DNA polymerase III from Escherichia coli cells expressing mutA mistranslator tRNA is error-prone

Impact of tRNA-induced proline-to-serine mistranslation on the transcriptome of Drosophila melanogaster

Mistranslation is the misincorporation of an amino acid into a polypeptide. Mistranslation has diverse effects on multicellular eukaryotes and is implicated in several human diseases. In Drosophila melanogaster, a serine transfer RNA (tRNA) that misincorporates serine at proline codons (P→S) affects male and female flies differently. The mechanisms behind this discrepancy are currently unknown. Here, we compare the transcriptional response of male and female flies to P→S mistranslation to identify genes and cellular processes that underlie sex-specific differences. Both males and females downregulate genes associated with various metabolic processes in response to P→S mistranslation. Males downregulate genes associated with extracellular matrix organization and response to negative stimuli such as wounding, whereas females downregulate aerobic respiration and ATP synthesis genes. Both sexes upregulate genes associated with gametogenesis, but females also upregulate cell cycle and DNA repair genes. These observed differences in the transcriptional response of male and female flies to P→S mistranslation have important implications for the sex-specific impact of mistranslation on disease and tRNA therapeutics.

Impact of tRNA-induced proline-to-serine mistranslation on the transcriptome of Drosophila melanogaster

Mistranslation is the misincorporation of an amino acid into a polypeptide. Mistranslation has diverse effects on multicellular eukaryotes and is implicated in several human diseases. In Drosophila melanogaster, a serine transfer RNA (tRNA) that misincorporates serine at proline codons (P→S) affects male and female flies differently. The mechanisms behind this discrepancy are currently unknown. Here, we compare the transcriptional response of male and female flies to P→S mistranslation to identify genes and cellular processes that underlie sex-specific differences. Both males and females downregulate genes associated with various metabolic processes in response to P→S mistranslation. Males downregulate genes associated with extracellular matrix organization and response to negative stimuli such as wounding, whereas females downregulate aerobic respiration and ATP synthesis genes. Both sexes upregulate genes associated with gametogenesis, but females also upregulate cell cycle and DNA repair genes. These observed differences in the transcriptional response of male and female flies to P→S mistranslation have important implications for the sex-specific impact of mistranslation on disease and tRNA therapeutics.

Adaptive resistance mutations at supra-inhibitory concentrations independent of SOS mutagenesis

Emergence of resistant bacteria during antimicrobial treatment is one of the most critical and universal health threats. It is known that several stress-induced mutagenesis and heteroresistance mechanisms can enhance microbial adaptation to antibiotics. Here, we demonstrate that the pathogen Bartonella can undergo stress-induced mutagenesis despite the fact it lacks error-prone polymerases, the rpoS gene and functional UV-induced mutagenesis. We demonstrate that Bartonella acquire de novo single mutations during rifampicin exposure at suprainhibitory concentrations at a much higher rate than expected from spontaneous fluctuations. This is while exhibiting a minimal heteroresistance capacity. The emerged resistant mutants acquired a single rpoB mutation, whereas no other mutations were found in their whole genome. Interestingly, the emergence of resistance in Bartonella occurred only during gradual exposure to the antibiotic, indicating that Bartonella sense and react to the changing environment. Using a mathematical model, we demonstrated that, to reproduce the experimental results, mutation rates should be transiently increased over 1,000-folds, and a larger population size or greater heteroresistance capacity is required. RNA expression analysis suggests that the increased mutation rate is due to downregulation of key DNA repair genes (mutS, mutY, and recA), associated with DNA breaks caused by massive prophage inductions. These results provide new evidence of the hazard of antibiotic overuse in medicine and agriculture.

The Promiscuous sumA Missense Suppressor from Salmonella enterica Has an Intriguing Mechanism of Action

While most missense suppressors have very narrow specificities and only suppress the allele against which they were isolated, the sumA missense suppressor from Salmonella enterica serovar Typhimurium is a promiscuous or broad-acting missense suppressor that suppresses numerous missense mutants. The sumA missense suppressor was identified as a glyV tRNA Gly3(GAU/C) missense suppressor that can recognize GAU or GAC aspartic acid codons and insert a glycine amino acid instead of aspartic acid. In addition to rescuing missense mutants caused by glycine to aspartic acid changes as expected, sumA could also rescue a number of other missense mutants as well by changing a neighboring (contacting) aspartic acid to glycine, which compensated for the other amino acid change. Thus the ability of sumA to rescue numerous missense mutants was due in part to the large number of glycine codons in genes that can be mutated to an aspartic acid codon and in part to the general tolerability and/or preference for glycine amino acids in proteins. Because the glyV tRNA Gly3(GAU/C) missense suppressor has also been extensively characterized in Escherichia coli as the mutA mutator, we demonstrated that all gain-of-function mutants isolated in a glyV tRNA Gly3(GAU/C) missense suppressor are transferable to a wild-type background and thus the increased mutation rates, which occur in glyV tRNA Gly3(GAU/C) missense suppressors, are not due to the suppression of these mutants.

