Population structure of Pseudomonas aeruginosa through a MLST approach and antibiotic resistance profiling of a Mexican clinical collection.

Pseudomonas aeruginosa is one of the most important pathogens worldwide. Population genetics studies have shown that the P. aeruginosa population has an epidemic structure with highly conserved clonal complexes. Nonetheless, epidemiological studies of P. aeruginosa have been historically absent or infrequent in developing countries, in which different medical treatments, conditions and infrastructure may have an impact in population dynamics and evolutionary outcomes, including antibiotic resistance profiles. In this study we contribute to fill this gap by analyzing 158 P. aeruginosa isolates from the most extensive nosocomial collection in Mexico City. We investigated the population genetic structure through a MLST approach together with a classical microbiology antibiotic resistance profiling, one of the associated concerns in the evolution of this pathogen. On the one hand, our results are in accordance with previous studies on the epidemic structure of P. aeruginosa, as well as the existence of three main phylogroups, that are not related to environmental parameters. On the other hand, antibiotic resistance profiles indicate higher prevalence in our sample of multi drug resistant (75.15%), extremely drug resistant (17.72%) and pan-drug resistant (9.49%) than resistance reported in developed countries. It is important to reflect on the causes that make less developed countries hotspots of antibiotic resistance, considering the multifactorial aspects of the socio-political context of such countries that include, but are not restricted to, public policy implementation and enforcement regarding access to antibiotics, as well as health care personnel education and other obstacles related to poverty and unequal access to health services and information.

Increased bar minigene mRNA stability during cell growth inhibition.

Bacteriophage lambda is unable to grow vegetatively on Escherichia coli mutants defective in peptidyl-tRNA hydrolase (Pth) activity. Mutations which allow phage growth on the defective host have been located at regions named bar in the lambda genome. Expression of wild-type bar regions from plasmid constructs results in inhibition of protein synthesis and lethality to Pth-defective cells. Two of these wild-type bar regions, barI+ and barII+, contain minigenes with similar AUG-AUA-stop codon sequences preceded by different Shine-Dalgarno (SD) and spacer regions. The induced expression of barI+ and barII+ regions from plasmid constructs resulted in similar patterns of protein synthesis inhibition and cell growth arrest. Therefore, these deleterious effects may stem from translation of the transcripts containing the minigene two-codon 'ORF' (open reading frame). To test for this possibility, we assayed the effect of point mutations within the barI minigene. The results showed that a base pair substitution within the SD and the two-codon 'ORF' sequences affected protein synthesis and cell growth inhibition. In addition, mRNA stability was altered in each mutant. Higher mRNA stability correlated with the more toxic minigenes. We argue that this effect may be caused by ribosome protection of the mRNA in paused complexes as a result of deficiency of specific tRNA.

Molecular basis for the temperature sensitivity of Escherichia coli pth(Ts).

The gene pth, encoding peptidyl-tRNA hydrolase (Pth), is essential for protein synthesis and viability of Escherichia coli. Two pth mutants have been studied in depth: a pth(Ts) mutant isolated as temperature sensitive and a pth(rap) mutant selected as nonpermissive for bacteriophage lambda vegetative growth. Here we show that each mutant protein is defective in a different way. The Pth(Ts) protein was very unstable in vivo, both at 43 degrees C and at permissive temperatures, but its specific activity was comparable to that of the wild-type enzyme, Pth(wt). Conversely, the mutant Pth(rap) protein had the same stability as Pth(wt), but its specific activity was low. The thermosensitivity of the pth(Ts) mutant, presumably, ensues after Pth(Ts) protein levels are reduced at 43 degrees C. Conditions that increased the cellular Pth(Ts) concentration, a rise in gene copy number or diminished protein degradation, allowed cell growth at a nonpermissive temperature. Antibiotic-mediated inhibition of mRNA and protein synthesis, but not of peptidyl-tRNA drop-off, reduced pth(Ts) cell viability even at a permissive temperature. Based on these results, we suggest that Pth(Ts) protein, being unstable in vivo, supports cell viability only if its concentration is maintained above a threshold that allows general protein synthesis.

Inhibition of translation and cell growth by minigene expression.

