Missense substitutions lethal to essential functions of EF-Tu

Trimethylation of Elongation Factor-Tu by the Dual Thermoregulated Methyltransferase EftM Does Not Impact Its Canonical Function in Translation

The Pseudomonas aeruginosa methyltransferase EftM trimethylates elongation factor-Tu (EF-Tu) on lysine 5 to form a post-translational modification important for initial bacterial adherence to host epithelial cells. EftM methyltransferase activity is directly temperature regulated. The protein stability of EftM is tuned with a melting temperature (T_m) around 37 °C such that the enzyme is stable and active at 25 °C, but is completely inactivated by protein unfolding at higher temperatures. This leads to higher observable levels of EF-Tu trimethylation at the lower temperature. Here we report an additional layer of thermoregulation resulting in lower eftM mRNA transcript level at 37 °C compared to 25 °C and show that this regulation occurs at the level of transcription initiation. To begin to define the impact of this system on P. aeruginosa physiology, we demonstrate that EF-Tu is the only observable substrate for EftM. Further, we interrogated the proteome of three different wild-type P. aeruginosa strains, their eftM mutants, and these mutants complemented with eftM and conclude that trimethylation of EF-Tu by EftM does not impact EF-Tu’s canonical function in translation. In addition to furthering our knowledge of this Pseudomonas virulence factor, this study provides an intriguing example of a protein with multiple layers of thermoregulation.

Functional Constraints on Replacing an Essential Gene with Its Ancient and Modern Homologs

Genes encoding proteins that carry out essential informational tasks in the cell, in particular where multiple interaction partners are involved, are less likely to be transferable to a foreign organism. Here, we investigated the constraints on transfer of a gene encoding a highly conserved informational protein, translation elongation factor Tu (EF-Tu), by systematically replacing the endogenous tufA gene in the Escherichia coli genome with its extant and ancestral homologs. The extant homologs represented tuf variants from both near and distant homologous organisms. The ancestral homologs represented phylogenetically resurrected tuf sequences dating from 0.7 to 3.6 billion years ago (bya). Our results demonstrate that all of the foreign tuf genes are transferable to the E. coli genome, provided that an additional copy of the EF-Tu gene, tufB, remains present in the E. coli genome. However, when the tufB gene was removed, only the variants obtained from the gammaproteobacterial family (extant and ancestral) supported growth which demonstrates the limited functional interchangeability of E. coli tuf with its homologs. Relative bacterial fitness correlated with the evolutionary distance of the extant tuf homologs inserted into the E. coli genome. This reduced fitness was associated with reduced levels of EF-Tu and reduced rates of protein synthesis. Increasing the expression of tuf partially ameliorated these fitness costs. In summary, our analysis suggests that the functional conservation of protein activity, the amount of protein expressed, and its network connectivity act to constrain the successful transfer of this essential gene into foreign bacteria.IMPORTANCE Horizontal gene transfer (HGT) is a fundamental driving force in bacterial evolution. However, whether essential genes can be acquired by HGT and whether they can be acquired from distant organisms are very poorly understood. By systematically replacing tuf with ancestral homologs and homologs from distantly related organisms, we investigated the constraints on HGT of a highly conserved gene with multiple interaction partners. The ancestral homologs represented phylogenetically resurrected tuf sequences dating from 0.7 to 3.6 bya. Only variants obtained from the gammaproteobacterial family (extant and ancestral) supported growth, demonstrating the limited functional interchangeability of E. coli tuf with its homologs. Our analysis suggests that the functional conservation of protein activity, the amount of protein expressed, and its network connectivity act to constrain the successful transfer of this essential gene into foreign bacteria.

Reducing ppGpp level rescues an extreme growth defect caused by mutant EF-Tu

Transcription and translation of mRNA's are coordinated processes in bacteria. We have previously shown that a mutant form of EF-Tu (Gln125Arg) in Salmonella Typhimurium with a reduced affinity for aa-tRNA, causes ribosome pausing, resulting in an increased rate of RNase E-mediated mRNA cleavage, causing extremely slow growth, even on rich medium. The slow growth phenotype is reversed by mutations that reduce RNase E activity. Here we asked whether the slow growth phenotype could be reversed by overexpression of a wild-type gene. We identified spoT (encoding ppGpp synthetase/hydrolase) as a gene that partially reversed the slow growth rate when overexpressed. We found that the slow-growing mutant had an abnormally high basal level of ppGpp that was reduced when spoT was overexpressed. Inactivating relA (encoding the ribosome-associated ppGpp synthetase) also reduced ppGpp levels and significantly increased growth rate. Because RelA responds specifically to deacylated tRNA in the ribosomal A-site this suggested that the tuf mutant had an increased level of deacylated tRNA relative to the wild-type. To test this hypothesis we measured the relative acylation levels of 4 families of tRNAs and found that proline isoacceptors were acylated at a lower level in the mutant strain relative to the wild-type. In addition, the level of the proS tRNA synthetase mRNA was significantly lower in the mutant strain. We suggest that an increased level of deacylated tRNA in the mutant strain stimulates RelA-mediated ppGpp production, causing changes in transcription pattern that are inappropriate for rich media conditions, and contributing to slow growth rate. Reducing ppGpp levels, by altering the activity of either SpoT or RelA, removes one cause of the slow growth and reveals the interconnectedness of intracellular regulatory mechanisms.