Stress-Induced Mutagenesis

Early research on the origins and mechanisms of mutation led to the establishment of the dogma that, in the absence of external forces, spontaneous mutation rates are constant. However, recent results from a variety of experimental systems suggest that mutation rates can increase in response to selective pressures. This chapter summarizes data demonstrating that,under stressful conditions, Escherichia coli and Salmonella can increase the likelihood of beneficial mutations by modulating their potential for genetic change.Several experimental systems used to study stress-induced mutagenesis are discussed, with special emphasison the Foster-Cairns system for "adaptive mutation" in E. coli and Salmonella. Examples from other model systems are given to illustrate that stress-induced mutagenesis is a natural and general phenomenon that is not confined to enteric bacteria. Finally, some of the controversy in the field of stress-induced mutagenesis is summarized and discussed, and a perspective on the current state of the field is provided.

Potential roles for DNA replication and repair functions in cell killing by streptomycin

The aminoglycoside streptomycin binds to ribosomes to promote mistranslation and eventual inhibition of translation. Streptomycin kills bacteria, whereas many other non-aminoglycoside inhibitors of translation do not. Because mistranslation is now known to affect DNA replication, we asked if hydroxyurea, a specific inhibitor of DNA synthesis, affects killing, and find that hydroxyurea significantly attenuates killing by streptomycin. We find that the hydroxyl radical scavengers d-mannitol and thiourea have either no effect or only a modest protective effect. The iron chelator 2,2'-dipyridyl eliminated killing by streptomycin, but further investigation revealed that it blocks streptomycin uptake. Prior treatment of cells with low-levels of methyl methanesulfonate to induce the adaptive response to alkylation leads to a significant attenuation of killing, which, together with the hydroxyurea effect, suggests roles for DNA replication and repair functions in cell killing by streptomycin.

Culture history and population heterogeneity as determinants of bacterial adaptation: the adaptomics of a single environmental transition

Diversity in adaptive responses is common within species and populations, especially when the heterogeneity of the frequently large populations found in environments is considered. By focusing on events in a single clonal population undergoing a single transition, we discuss how environmental cues and changes in growth rate initiate a multiplicity of adaptive pathways. Adaptation is a comprehensive process, and stochastic, regulatory, epigenetic, and mutational changes can contribute to fitness and overlap in timing and frequency. We identify culture history as a major determinant of both regulatory adaptations and microevolutionary change. Population history before a transition determines heterogeneities due to errors in translation, stochastic differences in regulation, the presence of aged, damaged, cheating, or dormant cells, and variations in intracellular metabolite or regulator concentrations. It matters whether bacteria come from dense, slow-growing, stressed, or structured states. Genotypic adaptations are history dependent due to variations in mutation supply, contingency gene changes, phase variation, lateral gene transfer, and genome amplifications. Phenotypic adaptations underpin genotypic changes in situations such as stress-induced mutagenesis or prophage induction or in biofilms to give a continuum of adaptive possibilities. Evolutionary selection additionally provides diverse adaptive outcomes in a single transition and generally does not result in single fitter types. The totality of heterogeneities in an adapting population increases the chance that at least some individuals meet immediate or future challenges. However, heterogeneity complicates the adaptomics of single transitions, and we propose that subpopulations will need to be integrated into future population biology and systems biology predictions of bacterial behavior.

Low level genome mistranslations deregulate the transcriptome and translatome and generate proteotoxic stress in yeast

Background

Organisms use highly accurate molecular processes to transcribe their genes and a variety of mRNA quality control and ribosome proofreading mechanisms to maintain intact the fidelity of genetic information flow. Despite this, low level gene translational errors induced by mutations and environmental factors cause neurodegeneration and premature death in mice and mitochondrial disorders in humans. Paradoxically, such errors can generate advantageous phenotypic diversity in fungi and bacteria through poorly understood molecular processes.