A random five-codon gene library was used to isolate minigenes whose expression causes cell growth arrest. Eight different deleterious minigenes were isolated, five of which had in-frame stop codons; the predicted expressed peptides ranged in size from two to five amino acids. Mutational analysis demonstrated that translation of the inhibitory minigenes is essential for growth arrest. Pulse-labeling experiments showed that expression of at least some of the selected minigenes results in inhibition of cellular protein synthesis. Expression of the deleterious minigenes in cells deficient in peptidyl-tRNA hydrolase causes accumulation of families of peptidyl-tRNAs corresponding to the last minigene codon; the inhibitory action of minigene expression could be suppressed by overexpression of the tRNA corresponding to the last sense codon in the minigene. Experimental data are compatible with the model that the deleterious effect of minigene expression is mediated by depletion of corresponding pools of free tRNAs.

lambda bar minigene-mediated inhibition of protein synthesis involves accumulation of peptidyl-tRNA and starvation for tRNA.

Expression of the bacteriophage lambda two-codon, AUG AUA, barI minigene (bar+) leads to the arrest of protein synthesis in cells defective in peptidyl-tRNA hydrolase (Pth). It has been hypothesized that translation of the bar+ transcript provokes premature release and accumulation of peptidyl-tRNA (p-tRNA). Inhibition of protein synthesis would then result from either starvation of sequestered tRNA or from toxicity of accumulated p-tRNA. To test this hypothesis and to investigate the cause of arrest, we used a coupled in vitro transcription-translation system primed with DNA containing bar+ and the beta-lactamase-encoding gene of the vector as a reporter. The results show that expression of bar+ minigene severely inhibits beta-lactamase polypeptide synthesis by Pth-defective extracts and partially inhibits synthesis by wild-type extracts. Fractions enriched for Pth, or a homogeneous preparation of Pth, prevented and reversed bar+-mediated inhibition. A mutant minigene, barA702, which changes the second codon AUA (Ile) to AAA (Lys), was also toxic for Pth-defective cells. Expression of barA702 inhibited in vitro polypeptide synthesis by Pth-defective extracts and, as with bar+, exogenous Pth prevented inhibition. Addition of pure tRNALys prevented inhibition by barA702 but not by bar+. Expression of bar+ and barA702 led to release and accumulation of p-tRNAIle and p-tRNALys respectively but bar+ also induced accumulation of p-tRNALys. Finally, bar+ stimulated association of methionine with ribosomes probably as fMet-tRNAfMet and the accumulation of methionine and isoleucine in solution as peptidyl-tRNA (p-tRNA). These results indicate that minigene-mediated inhibition of protein synthesis involves premature release of p-tRNA, misincorporation of amino acyl-tRNA, accumulation of p-tRNAs and possibly sequestration of tRNAs.

Translational repression by a transcriptional elongation factor.

One of the classical positive regulators of gene expression is bacteriophage lambda N protein. N regulates the transcription of early phage genes by participating in the formation of a highly processive, terminator-resistant transcription complex and thereby stimulates the expression of genes lying downstream of transcriptional terminators. Also included in this antiterminating transcription complex are an RNA site (NUT) and host proteins (Nus). Here we demonstrate that N has an additional, hitherto unknown regulatory role, as a repressor of the translation of its own gene. N-dependent repression does not occur when NUT is deleted, demonstrating that N-mediated antitermination and translational repression both require the same cis-acting site in the RNA. In addition, we have identified one nut and several host mutations that eliminate antitermination and not translational repression, suggesting the independence of these two N-mediated mechanisms. Finally, the position of nutL with respect to the gene whose expression is repressed is important.

Inhibition of Escherichia coli protein synthesis by abortive translation of phage lambda minigenes.

Escherichia coli mutants defective in peptidyl-tRNA hydrolase activity are unable to maintain bacteriophage lambda vegetative growth. Phage mutants, named bar, overcome the host limitation to support viral growth. Multicopy expression of lambda wild-type bar regions is deleterious to hydrolase-defective cells because it provokes arrest of protein synthesis. We noticed that the bar regions include minigenes whose transcripts would contain a Shine-Dalgarno-like sequence appropriately spaced for translation from a two codon open reading frame. To investigate the mechanism of bar inhibition, we asked if transcripts of the barI region function as mRNAs in their ribosomal interactions. We found that bar-containing RNA associates with ribosomes, forms ternary initiation complexes, yields a toeprint signal, and can be removed from ribosomes by run-off translation, as authentic mRNA. Since bar-containing RNA has the properties of a messenger, we propose that its translation leads to drop-off and accumulation of peptidyl-tRNA in pth-defective cells. Starvation of the tRNA(s) sequestered in pepidyl-tRNA(s) eventually causes inhibition of protein synthesis.

