Duplication of the tuf gene: a new insight into the phylogeny of eubacteria.

The conservation and duplication of the tuf gene encoding the elongation factor EF-Tu were used to define phylogenetic relationships among eubacteria. When the tufA gene of Escherichia coli was used as a probe in hybridization experiments, duplicate tuf genes were found in gram-negative bacteria from three major phyla: purple bacteria, bacteroides, and cyanobacteria. Only a single copy of tuf was found in gram-positive bacteria, including mycobacteria and mycoplasmas. Gram-positive clostridia were found to carry two copies of tuf.     

Evidence for horizontal gene transfer in evolution of elongation factor Tu in enterococci

The elongation factor Tu, encoded by tuf genes, is a GTP binding protein that plays a central role in protein synthesis. One to three tuf genes per genome are present, depending on the bacterial species. Most low-G+C-content gram-positive bacteria carry only one tuf gene. We have designed degenerate PCR primers derived from consensus sequences of the tuf gene to amplify partial tuf sequences from 17 enterococcal species and other phylogenetically related species. The amplified DNA fragments were sequenced either by direct sequencing or by sequencing cloned inserts containing putative amplicons. Two different tuf genes (tufA and tufB) were found in 11 enterococcal species, including Enterococcus avium, Enterococcus casseliflavus, Enterococcus dispar, Enterococcus durans, Enterococcus faecium, Enterococcus gallinarum, Enterococcus hirae, Enterococcus malodoratus, Enterococcus mundtii, Enterococcus pseudoavium, and Enterococcus raffinosus. For the other six enterococcal species (Enterococcus cecorum, Enterococcus columbae, Enterococcus faecalis, Enterococcus sulfureus, Enterococcus saccharolyticus, and Enterococcus solitarius), only the tufA gene was present. Based on 16S rRNA gene sequence analysis, the 11 species having two tuf genes all have a common ancestor, while the six species having only one copy diverged from the enterococcal lineage before that common ancestor. The presence of one or two copies of the tuf gene in enterococci was confirmed by Southern hybridization. Phylogenetic analysis of tuf sequences demonstrated that the enterococcal tufA gene branches with the Bacillus, Listeria, and Staphylococcus genera, while the enterococcal tufB gene clusters with the genera Streptococcus and Lactococcus. Primary structure analysis showed that four amino acid residues encoded within the sequenced regions are conserved and unique to the enterococcal tufB genes and the tuf genes of streptococci and Lactococcus lactis. The data suggest that an ancestral streptococcus or a streptococcus-related species may have horizontally transferred a tuf gene to the common ancestor of the 11 enterococcal species which now carry two tuf genes.     

Klebsiella pneumoniae origin of replication (oriC) is not active in Caulobacter crescentus, Pseudomonas putida, and Rhodobacter sphaeroides.

A DNA fragment carrying genes encoding the conjugal transfer system of the broad host range plasmid RK2 was inserted into a plasmid carrying the chromosomal origin of replication (oriC) from Klebsiella pneumoniae. The resulting plasmid, pEON1, was readily transferred between gram-negative bacteria and carried two potential origins of replication: oriC and the replication origin from pBR322 (oriPBR). Although pEON1 could be transferred to Caulobacter crescentus, Pseudomonas putida, and Rhodobacter sphaeroides, pEON1 was not maintained in these strains. However, an oriC-containing plasmid was maintained in these nonenteric bacteria when an RK2 origin of replication was present on the plasmid. Thus, the inability of pEON1 to be established in a nonenteric bacterium represents a failure of oriC to function as an origin of replication rather than a toxic effect of oriC. The initiation potential of the chromosomal origin of replication from K. pneumoniae appears to be realized only in enteric bacteria.     

Two tuf genes in the cyanobacterium Spirulina platensis.

Probes derived from the tufA gene of Escherichia coli have been utilized to detect homologous sequences on Spirulina platensis DNA. A 6-kilobase-pair fragment of S. platensis DNA appears to contain two sequences homologous to the E. coli gene. Thus, as reported for gram-negative bacteria, the cyanobacterium presumably contains two tuf genes.     