Results

In order to clarify the biological relevance of gene translational errors we have engineered codon misreading in yeast and used profiling of total and polysome-associated mRNAs, molecular and biochemical tools to characterize the recombinant cells. We demonstrate here that gene translational errors, which have negligible impact on yeast growth rate down-regulate protein synthesis, activate the unfolded protein response and environmental stress response pathways, and down-regulate chaperones linked to ribosomes.

Conclusions

We provide the first global view of transcriptional and post-transcriptional responses to global gene translational errors and we postulate that they cause gradual cell degeneration through synergistic effects of overloading protein quality control systems and deregulation of protein synthesis, but generate adaptive phenotypes in unicellular organisms through activation of stress cross-protection. We conclude that these genome wide gene translational infidelities can be degenerative or adaptive depending on cellular context and physiological condition.

Genetic code ambiguity: an unexpected source of proteome innovation and phenotypic diversity

Translation of the genome into the proteome is a highly accurate biological process. However, the molecular mechanisms involved in protein synthesis are not error free and downstream protein quality control systems are needed to counteract the negative effects of translational errors (mistranslation) on proteome and cell homeostasis. This plus human and mice diseases caused by translational error generalized the idea that codon ambiguity is detrimental to life. Here we depart from this classical view of deleterious translational error and highlight how codon ambiguity can play important roles in the evolution of novel proteins. We also explain how tRNA mischarging can be relevant for the synthesis of functional proteomes, how codon ambiguity generates phenotypic and genetic diversity and how advantageous phenotypes can be selected, fixed, and inherited. A brief introduction to the molecular nature of translational error is provided; however, detailed information on the mechanistic aspects of mistranslation or comprehensive literature reviews of this topic should be obtained elsewhere.

Stress-induced mutagenesis in bacteria

Bacteria spend their lives buffeted by changing environmental conditions. To adapt to and survive these stresses, bacteria have global response systems that result in sweeping changes in gene expression and cellular metabolism. These responses are controlled by master regulators, which include: alternative sigma factors, such as RpoS and RpoH; small molecule effectors, such as ppGpp; gene repressors such as LexA; and, inorganic molecules, such as polyphosphate. The response pathways extensively overlap and are induced to various extents by the same environmental stresses. These stresses include nutritional deprivation, DNA damage, temperature shift, and exposure to antibiotics. All of these global stress responses include functions that can increase genetic variability. In particular, up-regulation and activation of error-prone DNA polymerases, down-regulation of error-correcting enzymes, and movement of mobile genetic elements are common features of several stress responses. The result is that under a variety of stressful conditions, bacteria are induced for genetic change. This transient mutator state may be important for adaptive evolution.

Critical roles for a genetic code alteration in the evolution of the genus Candida

During the last 30 years, several alterations to the standard genetic code have been discovered in various bacterial and eukaryotic species. Sense and nonsense codons have been reassigned or reprogrammed to expand the genetic code to selenocysteine and pyrrolysine. These discoveries highlight unexpected flexibility in the genetic code, but do not elucidate how the organisms survived the proteome chaos generated by codon identity redefinition. In order to shed new light on this question, we have reconstructed a Candida genetic code alteration in Saccharomyces cerevisiae and used a combination of DNA microarrays, proteomics and genetics approaches to evaluate its impact on gene expression, adaptation and sexual reproduction. This genetic manipulation blocked mating, locked yeast in a diploid state, remodelled gene expression and created stress cross-protection that generated adaptive advantages under environmental challenging conditions. This study highlights unanticipated roles for codon identity redefinition during the evolution of the genus Candida, and strongly suggests that genetic code alterations create genetic barriers that speed up speciation.

Hypermutagenesis in mutA cells is mediated by mistranslational corruption of polymerase, and is accompanied by replication fork collapse