Regulation of protein synthesis by minigene expression.

Peptidyl-tRNA hydrolase (Pth), an enzyme essential for Escherichia coli viability, scavenges peptidyl-tRNA released during abortive polypeptide chain elongation. Bacterial strains of E coli partially defective in Pth activity are unable to maintain bacteriophage lambda growth. Phage mutations that overcome the bacterial defect have been located to several regions in the lambda genome named bar. Plasmid constructs expressing just the bar region are toxic and cause a general arrest of protein synthesis in Pth-defective cells. Inspection of the nucleotide sequence from two bar regions reveals the short coding sequence AUG AUA Stop, spaced by an AT-rich segment from a Shine Dalgarno-like sequence (S-D). These sequences have been named minigenes. Base changes altering the putative S-D, the two sense codons, or the stop codon have been found to reduce Bar-toxicity. Transcripts containing bar function as mRNA. Upon expression in pth mutants, wild-type (bar+) transcripts are found associated with ribosomes. In addition, bar+ RNA forms ternary complexes with the 30S ribosomal subunit and the initiator tRNA and can be released upon run-off translation in the same way as an authentic mRNA. A cell free system for protein synthesis reproduces the in vivo effects: bar+ expression inhibits protein synthesis, bar+ RNA sequences are associated with ribosomes in the inhibited extracts, addition of purified Pth restores synthesis, and excess of tRNA(Lys), specific for the last sense codon in a mutant toxic minigene, prevents protein synthesis inhibition. Also, bar expression promotes association of methionine with ribosomes possibly in a translation complex. These results are consistent with a model proposing tRNA starvation to explain the behaviour of a pth mutant, thermosensitive for protein synthesis.

The growth defect in Escherichia coli deficient in peptidyl-tRNA hydrolase is due to starvation for Lys-tRNA(Lys).

The existence of a conditional lethal temperature-sensitive mutant affecting peptidyl-tRNA hydrolase in Escherichia coli suggests that this enzyme is essential to cell survival. We report here the isolation of both chromosomal and multicopy suppressors of this mutant in pth, the gene encoding the hydrolase. In one case, the cloned gene responsible for suppression is shown to be lysV, one of three genes encoding the unique lysine acceptor tRNA; 10 other cloned tRNA genes are without effect. Overexpression of lysV leading to a 2- to 3-fold increase in tRNA(Lys) concentration overcomes the shortage of peptidyl-tRNA hydrolase activity in the cell at non-permissive temperature. Conversely, in pth, supN double mutants, where the tRNA(Lys) concentration is reduced due to the conversion of lysV to an ochre suppressor (supN), the thermosensitivity of the initial pth mutant becomes accentuated. Thus, cells carrying both mutations show practically no growth at 39 degrees C, a temperature at which the pth mutant grows almost normally. Growth of the double mutant is restored by the expression of lysV from a plasmid. These results indicate that the limitation of growth in mutants of E.coli deficient in Pth is due to the sequestration of tRNA(Lys) as peptidyl-tRNA. This is consistent with previous observations that this tRNA is particularly prone to premature dissociation from the ribosome.

Microbial genes homologous to the peptidyl-tRNA hydrolase-encoding gene of Escherichia coli.

We have cloned and determined the nucleotide (nt) sequences of the genes encoding peptidyl-tRNA hydrolase (Pth) homologues of Salmonella typhi (St) and the Lyme disease spirochaete, Borrelia burgdorferi (Bb). We also completed the nt sequence of a pth homologous gene contained in a Chlamydia trachomatis (Ct) clone identified in the databanks. The open reading frames (ORFs) of the Pth homologues encode putative polypeptides of 194 (St), 188 (Bb) and 194 (Ct) amino acids exhibiting significant identity with Escherichia coli (Ec) Pth. Together with the products of two previously unidentified ORFs from Bacillus subtilis and Saccharomyces cerevisiae, and the recently recognized Haemophilus influenzae and Mycoplasma genitalium pth genes, these seven putative polypeptides and the Ec Pth form a group of homologous basic proteins spanning eubacteria and eukaryota which can be defined by at least three conserved regions. Previously known Ec pth mutations were located in highly conserved residues.