Mutants of the RNA-processing enzyme RNase E reverse the extreme slow-growth phenotype caused by a mutant translation factor EF-Tu

Salmonella enterica with mutant EF-Tu (Gln125Arg) has a low level of EF-Tu, a reduced rate of protein synthesis and an extremely slow growth rate. Eighty independent suppressor mutations were selected that restored normal growth. In some cases (n= 7) suppression was due to mutations in tufA but, surprisingly, in most cases (n= 73) to mutations in rne, the gene coding for RNase E. These rne mutations alone had only modest effects on growth rate. Fifty different suppressor mutations were isolated in rne, all located in or close to the N-terminal endonucleolytic half of RNase E. Steady state levels of several mRNAs were lower in the mutant tuf strain but restored to wild-type levels in the tuf-rne double mutant. In contrast, the half-lives of mRNAs were unaffected by the tuf mutation. We propose a model where the tuf mutation causes the ribosome following RNA polymerase to pause, possibly in a codon-specific manner, exposing unshielded nascent message to RNase E cleavage. Normal growth rate can be restored by increasing EF-Tu activity or by reducing RNase E activity. Accordingly, RNase E is suggested to act at two distinct stages in the life of mRNA: early, on the nascent transcript; late, on the complete mRNA.

Phylogeny of the Enterobacteriaceae based on genes encoding elongation factor Tu and F-ATPase β-subunit

The phylogeny of enterobacterial species commonly found in clinical samples was analysed by comparing partial sequences of their elongation factor Tu gene (tuf) and of their F-ATPase β-subunit gene (atpD). An 884 bp fragment for tuf and an 884 or 871 bp fragment for atpD were sequenced for 96 strains representing 78 species from 31 enterobacterial genera. The atpD sequence analysis exhibited an indel specific to Pantoea and Tatumella species, showing, for the first time, a tight phylogenetic affiliation between these two genera. Comprehensive tuf and atpD phylogenetic trees were constructed and are in agreement with each other. Monophyletic genera are Cedecea, Edwardsiella, Proteus, Providencia, Salmonella, Serratia, Raoultella and Yersinia. Analogous trees based on 16S rRNA gene sequences available from databases were also reconstructed. The tuf and atpD phylogenies are in agreement with the 16S rRNA gene sequence analysis, and distance comparisons revealed that the tuf and atpD genes provide better discrimination for pairs of species belonging to the family Enterobacteriaceae. In conclusion, phylogeny based on tuf and atpD conserved genes allows discrimination between species of the Enterobacteriaceae.

Co-evolution of the tuf genes links gene conversion with the generation of chromosomal inversions

The tufA and tufB genes in Salmonella typhimurium co-evolve by recombination and exchange of genetic material. A model is presented which predicts that co-evolution is achieved by gene conversions and chromosomal inversions. Analysis of recombinants reveals that conversion and inversion each occur with similar rates and each depends on RecBCD activity. The model predicts sequence structures for different classes of post-recombination tuf genes. Sequence analysis reveals the presence of each of these structures and classes, with a predicted bias in the absence of mismatch repair. An implication of these data is that co-evolution of gene families can be linked with the generation of chromosomal rearrangements.

Influence of the last amino acid in the nascent peptide on EF-Tu during decoding

The last two amino acids of the nascent peptide at the ribosomal P-site influence the efficiency of termination readthrough at the stop codon UGA (Mottagui-Tabar et al (1994) EMBO J 13, 249-257; Björnsson et al (1996) EMBO J 15, 1696-1704). Here we analyze this effect on readthrough by wild type or a UGA suppressor form (Su9) of tRNA(Trp) by varying the codons at positions-1 and -2 at the 5' side of UGA. Strains with wild-type or mutant (ArBr) forms of elongation factor Tu (EF-Tu) were analyzed (Vijgenboom et al (1985) EMBO J4, 1049-1052). The effect on readthrough by changing these-1 and -2 codons is different on the two forms of tRNA(Trp) and is also dependent on the structure of EF-Tu. Readthrough by the tRNA(Trp)-derived suppressor, but not wild-type tRNA(Trp), is sensitive to the van der Waals volume of the last amino acid in the nascent peptide. Together with mutant EF-Tu, both forms of tRNA(Trp) are sensitive. The data suggest that the C-terminal amino acid in the nascent peptide is in a functional interaction with the EF-Tu ternary complex. This interaction is changed by mutation in tRNA(Trp) at position 24 or in EF-Tu at position 375. No indication of a changed interaction between the mutant EF-Tu and the penultimate amino acid could be found. Mutant forms of RF2 (Mikuni et al (1991) Biochimie 73, 1509-1516) and ribosomal proteins S4 and S12 (Fáxen et al (1988) J Bacteriol 170, 3756-3760) were found not be altered in sensitivity to the last two amino acids in the nascent peptide.