The conservation of DNA sequences over very long periods of evolutionary time. Evidence against intergeneric chromosomal transfer as an explanation for the presence of Escherichia coli tuf gene sequences in taxonomically-unrelated prokaryotes

In the present study we tried to determine whether the presence of DNA sequences homologous to the Escherichia coli tuf gene (encodes peptide chain elongation factor Tu) in many taxonomically-unrelated prokaryotes is due to selective pressure for these sequences or due to the transfer of chromosomal material subsequent to the divergence of the genera from their progenitors. We found that the degree of sequence homology to the DNA immediately adjacent to the E. coli tuf A gene is either nonexistent or much less than that found for the tuf gene. Furthermore, the tuf-homologous sequences present in one prokaryote were found to be in large part the same as or a subset of those present in others. That is, various prokaryotes share a common subset of tuf-homologous sequences. These findings suggest that strong selective pressure and not recent intergeneric chromosomal transfer is responsible for the ubiquitous presence of certain tuf-homologous sequences. Because the genetic code is degenerate, DNA sequence need not be conserved to conserve protein sequence. Therefore, if the only function of these sequences is to encode protein, their persistence must mean that in some instances codon sequence is selected for.     

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.     

dGTP triphosphohydrolase, a unique enzyme confined to members of the family Enterobacteriaceae.

The enzyme dGTP triphosphohydrolase (dGTPase; EC 3.1.5.1) was assayed in partially purified extracts of several genera of bacteria, and it was found to be strictly confined to members of the family Enterobacteriaceae. Whereas 11 of 12 enteric bacteria had comparable activity for this enzyme, 8 of 8 nonenteric bacteria, including species in the very closely related genera Vibrio and Aeromonas, did not assay positively for this enzyme. When challenged with Escherichia coli anti-dGTPase antiserum, the active enzymes fell into three groups, retaining 0, approximately 50, or 100% of their original activity. A computer search has revealed an amino acid sequence in the E. coli enzyme which matches well with the single-stranded-DNA binding motif of Prasad and Chiu (J. Mol. Biol. 193:579-584, 1987) and may account for the enzyme's observed interaction with DNA. As far as we are aware, this is the only enzymatic activity so far reported to be present solely in the enteric bacteria.     

Nucleotide sequence and codon usage of the elongation factor Tu(EF-Tu) gene from Mycoplasma pneumoniae

The Mycoplasma pneumoniae tuf gene, encoding the elongation factor protein Tu, was cloned and sequenced. The nucleotide sequence of the mycoplasmal gene showed about 60% homology to the sequences of tuf genes of other prokaryotes, yeast mitochondria and Euglena gracilis chloroplasts, and about 75% similarity was found when comparing the deduced amino acid sequences of the various Tu proteins. The relatively low G + C content (40%) of the M. pneumoniae DNA was reflected in a low G + C content (44.6%) of the tuf gene, and in a preferential use of adenine and uracil at the third position of codons, yet codon usage analysis revealed the presence of almost all of the codons of the genetic code in the mycoplasmal gene. Southern blot hybridization of digested DNAs of 11 Mollicutes species with the entire M. pneumoniae tuf gene and with its 5' part suggested the presence of one copy only of this gene in the representative species of the Mollicutes. In this respect, the Mollicutes resemble Gram-positive bacteria and differ from the Gram-negative bacteria, which carry two copies of the tuf gene.     

A chimeric disposition of the elongation factor genes in Rickettsia prowazekii.

An exceptional disposition of the elongation factor genes is observed in Rickettsia prowazekii, in which there is only one tuf gene, which is distant from the lone fus gene. In contrast, the closely related bacterium Agrobacterium tumefaciens has the normal bacterial arrangement of two tuf genes, of which one is tightly linked to the fus gene. Analysis of the flanking sequences of the single tuf gene in R. prowazekii shows that it is preceded by two of the four tRNA genes located in the 5' region of the Escherichia coli tufB gene and that it is followed by rpsJ as well as associated ribosomal protein genes, which in E. coli are located downstream of the tufA gene. The fus gene is located within the str operon and is followed by one tRNA gene as well as by the genes secE and nusG, which are located in the 3' region of tufB in E. coli. This atypical disposition of genes suggests that intrachromosomal recombination between duplicated tuf genes has contributed to the evolution of the unique genomic architecture of R. prowazekii.     