Open reading frames flanking the peptidyl-tRNA hydrolase-encoding gene of Escherichia coli.

The nucleotide (nt) sequences flanking the peptidyl-tRNA hydrolase-encoding gene (pth) of Escherichia coli were determined and analyzed. A coding open reading frame (ORF-3), identified just downstream from pth, had a deduced amino acid (aa) sequence homologous to a family of GTP-binding proteins. We found discrepancies between the ORF-3 sequence from a plasmid clone used in previous studies and another one derived from Kohara's phage collection. Two putative genes, ORF-4 and ORF-2, were also found upstream from pth. ORF-4 could code for a 393-aa peptide homologous to membrane-bound proteins. The nt sequence between ORF-2 and pth revealed the existence of a CAP-binding site correctly positioned to regulate the expression of ORF-2.

RNaselll activation of bacteriophage lambda N synthesis.

The bacteriophage lambda N gene product is one of the first genes expressed during phage development. N protein allows the expression of other phage genes by altering the transcription elongation process so as to prevent transcription termination. We have found that N levels may be modulated soon after induction or infection. Using N-lacZ fusions, we determined that cells containing RNaselll have at least a fourfold greater expression than cells defective for RNaselll. This effect is exerted at the post-transcriptional level. RNaselll processes an RNA stem structure in the N-leader RNA. Removal of the stem structure by deletion increases N expression and prevents further stimulation by RNaselll. The base of this stable stem is adjacent to the N ribosome binding site. We present a model for control of N synthesis in which this stable stem inhibits ribosome access to the N mRNA.

Ribosomal RNA and peptidyl-tRNA hydrolase: a peptide chain termination model for lambda bar RNA inhibition.

We propose here a model to explain the inhibition of bacteriophage lambda (lambda) vegetative growth and the killing of E coli cells defective in peptidyl-tRNA hydrolase (Pth) by lambda bar RNA. The model suggests that bar RNA, which contains a characteristic UGA triplet, base-pairs in an anti-parallel fashion with the 1199-1205 region of E coli 16S rRNA. In doing so, it prevents the required functioning of that region of 16S rRNA in UGA-specific peptide chain termination. Pth is implicated in peptide chain termination because a defect in Pth is required for the achievement of the bar RNA inhibitory effects. We make certain predictions that flow from the model, predictions involving suppression of nonsense mutations, and present preliminary experimental results that demonstrate the fulfillment of those predictions.

Peptidyl-tRNA hydrolase is involved in lambda inhibition of host protein synthesis.

Escherichia coli rap mutants do not support vegetative growth of bacteriophage lambda and die upon transcription of lambda DNA bar sites. Bacteria harbouring a pth(ts) mutation synthesize thermosensitive peptidyl-tRNA hydrolase (Pth) and die at 42 degrees C from a defect in protein synthesis. We present evidence that both rap and pth(ts) mutations affect the same gene: (i) peptidyl-tRNA hydrolase activity was found to be defective in rap mutants; (ii) at a threshold temperature, pth cells, like rap mutants, prevented lambda growth and were killed by transcription of cloned bar sites; (iii) sequencing a 1600 bp DNA fragment comprising both loci revealed an ORF located within the limits set by a complementation analysis and encoding a putative polypeptide of 21 kDa; (iv) cloning and sequencing of rap and pth(ts) mutant DNAs both revealed single nucleotide transitions from the wild type ORF sequence, resulting in Arg134 to His and Gly101 to Asp changes respectively. Analysis of plasmid-directed proteins identified a polypeptide of approximately 21 kDa; the N-terminal sequence, amino acid composition and isoelectric point of this protein match those expected from the ORF nucleotide sequence. We propose that Pth activity, directly or indirectly, is the target for lambda bar RNA leading to rap cell death.

Different specificities of ribonuclease II and polynucleotide phosphorylase in 3'mRNA decay.

