Functional EF-Tu with large C-terminal extensions in an E coli strain with a precise deletion of both chromosomal tuf genes

An Escherichia coli strain was constructed in which both chromosomal genes encoding elongation factor (EF)-Tu (tufA and tufB) have been inactivated with precise coding sequence replacements. A tufA gene in an expression vector is supplied as the sole EF-Tu source. By using plasmid replacement, based on plasmid incompatibility, mutant EF-Tu variants with a large C'-terminal extension up to 270 amino acids were studied and proved to be functional in a strain lacking the chromosomal tufA and tufB genes.     

Transfer of plasmid-borne tuf mutations to the chromosome as a genetic tool for studying the functioning of EF-TuA and EF-TuB in the E. coli cell

The elongation factor EF-Tu of E. coli is a multifunctional protein that lends itself extremely well to studies concerning structure-function relationships. It is encoded by two genes: tufA and tufB. Mutant species of EF-Tu have been obtained by various genetic manipulations, including site- and segment-directed mutagenesis of tuf genes on a vector. The presence of multiple tuf genes in the cell, both chromosomal and plasmid-borne, hampers the characterization of the mutant EF-Tu. We describe a procedure for transferring plasmid-borne tuf gene mutations to the chromosome. Any mutation engineered by genetic manipulation of tuf genes on a vector can be transferred both to the tufA and the tufB position on the chromosome. The procedure facilitated the functional characterization of some of our recently obtained tuf mutations. Of particular relevance is, that it enabled us for the first time to obtain a mutant tufB on the chromosome, encoding an EF-TuB resistant to kirromycin. It thus became possible to study the consequences for growth of tufA inactivation by insertion of bacteriophage Mu. The preliminary evidence obtained suggests that an EF-TuA, active in polypeptide synthesis, is essential for growth whereas such an EF-TuB is dispensable.     

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

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

Cloning and characterization of the chloroplast elongation factor EF-Tu cDNA of Oryza sativa L

From the rice leaf cDNA library, we have cloned a cDNA encoding rice chloroplast translational elongation factor EF-Tu (tufA). The rice tufA cDNA clone contains 1678 nucleotides and codes for a 467 amino acid protein including a putative chloroplast transit peptide of 59 amino acid residues. The predicted molecular mass of the mature protein is approximately 45 kDa. This cDNA clone contains the 61 nucleotides of the 5' untranslated region (UTR) and the 213 nucleotides of 3' UTR. Amino acid sequence identity of the rice tufA with the mature chloroplast EF-Tu proteins of tobacco, pea, arabidopsis, and soybean ranges from 83% to 86%. The deduced polypeptide of the rice tufA cDNA contains GTP binding domains in its N-terminal region and chloroplast EF-Tu signature regions in the C-terminal region. The rice tufA appears to exist as a single copy gene, although its homologues of maize and oat exist as multiple copy genes. The rice tufA gene is located in chromosome 1 and is more highly expressed in the leaf than in root tissue.     

Divergence among genes encoding the elongation factor Tu of Yersinia Species

Elongation factor Tu (EF-Tu), encoded by tuf genes, carries aminoacyl-tRNA to the ribosome during protein synthesis. Duplicated tuf genes (tufA and tufB), which are commonly found in enterobacterial species, usually coevolve via gene conversion and are very similar to one another. However, sequence analysis of tuf genes in our laboratory has revealed highly divergent copies in 72 strains spanning the genus Yersinia (representing 12 Yersinia species). The levels of intragenomic divergence between tufA and tufB sequences ranged from 8.3 to 16.2% for the genus Yersinia, which is significantly greater than the 0.0 to 3.6% divergence observed for other enterobacterial genera. We further explored tuf gene evolution in Yersinia and other Enterobacteriaceae by performing directed sequencing and phylogenetic analyses. Phylogenetic trees constructed using concatenated tufA and tufB sequences revealed a monophyletic genus Yersinia in the family Enterobacteriaceae. Moreover, Yersinia strains form clades within the genus that mostly correlate with their phenotypic and genetic classifications. These genetic analyses revealed an unusual divergence between Yersinia tufA and tufB sequences, a feature unique among sequenced Enterobacteriaceae and indicative of a genus-wide loss of gene conversion. Furthermore, they provided valuable phylogenetic information for possible reclassification and identification of Yersinia species.     

Sequence and identification of the nucleotide binding site for the elongation factor Tu from Thermus thermophilus HB8.

Two structural genes for the Thermus thermophilus elongation factor Tu (tuf) were identified by cross-hybridization with the tufA gene from E. coli. The sequence of one of these tuf genes, localized on a 6.6 kb Bam HI fragment, was determined and confirmed by partial protein sequencing of an authentic elongation factor Tu from T. thermophilus HB8. Expression of this tuf gene in E. coli minicells provided a low amount of immuno-precipitable thermophilic EF-Tu. Affinity labeling of the T. thermophilus EF-Tu and sequence comparison with homologous proteins from other organisms were used to identify the guanosine-nucleotide binding domain.     