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.     

Determination of the number of tuf genes in Chlamydia trachomatis and Neisseria gonorrhoeae

Restriction endonuclease fragments of DNA from Neisseria gonorrhoeae and Chlamydia trachomatis (mouse pneumonitis biovar) were hybridized to probes from the N-terminal and C-terminal portions of the Escherichia coli tufA gene. In common with other Gram-negative bacteria, the genome of N. gonorrhoeae was found to contain two homologous sequences (presumptive tuf genes). The C. trachomatis genome contained a single tuf sequence.     

Sequencing of heat shock protein 70 (DnaK) homologs from Deinococcus proteolyticus and Thermomicrobium roseum and their integration in a protein-based phylogeny of prokaryotes.

The 70-kDa heat shock protein (hsp70) sequences define one of the most conserved proteins known to date. The hsp70 genes from Deinococcus proteolyticus and Thermomicrobium roseum, which were chosen as representatives of two of the most deeply branching divisions in the 16S rRNA trees, were cloned and sequenced. hsp70 from both these species as well as Thermus aquaticus contained a large insert in the N-terminal quadrant, which has been observed before as a unique characteristic of gram-negative eubacteria and eukaryotes and is not found in any gram-positive bacteria or archaebacteria. Phylogenetic analysis of hsp70 sequences shows that all of the gram-negative eubacterial species examined to date (which includes members from the genera Deinococcus and Thermus, green nonsulfur bacteria, cyanobacteria, chlamydiae, spirochetes, and alpha-, beta-, and gamma-subdivisions of proteobacteria) form a monophyletic group (excluding eukaryotic homologs which are derived from this group via endosybitic means) strongly supported by the bootstrap scores. A closer affinity of the Deinococcus and Thermus species to the cyanobacteria than to the other available gram-negative sequences is also observed in the present work. In the hsp7O trees, D. proteolyticus and T. aquaticus were found to be the most deeply branching species within the gram-negative eubacteria. The hsp70 homologs from gram-positive bacteria branched separately from gram-negative bacteria and exhibited a closer relationship to and shared sequence signatures with the archaebacteria. A polyphyletic branching of archaebacteria within gram-positive bacteria is strongly favored by different phylogenetic methods. These observations differ from the rRNA-based phylogenies where both gram-negative and gram-positive species are indicated to be polyphyletic. While it remains unclear whether parts of the genome may have variant evolutionary histories, these results call into question the general validity of the currently favored three-domain dogma.     

Analysis of the nucleotide sequence of the Mycoplasma hominis tuf gene and its flanking region

A gene from Mycoplasma hominis PG21 similar to the tuf gene encoding the elongation factor Tu (EF-Tu) of Escherichia coli was cloned and sequenced. The 1193-bp open reading frame flanked by a putative promoter and a potential stem-and-loop structure encoded a 44-kDa polypeptide. The tuf gene of M. hominis PG21 has the lowest G + C content seen in prokaryotes (38.2%). A gene (mhlmp1) encoding a variable surface exposed membrane protein (LMP1) was found downstream the 3' end of the tuf gene. It was found that the highly conserved tuf gene was linked to the highly variable mhlmp1 gene in 26 different M. hominis strains.     

Major heat-modifiable outer membrane protein in gram-negative bacteria: comparison with the ompA protein of Escherichia coli.