We review recent evidence on the in vivo and in vitro mRNA degradation properties of 2 3'-exonucleases, ribonuclease II and polynucleotide phosphorylase. Although secondary structures in the RNA can act as protective barriers against 3' exonucleolytic degradation, it appears that this effect depends on the stability of these structures. The fact that RNase II is more sensitive to RNA secondary structure than PNPase, could account for some differences observed in messenger degradation by the 2 enzymes in vivo. Terminator stem-loop structures are often very stable and 3' exonucleolytic degradation proceeds only after they have been eliminated by an endonucleolytic cleavage. Other secondary structures preceding terminator stem-loop seem to contribute to mRNA stability against exonucleolytic decay.

A short DNA sequence from lambda phage inhibits protein synthesis in Escherichia coli rap.

The Escherichia coli rap mutant inhibits vegetative growth of bacteriophage lambda. Phage mutations termed bar, which overcome the rap defect, have been mapped to three genetic loci in the pL operon. Plasmids with a lambda wild-type bar DNA segment cloned downstream from an active promoter cannot be maintained in rap mutant bacteria. The viability of a rap mutant strain decreases rapidly after induction of transcription through bar regions present on plasmids. Under these (restrictive) conditions the expression of plasmid-encoded beta-lactamase and plasmid DNA replication are arrested, but plasmid RNA synthesis continues for several hours. Analysis of protein extracts from E. coli rap cells containing bar plasmids revealed that both plasmid and bacterial protein synthesis are inhibited under restrictive conditions. In addition, unlike other RNAs tested, the chemical half-life of bar RNA increases 3.5-fold relative to the half-life of bar RNA under permissive conditions. We propose that transcription through the bar region, or the accumulation of bar RNA, results in an irreversible defect in cellular mRNA translation. This defect eventually kills the rap cells, and thus prevents bar plasmid maintenance.

Different specificities of ribonuclease II and polynucleotide phosphorylase in 3'mRNA decay.

We review recent evidence on the in vivo and in vitro mRNA degradation properties of 2 3'-exonucleases, ribonuclease II and polynucleotide phosphorylase. Although secondary structures in the RNA can act as protective barriers against 3' exonucleolytic degradation, it appears that this effect depends on the stability of these structures. The fact that RNase II is more sensitive to RNA secondary structure than PNPase, could account for some differences observed in messenger degradation by the 2 enzymes in vivo. Terminator stem-loop structures are often very stable and 3' exonucleolytic degradation proceeds only after they have been eliminated by an endonucleolytic cleavage. Other secondary structures preceding terminator stem-loop seem to contribute to mRNA stability against exonucleolytic decay.

Transcription of a bacteriophage lambda DNA site blocks growth of Escherichia coli.

The rap mutation in Escherichia coli prevents the growth of bacteriophage lambda. Phage mutations that overcome rap inhibition (bar) have been mapped to loci in the pL operon. We cloned and sequenced three mutations in two of these loci: barIa to the left arm of the lambda attachment site (attP) and barII in the ssb (ea10) gene. The mutations represent single base-pair changes within nearly identical 16-base-pair DNA segments. Each mutation disrupts a sequence of dyad symmetry within the segment. Plasmids carrying a bar+ sequence downstream to an active promoter are lethal to rap, but not rap+, bacteria. The bar sequences isolated from the lambda bar mutants are not lethal. We synthesized a minimal lambda barIa+ sequence, 5'-TATATTGATATTTATATCATT, and cloned it downstream to an inducible promoter. When transcribed, this sequence is sufficient to kill a rap strain.

Phage genetic sites involved in lambda growth inhibition by the Escherichia coli rap mutant.

The rap mutation of Escherichia coli prevents the growth of bacteriophage lambda. We have isolated phage mutants that compensate for the host deficiency. The mutations, named bar, were genetically located to three different loci of the lambda genome: barI in the attP site, barII in the cIII ea10 region, and barIII within or very near the imm434 region. The level of lambda leftward transcription correlates with rap exclusion. Phage lambda mutants partially defective in the pL promoter or in pL-transcript antitermination showed a Bar- phenotype. Conversely, mutants constitutive for transcription from the pI or pL promoters were excluded more stringently by rap bacteria. We conclude that rap exclusion depends on the magnitude of transcription through the wild type bar loci in the phage genome.