A mutation that alters the nucleotide specificity of elongation factor Tu, a GTP regulatory protein

A single amino acid substitution (Asp to Asn) at position 138 of Escherichia coli elongation factor Tu (EF-Tu) was introduced in the tufA gene clone by oligonucleotide site-directed mutagenesis. The mutated tufA gene was then expressed in maxicells. The properties of [35S]methionine-labeled mutant and wild type EF-Tu were compared by in vitro assays. The Asn-138 mutation greatly reduced the protein's affinity for GDP; however, this mutation dramatically increased the protein's affinity for xanthosine 5'-diphosphate. The mutant protein forms a stable complex with Phe-tRNA and xanthosine 5'-triphosphate, which binds to ribosomes, whereas it does not form a complex with Phe-tRNA and GTP (10 microM). These results suggest that in EF-Tu.nucleoside diphosphate complexes, amino acid residue 138 must interact with the substituent on C-2 of the purine ring. Thus, in wild type EF-Tu, Asp-138 would hydrogen bond to the 2-amino group of GDP, and in the mutant EF-Tu, Asn-138 would form an equivalent hydrogen bond with the 2-carbonyl group of xanthosine 5'-diphosphate. Aspartic acid 138 is conserved in the homologous sequences of all GTP regulatory proteins. This mutation would allow one to specifically alter the nucleotide specificity of other GTP regulatory proteins.     

Pulvomycin-resistant mutants of E.coli elongation factor Tu.

This paper reports the generation of Escherichia coli mutants resistant to pulvomycin. Together with targeted mutagenesis of the tufA gene, conditions were found to overcome membrane impermeability, thereby allowing the selection of three mutants harbouring elongation factor (EF)-Tu Arg230-->Cys, Arg333-->Cys or Thr334-->Ala which confer pulvomycin resistance. These mutations are clustered in the three-domain junction interface of the crystal structure of the GTP form of Thermus thermophilus EF-Tu. This result shares similarities with kirromycin resistance; kirromycin-resistant mutations cluster in the domain 1-3 interface. Since both interface regions are involved in the EF-Tu switch mechanism, we propose that pulvomycin and kirromycin both act by specifically disturbing the allosteric changes required for the switch from EF-Tu-GTP to EF-Tu-GDP. The three-domain junction changes dramatically in the switch to EF-Tu.GDP; in EF-Tu.GDP this region forms an open hole. Structural analysis of the mutation positions in EF-Tu.GTP indicated that the two most highly resistant mutants, R230C and R333C, are part of an electrostatic network involving numerous residues. All three mutations appear to destabilize the EF-Tu.GTP conformation. Genetic and protein characterizations show that sensitivity to pulvomycin is dominant over resistance. This appears to contradict the currently accepted model of protein synthesis inhibition by pulvomycin.     

Both genes for EF-Tu in Salmonella typhimurium are individually dispensable for growth

Each of the two genes encoding EF-Tu in Salmonella typhimurium has been inactivated using a mini-Mu MudJ insertion. Eleven independently isolated insertions are described, six in tufA and five in tufB. Transduction analysis shows that the inserted MudJ is 100% linked to the appropriate tuf gene. A mutant strain with electrophoretically distinguishable EF-TuA and EF-TuB was used to show, on two-dimensional gels, that the MudJ insertions result in the loss of the appropriate EF-Tu protein. Southern blotting, using cloned Escherichia coli tuf sequences as probes, shows that each MudJ insertion results in the physical breakage of the appropriate tuf gene. The degree of growth-rate impairment associated with each tuf inactivation is independent of which tuf gene is inactivated. The viability of S. typhimurium strains with either tuf gene inactive contrasts strongly with data suggesting that in the closely related bacterium E. coli, an active tufA gene is essential for growth. Finally the strains described here facilitate the analysis of phenotypes associated with individual mutant or wild-type Tus both in vivo and in vitro.     

Regulation of the ColV plasmid-determined iron (III)-aerobactin transport system in Escherichia coli.

Regulation by iron was studied in Escherichia coli strains whose iron supply was entirely dependent on the iron(III)-aerobactin system determined by the ColV plasmid. By the insertion of phage Mu (Ap lac) into the ColV plasmid, mutants were selected that could no longer grow in iron-limited media. The inserted Mu (Ap lac) strongly reduced the amount of aerobactin and he cloacin receptor protein formed by the cells. Their production was no longer subject to regulation by iron. The Mu (Ap lac) insertion apparently led to a polar effect on the expression of the presumably closely linked genes that control the synthesis of aerobactin and the cloacin receptor protein. The expression of the beta-galactosidase gene on the inserted phage genome came under the control of the iron state of the cells. Under iron-limited growth conditions, the amount of beta-galactosidase synthesized was, depending on the strain studied, 6 to 30 times higher than under iron-sufficient growth conditions. In fur mutants with an impaired iron regulation of ll iron supply systems studied so far, high amounts of beta-galactosidase were synthesized independent of the cells' iron supply. The results demonstrate an iron-controlled promoter on the ColV plasmid which is subject to regulation by the chromosomal fur gene.     

Translational frameshifts induced by mutant species of the polypeptide chain elongation factor Tu of Escherichia coli

Translational frameshifts, both +1 and -1, are promoted by mutations in tufA and tufB, the two genes encoding the polypeptide chain elongation factor (EF) Tu of Escherichia coli. Strains harboring the mutant EF-Tu(Ala375----Thr) encoded by either tufA or tufB or by both, display a linear relationship between the frequency of frameshifting and the concentration of mutant EF-Tu, relative to the total amount of EF-Tu. A second mutant species, EF-TuB(Gly222----Asp), also promotes frameshifting. The frequency is strikingly enhanced by the combined action of EF-TuA(Ala375----Thr) and EF-TuB(Gly222----Asp) and exceeds by far the total contribution of the two mutant EF-Tus studied separately. These observations raise the question whether the formation of each peptide bond under conditions that no frameshifting occurs also requires the combined action of two EF-Tu molecules, in this case not differing functionally.