accurate and efficient translation of proteins is of fundamental importance to both bacteria and higher organisms. Most of our knowledge about the control of translational fidelity comes from studies of Escherichia coli. In particular, ram (ribosomal ambiguity) mutations in structural genes of E. coli ribosomal proteins S4 and S5 have been shown to increase translational error frequencies. We describe the first sequence of a ribosomal protein gene that affects translational ambiguity in a eucaryote. We show that the yeast omnipotent suppressor SUP44 encodes the yeast ribosomal protein S4. The gene exists as a single copy without an intron. The SUP44 protein is 26% identical (54% similar) to the well-characterized E. coli S5 ram protein. SUP44 is also 59% identical (78% similar) to mouse protein LLrep3, whose function was previously unknown (D.L. Heller, K.M. Gianda, and L. Leinwand, Mol. Cell. Biol. 8:2797-2803, 1988). The SUP44 suppressor mutation occurs near a region of the protein that corresponds to the known positions of alterations in E. coli S5 ram mutations. This is the first ribosomal protein whose function and sequence have been shown to be conserved between procaryotes and eucaryotes.

Sequence and functional similarity between a yeast ribosomal protein and the Escherichia coli S5 ram protein

The accurate and efficient translation of proteins is of fundamental importance to both bacteria and higher organisms. Most of our knowledge about the control of translational fidelity comes from studies of Escherichia coli. In particular, ram (ribosomal ambiguity) mutations in structural genes of E. coli ribosomal proteins S4 and S5 have been shown to increase translational error frequencies. We describe the first sequence of a ribosomal protein gene that affects translational ambiguity in a eucaryote. We show that the yeast omnipotent suppressor SUP44 encodes the yeast ribosomal protein S4. The gene exists as a single copy without an intron. The SUP44 protein is 26% identical (54% similar) to the well-characterized E. coli S5 ram protein. SUP44 is also 59% identical (78% similar) to mouse protein LLrep3, whose function was previously unknown (D.L. Heller, K.M. Gianda, and L. Leinwand, Mol. Cell. Biol. 8:2797-2803, 1988). The SUP44 suppressor mutation occurs near a region of the protein that corresponds to the known positions of alterations in E. coli S5 ram mutations. This is the first ribosomal protein whose function and sequence have been shown to be conserved between procaryotes and eucaryotes.

Ribosomal protein L30 is dispensable in the yeast Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, L30 is one of many ribosomal proteins that is encoded by two functional genes. We have cloned and sequenced RPL30B, which shows strong homology to RPL30A. Use of mRNA as a template for a polymerase chain reaction demonstrated that RPL30B contains an intron in its 5' untranslated region. This intron has an unusual 5' splice site, C/GUAUGU. The genomic copies of RPL30A and RPL30B were disrupted by homologous recombination. Growth rates, primer extension, and two-dimensional ribosomal protein analyses of these disruption mutants suggested that RPL30A is responsible for the majority of L30 production. Surprisingly, meiosis of a diploid strain carrying one disrupted RPL30A and one disrupted RPL30B yielded four viable spores. Ribosomes from haploid cells carrying both disrupted genes had no detectable L30, yet such cells grew with a doubling time only 30% longer than that of wild-type cells. Furthermore, depletion of L30 did not alter the ratio of 60S to 40S ribosomal subunits, suggesting that there is no serious effect on the assembly of 60S subunits. Polysome profiles, however, suggest that the absence of L30 leads to the formation of stalled translation initiation complexes.

Ribosomal protein L30 is dispensable in the yeast Saccharomyces cerevisiae

In the yeast Saccharomyces cerevisiae, L30 is one of many ribosomal proteins that is encoded by two functional genes. We have cloned and sequenced RPL30B, which shows strong homology to RPL30A. Use of mRNA as a template for a polymerase chain reaction demonstrated that RPL30B contains an intron in its 5' untranslated region. This intron has an unusual 5' splice site, C/GUAUGU. The genomic copies of RPL30A and RPL30B were disrupted by homologous recombination. Growth rates, primer extension, and two-dimensional ribosomal protein analyses of these disruption mutants suggested that RPL30A is responsible for the majority of L30 production. Surprisingly, meiosis of a diploid strain carrying one disrupted RPL30A and one disrupted RPL30B yielded four viable spores. Ribosomes from haploid cells carrying both disrupted genes had no detectable L30, yet such cells grew with a doubling time only 30% longer than that of wild-type cells. Furthermore, depletion of L30 did not alter the ratio of 60S to 40S ribosomal subunits, suggesting that there is no serious effect on the assembly of 60S subunits. Polysome profiles, however, suggest that the absence of L30 leads to the formation of stalled translation initiation complexes.