Elevated mistranslation induces a mutator response termed translational stress-induced mutagenesis (TSM) that is mediated by an unidentified modification of DNA polymerase III. Here we address two questions: (i) does TSM result from direct polymerase corruption, or from an indirect pathway triggered by increased protein turnover? (ii) Why are homologous recombination functions required for the expression of TSM under certain conditions, but not others? We show that replication of bacteriophage T4 in cells expressing the mutA allele of the glyVtRNA gene (Asp-Gly mistranslation), leads to both increased mutagenesis, and to an altered mutational specificity, results that strongly support mistranslational corruption of DNA polymerase. We also show that expression of mutA, which confers a recA-dependent mutator phenotype, leads to increased lambdoid prophage induction (selectable in vivo expression technology assay), suggesting that replication fork collapse occurs more frequently in mutA cells relative to control cells. No such increase in prophage induction is seen in cells expressing alaVGlu tRNA (Glu-->Ala mistranslation), in which the mutator phenotype is recA-independent. We propose that replication fork collapse accompanies episodic hypermutagenic replication cycles in mutA cells, requiring homologous recombination functions for fork recovery, and therefore, for mutation recovery. These findings highlight hitherto under-appreciated links among translation, replication and recombination, and suggest that translational fidelity, which is affected by genetic and environmental signals, is a key modulator of replication fidelity.

Elevated expression of DNA polymerase II increases spontaneous mutagenesis in Escherichia coli

Escherichia coli DNA polymerase II (Pol-II), encoded by the SOS-regulated polB gene, belongs to the highly conserved group B (alpha-like) family of "high-fidelity" DNA polymerases. Elevated expression of polB gene was recently shown to result in a significant elevation of translesion DNA synthesis at 3, N(4)-ethenocytosine lesion with concomitant increase in mutagenesis. Here, I show that elevated expression of Pol-II leads to an approximately 100-fold increase in spontaneous mutagenesis in a manner that is independent of SOS, umuDC, dinB, recA, uvrA and mutS functions. Cells grow slowly and filament with elevated expression of Pol-II. Introduction of carboxy terminus ("beta interaction domain") mutations in polB eliminates elevated spontaneous mutagenesis, as well as defects in cell growth and morphology, suggesting that these abilities require the interaction of Pol-II with the beta processivity subunit of DNA polymerase III. Introduction of a mutation in the proofreading exo motif of polB elevates mutagenesis by a further 180-fold, suggesting that Pol-II can effectively compete with DNA polymerase III for DNA synthesis. Thus, Pol-II can contribute to spontaneous mutagenesis when its expression is elevated.

An editing-defective aminoacyl-tRNA synthetase is mutagenic in aging bacteria via the SOS response

Mistranslation in bacterial and mammalian cells leads to production of statistical proteins that are, in turn, associated with specific cell or animal pathologies, including death of bacterial cells, apoptosis of mammalian cells in culture, and neurodegeneration in the mouse. A major source of mistranslation comes from heritable defects in the editing activities of aminoacyl-tRNA synthetases. These activities clear errors of aminoacylation by deacylation of mischarged tRNAs. We hypothesized that, in addition to previously reported phenotypes in bacterial and mammalian systems, errors of aminoacylation could be mutagenic and lead to disease. As a first step in testing this hypothesis, the effect of an editing defect in a single tRNA synthetase on the accumulation of mutations in aging bacteria was investigated. A striking, statistically significant, enhancement of the mutation rate in aging bacteria was found. This enhancement comes from an increase in error-prone DNA repair through induction of the bacterial SOS response. Thus, mistranslation, as caused by an editing-defective tRNA synthetase, can lead to heritable genetic changes that could, in principle, be linked to disease.

RecB-dependent mutator phenotype in Neisseria meningitidis strains naturally defective in mismatch repair

Several invasive serogroup B meningococcal strains phylogenetically related to the lineage III (ET-24) exhibited a mutator phenotype as shown by mutagenicity assay using rifampicin-resistance as a selection marker. Hypermutation was associated to the presence of defective mutL alleles that were genetically characterized. Interestingly, the mutator phenotype was suppressed when a non-functional recB(ET-37) allele, derived from ET-37 meningococcal strains, replaced the functional recB allele in a lineage III strain. In contrast, the same gene replacement did not affect mutation frequencies in a mismatch repair-proficient strain. These results suggested that in MutL-deficient strains spontaneous mutations mostly arise from post-replicative DNA synthesis associated to the activity of the RecBCD recombination pathway.