Genetic map of Salmonella typhimurium, edition VIII

We present edition VIII of the genetic map of Salmonella typhimurium LT2. We list a total of 1,159 genes, 1,080 of which have been located on the circular chromosome and 29 of which are on pSLT, the 90-kb plasmid usually found in LT2 lines. The remaining 50 genes are not yet mapped. The coordinate system used in this edition is neither minutes of transfer time in conjugation crosses nor units representing "phage lengths" of DNA of the transducing phage P22, as used in earlier editions, but centisomes and kilobases based on physical analysis of the lengths of DNA segments between genes. Some of these lengths have been determined by digestion of DNA by rare-cutting endonucleases and separation of fragments by pulsed-field gel electrophoresis. Other lengths have been determined by analysis of DNA sequences in GenBank. We have constructed StySeq1, which incorporates all Salmonella DNA sequence data known to us. StySeq1 comprises over 548 kb of nonredundant chromosomal genomic sequences, representing 11.4% of the chromosome, which is estimated to be just over 4,800 kb in length. Most of these sequences were assigned locations on the chromosome, in some cases by analogy with mapped Escherichia coli sequences.

Mutations to kirromycin resistance occur in the interface of domains I and III of EF-Tu.GTP

The antibiotic kirromycin inhibits protein synthesis by binding to EF-Tu and preventing its release from the ribosome after GTP hydrolysis. We have isolated and sequenced a collection of kirromycin resistant tuf mutations and identified thirteen single amino acid substitutions at seven different sites in EF-Tu. These have been mapped onto the 3D structures of EF-Tu.GTP and EF-Tu.GDP. In the active GTP form of EF-Tu the mutations cluster on each side of the interface between domains I and III. We propose that this domain interface is the binding site for kirromycin.

Fusidic acid-resistant mutants define three regions in elongation factor G of Salmonella typhimurium

We have sequenced fusA, the gene coding for elongation factor G (EF-G), in 18 different mutants of Salmonella typhimurium selected as fusidic acid resistant (FuR). In addition, we have sequenced two previously described FuR mutants from Escherichia coli. In all cases, the resistance is due to a mutation in one of three separate regions in fusA. The three clusters of mutant sites superimpose on regions that are well conserved, suggesting that they are of a more general functional importance. To further classify the mutants, we have measured the minimal inhibitory concentration (MIC) for Fu and for two other antibiotics which interfere with translocation on the ribosome, kanamycin (Km) and spectinomycin (Sp). The levels of resistance to Fu for each of the mutants are significantly higher than in the wild type (wt), and vary by about one order of magnitude between the highest and the lowest. Most of the mutants are also more resistant to Km than the wt, although the level of resistance is low and the variation small. In contrast, about half of the mutants are more sensitive to Sp than the wt, with only one being more resistant. Only three of the twenty mutants behave like the wt with respect to the non-selected phenotypes, KmR and SpR.

Growth and translation elongation rate are sensitive to the concentration of EF-Tu

We have used quantitative immunoblotting to estimate the amount of EF-Tu in a variety of S. typhimurium strains with wild-type, mutant, insertionally inactivated or plasmid-borne tuf genes. In the same strains we have measured translation elongation rate, exponential growth rate and the level of nonsense codon readthrough. In the wild-type strain, at moderate to fast growth rates, our data show that EF-Tu makes up 8-9% of total cell protein. Strains with either of the tuf genes insertionally inactivated have 65% of the wild-type EF-Tu level, irrespective of which tuf gene remains active, or whether that gene is wild-type or a kirromycin-resistant mutant. Strains with only one active tuf gene have reduced growth and translation elongation rates. From the magnitude of the reduction in elongation rate relative to the level of EF-Tu we calculate that in glucose minimal medium the in vivo saturation level of wild-type ribosomes by ternary complexes is only 63%. Strains with a ribosome mutation causing a poor interaction with ternary complex are non-viable on minimal medium when the level of EF-Tu is reduced.