A gene family for acidic ribosomal proteins in Schizosaccharomyces pombe: two essential and two nonessential genes

We have cloned the genes for small acidic ribosomal proteins (A-proteins) of the fission yeast Schizosaccharomyces pombe. S. pombe contains four transcribed genes for small A-proteins per haploid genome, as is the case for Saccharomyces cerevisiae. In contrast, multicellular eucaryotes contain two transcribed genes per haploid genome. The four proteins of S. pombe, besides sharing a high overall similarity, form two couples of nearly identical sequences. Their corresponding genes have a very conserved structure and are transcribed to a similar level. Surprisingly, of each couple of genes coding for nearly identical proteins, one is essential for cell growth, whereas the other is not. We suggest that the unequal importance of the four small A-proteins for cell survival is related to their physical organization in 60S ribosomal subunits.

A gene family for acidic ribosomal proteins in Schizosaccharomyces pombe: two essential and two nonessential genes

We have cloned the genes for small acidic ribosomal proteins (A-proteins) of the fission yeast Schizosaccharomyces pombe. S. pombe contains four transcribed genes for small A-proteins per haploid genome, as is the case for Saccharomyces cerevisiae. In contrast, multicellular eucaryotes contain two transcribed genes per haploid genome. The four proteins of S. pombe, besides sharing a high overall similarity, form two couples of nearly identical sequences. Their corresponding genes have a very conserved structure and are transcribed to a similar level. Surprisingly, of each couple of genes coding for nearly identical proteins, one is essential for cell growth, whereas the other is not. We suggest that the unequal importance of the four small A-proteins for cell survival is related to their physical organization in 60S ribosomal subunits.

Substitution of an invariant nucleotide at the base of the highly conserved '530-loop' of 15S rRNA causes suppression of yeast mitochondrial ochre mutations

We have determined the nucleotide sequence alteration in the 15S rRNA gene of a Saccharomyces cerevisiae strain carrying the previously described mitochondrial ochre suppressor, MSUI. The suppressor contains an A residue at position 633 of the yeast mitochondrial sequence, in place of the wild-type G. This position, located in the highly conserved region forming the stem of the '530-loop', corresponds to G517 of the Escherichia coli 16S rRNA and is occupied by G in all other known small rRNA sequences. This finding strongly supports the previous conclusions of others that the 530-loop region plays an important role in enhancing translational accuracy.

Ribosomal protein L7/L12 has a helix-turn-helix motif similar to that found in DNA-binding regulatory proteins

Inspection of the structure of the C-terminal domain of ribosomal protein L7/L12 (1) reveals a helix-turn-helix motif similar to the one found in many DNA-binding regulatory proteins (2-5). The 19 alpha-carbon atoms of the L7/L12 alpha-helices superimpose on the DNA binding helices of CAP and cro with root-mean-square distances between corresponding alpha carbons of 1.45 and 1.55 A, respectively. These helices in L7/L12 are within a patch of highly conserved residues on the surface of L7/L12 whose role is as yet uncertain. We raise the possibility that they may constitute a binding site for nucleic acids, most probably RNA. Consistent with this hypothesis are calculations of the electrostatic charge potential surrounding the protein, which show a region of positive potential centered on the first of these helices.

Suppression of the Escherichia coli rpoH opal mutation by ribosomes lacking S15 protein

Several suppressors (suhD) that can specifically suppress the temperature-sensitive opal rpoH11 mutation of Escherichia coli K-12 have been isolated and characterized. Unlike the parental rpoH11 mutant deficient in the heat shock response, the temperature-resistant pseudorevertants carrying suhD were capable of synthesizing sigma 32 and exhibiting partial induction of heat shock proteins. These strains were also cold sensitive and unable to grow at 25 degrees C. Genetic mapping and complementation studies permitted us to localize suhD near rpsO (69 min), the structural gene for ribosomal protein S15. Ribosomes and polyribosomes prepared from suhD cells contained a reduced level (ca. 10%) of S15 relative to that of the wild type. Cloning and sequencing of suhD revealed that an IS10-like element had been inserted at the attenuator-terminator region immediately downstream of the rpsO coding region. The rpsO mRNA level in the suhD strain was also reduced to about 10% that of wild type. Apparently, ribosomes lacking S15 can actively participate in protein synthesis and suppress the rpoH11 opal (UGA) mutation at high temperature but cannot sustain cell growth at low temperature.