The outer membranes of several strains of Escherichia coli, other enteric bacteria, and a variety of nonenteric gram-negative bacteria all contain a major heat-modifiable protein similar to the OmpA protein of E. coli K-12. The heat-modifiable proteins from these bacteria resemble the K-12 protein in molecular weight, in preferential release from the outer membrane by sodium dodecyl sulfate in the presence of Mg2+, and in characteristic cleavage by proteases to yield a smaller fragment which remains membrane bound. Antiserum directed against the K-12 protein precipitated the heat-modifiable protein from all strains of Enterobacteriaceae, and chemical comparison by isoelectric focusing, cyanogen bromide cleavage profiles, and proteolytic peptide analysis indicated that the proteins from the various enteric bacteria were nearly identical in primary structure. The heat-modifiable proteins from bacteria phylogenically distant from E. coli shared many of the properties of the E. coli protein but were chemically distinct. Thus, it appears that the structure (and, presumably, the function) of the heat-modifiable protein of gram-negative bacteria is strongly conserved during evolution.     

Genetic and molecular analysis of the tRNA-tufB operon of the myxobacterium Stigmatella aurantiaca.

The tufB gene, encoding elongation factor Tu (EF-Tu), from the myxobacterium Stigmatella aurantiaca was cloned and sequenced. It is preceded by four tRNA genes, the first ever described in myxobacteria. The tRNA synthesized from these genes and the general organization of the locus seem identical to that of Escherichia coli, but differences of potential importance were found in the tRNA sequences and in the intergenic regions. The primary structure of EF-Tu was deduced from the tufB DNA sequence. The factor is composed of 396 amino acids, with a predicted molecular mass of 43.4 kDa, which was confirmed by expression of tufB in maxicells. Sequence comparisons between S.aurantiaca EF-Tu and other bacterial homologues from E.coli, Salmonella typhimurium and Thermus thermophilus displayed extensive homologies (75.9%). Among the variable positions, two Cys residues probably involved in the temperature sensitivity of E.coli and S.typhimurium EF-Tu are replaced in T.thermophilus and S.aurantiaca EF-Tu. Since two or even three tuf genes have been described in other bacterial species, the presence of multiple tuf genes was sought for. Southern and Northern analysis are consistent with two tuf genes in the genome of S.aurantiaca. Primer extension experiments indicate that the four tRNA genes and tufB are organized in a single operon.     

Propionispora vibrioides, nov. gen., nov. sp., a new gram-negative, spore-forming anaerobe that ferments sugar alcohols

Anaerobic enrichment cultures, with erythritol as substrate, resulted in the isolation of a strain with properties not yet found in an existing genus in this combination. The strain, FKBS1, was strictly anaerobic, stained gram-negative and formed spores. Cells were small motile vibrios with flagella inserted at the concave side of the cell. Spores were located terminally and caused only slight swelling of the cells if compared to related spore-forming genera. FKBS1 fermented fructose, mannitol, sorbitol, xylitol and erythritol to propionic acid, acetic acid, CO2 and small amounts of H2 to balance the difference in the oxidation-reduction value between substrate and cell mass. The 16S rDNA sequence revealed relationship to the Sporomusa-Pectinatus-Selenomonas group. However, the phylogenetic distance to any of its members was too great to allow it to be placed in one of the existing genera. Morphologically the strain resembled Sporomusa, which, however, performs an acetogenic type of fermentation. The propionic-acid-forming genera of the group are either not spore-formers or, in the case of Dendrosporobacter quercicolus (syn. Clostridium quercicolum), morphologically different. It is therefore proposed to classify strain FKBS1 as a new genus and species, Propionispora vibrioides.     

The role of EF-Tu and other translation components in determining translocation step size

The two EF-Tu encoding genes, tufA and tufB, of Salmonella typhimurium have been sequenced. Nearly all the differences from their Escherichia coli counterparts are third position changes which do not alter the encoded amino acids. Unexpectedly, most of the changes in one Salmonella tuf gene are paralleled by changes in the other tuf gene perhaps due to gene repair despite the distance separating the genes. Three mutants which cause mis-framing, have their substitutions at codon 375. Explanations for mutants which cause mis-framing are considered and the mechanism of normal reading frame maintenance discussed.     

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.