A technique for targeted mutagenesis of the EF-Tu chromosomal gene by M13-mediated gene replacement

A generally applicable system for targeted mutagenesis of a chromosomal sequence is described. The Escherichia coli tufA gene was mutated using a recombinant M13mp9 phage vector carrying a tuf gene. Integration via crossing over with the chromosomal tufA target gene produced an M13 lysogen. These lysogens were screened for resistance to kirromycin. The M13 phage carrying tufA mutations were efficiently retrieved by a genetic procedure. Genetic mapping was performed with the M13 vectors. The same recombinant M13 phage was used for mutagenesis, lysogen formation, gene replacement, retrieval, mapping and sequencing of kirromycin mutants. Three different mutations yielding resistance to kirromycin were found: two of these have previously been found and characterised, while the third mutation, Gly316-->Asp, is a new mutant. We also report the identification of a fourth kirromycin-resistant mutant, Gln124-->Lys.

Elongation factors in protein synthesis

Recent discoveries of elongation factor-related proteins have considerably complicated the simple textbook scheme of the peptide chain elongation cycle. During growth and differentiation the cycle may be regulated not only by factor modification but also factor replacement. In addition, rare tRNAs may have their own rare factor proteins. A special case is the acquisition of resistance by bacteria to elongation factor-directed antibiotics. Pertinent data from the literature and our own work with Escherichia coli and Streptomyces are discussed. The GTP-binding domain of EF-Tu has been studied extensively, but little molecular detail is available on the interactions with its other ligands or effectors, or on the way they are affected by the GTPase switch signal. A growing number of EF-Tu mutants obtained by ourselves and others are helping us in testing current ideas. We have found a synergistic effect between EF-Tu and EF-G in their uncoupled GTPase reactions on empty ribosomes. Only the EF-G reaction is perturbed by fluoroaluminates.

A single amino acid substitution in elongation factor Tu disrupts interaction between the ternary complex and the ribosome

Elongation factor Tu (EF-Tu).GTP has the primary function of promoting the efficient and correct interaction of aminoacyl-tRNA with the ribosome. Very little is known about the elements in EF-Tu involved in this interaction. We describe a mutant form of EF-Tu, isolated in Salmonella typhimurium, that causes a severe defect in the interaction of the ternary complex with the ribosome. The mutation causes the substitution of Val for Gly-280 in domain II of EF-Tu. The in vivo growth and translation phenotypes of strains harboring this mutation are indistinguishable from those of strains in which the same tuf gene is insertionally inactivated. Viable cells are not obtained when the other tuf gene is inactivated, showing that the mutant EF-Tu alone cannot support cell growth. We have confirmed, by partial protein sequencing, that the mutant EF-Tu is present in the cells. In vitro analysis of the natural mixture of wild-type and mutant EF-Tu allows us to identify the major defect of this mutant. Our data shows that the EF-Tu is homogeneous and competent with respect to guanine nucleotide binding and exchange, stimulation of nucleotide exchange by EF-Ts, and ternary complex formation with aminoacyl-tRNA. However various measures of translational efficiency show a significant reduction, which is associated with a defective interaction between the ribosome and the mutant EF-Tu.GTP.aminoacyl-tRNA complex. In addition, the antibiotic kirromycin, which blocks translation by binding EF-Tu on the ribosome, fails to do so with this mutant EF-Tu, although it does form a complex with EF-Tu. Our results suggest that this region of domain II in EF-Tu has an important function and influences the binding of the ternary complex to the codon-programmed ribosome during protein synthesis. Models involving either a direct or an indirect effect of the mutation are discussed.

Suppression of rpsL phenotypes by tuf mutations reveals a unique relationship between translation elongation and growth rate

We have found a simple relationship between bacterial growth rate and the translation elongation rate. Thus, for a set of defined ribosomal protein S12 mutations which reduce the efficiency of the ternary complex ribosome interaction (and restrict the frequency of translational errors) there is a linear relationship between growth rate and translation elongation rate. When these mutants are combined with defined EF-Tu mutants (which increase the probability of translational errors) both the elongation rate and growth rate reductions are reversed. The reductions and reversals are described by a unique linear relationship. We interpret this to mean that these two types of mutation exert opposing effects on the same molecular interaction. We suggest that this interaction is in the initial selection of the aminoacyl-tRNA on the ribosome. The slope of the relationship between translation elongation rate and growth rate, defined in per cent of the wild-type rates, is close to 1. Interestingly, the reversal of the elongation and growth phenotypes is incomplete, suggesting that the ribosomal mutants have an additional defect which is not compensated for by the ternary complex interaction. Our results show that the efficiency of the ternary complex ribosome interaction limits the translation elongation rate, which in turn correlates with changes in exponential growth rate.