Mutant 16S ribosomal RNA: a codon-specific translational suppressor

We have isolated an unusual codon-specific translational suppressor in Escherichia coli. The suppressor resulted from a spontaneous mutation in a chromosomal gene during a selection for suppressors of the auxotrophic nonsense mutation trpA(UGA211). The suppressor allows readthrough of UGA mutations at two positions in trpA and at two sites in bacteriophage T4. It does not, however, suppress amber (UAG) or ochre (UAA) mutations that were tested in both genomes, some of which were at the same positions as the suppressible UGA mutations. The suppressor also does not allow mistranslation of the UGA-related trpA missense mutations UGG at positions 211 and 234, AGA at 211 and 234, CGA at 211, or UGU and UGC at 234. The suppressor mutation was mapped by genetic procedures to position 89 on the E. coli genetic map. Localization of the suppressor mutation to rrnB was achieved by cloning it in the low-copy-number plasmid pEJM007 by in vivo recombination from the chromosome. Recloning in bacteriophage M13 and subsequent DNA sequence analysis allowed the identification of the suppressor mutation as a deletion of the cytidylic acid residue at nucleotide position 1054 of the 16S ribosomal RNA. The mutant EcoRI-Xba I fragment from the suppressor gene was recloned, from M13, in an otherwise wild-type rrnB in the plasmid pEJM007, and UGA suppression was examined. The UGA-suppressing activity of the reconstructed suppressor-containing pEJM007 was indistinguishable from that of the original recombinant suppressor-containing plasmid. This result demonstrates that the C1054 deletion in 16S rRNA is both necessary and sufficient for UGA suppression. The existence of this mutant suggests an important role for rRNA in codon recognition, at least for accurate polypeptide chain termination.

Functional interactions in vivo between suppressor tRNA and mutationally altered ribosomal protein S4

Ribosomal mutants (rpsD) which are associated with a generally increased translational ambiguity were investigated for their effects in vivo on individual tRNA species using suppressor tRNAs as models. It was found that nonsense suppression is either increased, unaffected or decreased depending on the codon context and the rpsD allele involved as well as the nature of the suppressor tRNA. Missense suppression of AGA and AGG by glyT(SuAGA/G) tRNA as well as UGG by glyT(SuUGG-8) tRNA is unaffected whereas suppression of UGG by glyT(SuUGA/G) or glyV(SuUGA/G) tRNA is decreased in the presence of an rpsD mutation. The effects on suppressor tRNA are thus not correlated with the ribosomal ambiguity (Ram) phenotype of the rpsD mutants used in this study. It is suggested that the mutationally altered ribosomes are changed in functional interactions with the suppressor tRNA itself rather than with the competing translational release factor(s) or cognate aminoacyl tRNA. The structure of suppressor tRNA, particularly the anticodon loop, and the suppressed codon as well as the codon context determine the allele specific functional interactions with these ribosomal mutations.

Mutant EF-Tu increases missense error in vitro

We have studied the consequences of mutational alteration in the structure of EF-Tu on the missense errors and proofreading activity of bacterial ribosomes in vitro. Our data show that the EF-Tu Bo mutant form of EF-Tu (van der Meide et al. 1983a) is inactive in polypeptide synthesis on the ribosome, even though it binds aminoacyl-tRNA. A second mutant form, EF-Tu Ar (van der Meide et al. 1983a), is active in polypeptide synthesis but supports a much higher messense incorporation with either leucine isoacceptor 2 or leucine isoacceptor 4 in the in vitro system. Further analysis of the kinetic basis of this enhanced missense frequency revealed that the mutation responsible for the alteration in EF-Tu Ar increases the errors at both the proofreading step and the initial selection. In this respect the effect of this particular mutation is similar to the mode of action of the antibiotic kanamycin (Jelenc and Kurland 1984).