Mistranslation and genetic variability: the effect of streptomycin

Streptomycin is an aminoglycoside antibiotic that acts at the level of protein synthesis. Exposure to sublethal concentrations of this antibiotic increased significantly the number of Arg+ mutants derived from an Escherichia coli argE3 (ochre) rpsL31 (streptomycin-resistant) strain. The vast majority of these mutants appeared on selective minimal medium plates with streptomycin (200 micro g/ml) during stationary phase, after 6-10 days incubation at 37 degrees C. Derivative mutD5 or mutL or mutS mutants, carrying a faulty epsilon subunit of DNA polymerase or a defective mismatch DNA-repair protein, respectively, also showed higher numbers of Arg+ mutants on selective medium with streptomycin than on medium without streptomycin. Interestingly, with these DNA-repair mutants about 50% of the Arg+ mutants generated in the presence of streptomycin appeared during the first 5 days of incubation. These observations suggest that the activities of these fidelity-repair proteins prevent in the parental strain the early appearance of the supernumerary Arg+ mutants on the selective medium with streptomycin. The appearance of Arg+ mutants on the plates with streptomycin was not significantly altered by recA, rpoS or dps mutations. A high percentage of the Arg+ mutants arising in the presence of streptomycin were streptomycin-dependent for growth without arginine (Arg+ St-D). These types of mutants displayed a Ram (for ribosomal ambiguity) phenotype, manifested by increased misreading, assayed by in vitro and in vivo experiments and by leakiness on several selective minimal media. Genetic data indicated that these mutants carry a mutation located at about 74 min of the E.coli map that relieves the high translational fidelity conferred by the rpsL mutation. These studies suggest that the growth-limiting conditions of the assay system used, as well as the presence of streptomycin, which causes an increased production of altered proteins, favours the appearance and growth of compensatory Arg+ mutants.

Escherichia coli DNA polymerase II can efficiently bypass 3,N(4)-ethenocytosine lesions in vitro and in vivo

Escherichia coli DNA polymerase II (pol-II) is a highly conserved protein that appears to have a role in replication restart, as well as in translesion synthesis across specific DNA adducts under some conditions. Here, we have investigated the effects of elevated expression of pol-II (without concomitant SOS induction) on translesion DNA synthesis and mutagenesis at 3,N(4)-ethenocytosine (varepsilonC), a highly mutagenic DNA lesion induced by oxidative stress as well as by exposure to industrial chemicals such as vinyl chloride. In normal cells, survival of transfected M13 single-stranded DNA bearing a single varepsilonC residue (varepsilonC-ssDNA) is about 20% of that of control DNA, with about 5% of the progeny phage bearing a mutation at the lesion site. Most mutations are C-->A and C-->T, with a slight predominance of transversions over transitions. In contrast, in cells expressing elevated levels of pol-II, survival of varepsilonC-ssDNA is close to 100%, with a concomitant mutation frequency of almost 99% suggesting highly efficient translesion DNA synthesis. Furthermore, an overwhelming majority of mutations at varepsilonC are C-->T transitions. Purified pol-II efficiently catalyzes translesion synthesis at varepsilonC in vitro, accompanied by high levels of mutagenesis with the same specificity. These results suggest that the observed in vivo effects in pol-II over-expressing cells are due to pol-II-mediated DNA synthesis. Introduction of mutations in the carboxy terminus region (beta interaction domain) of polB eliminates in vivo translesion synthesis at varepsilonC, suggesting that the ability of pol-II to compete with pol-III requires interaction with the beta processivity subunit of pol-III. Thus, pol-II can compete with pol-III for translesion synthesis.

Specificity of spontaneous mutations induced in mutA mutator cells

Escherichia coli cells expressing the mutA allele of a glyV (glycine tRNA) gene express a strong mutator phenotype. The mutA allele differs from the wild type glyV gene by a base substitution in the anticodon such that the resulting tRNA misreads certain aspartate codons as glycine, resulting in random, low-level Asp-->Gly substitutions in proteins. Subsequent work showed that many types of mistranslation can lead to a very similar phenotype, named TSM for translational stress-induced mutagenesis. Here, we have determined the specificity of forward mutations occurring in the lacI gene in mutA cells as well as in wild type cells. Our results show that in comparison to wild type cells, base substitutions are elevated 23-fold in mutA cells, as against a eight-fold increase in insertions and a five-fold increase in deletions. Among base substitutions, transitions are elevated 13-fold, with both G:C-->A:T and A:T-->G:C mutations showing roughly similar increases. Transversions are elevated 35-fold, with G:C-->T:A, G:C-->C:G and A:T-->C:G elevated 28-, 13- and 27-fold, respectively. A:T-->T:A mutations increase a striking 348-fold over parental cells, with most occurring at two hotspot sequences that share the G:C-rich sequence 5'-CCGCGTGG. The increase in transversion mutations is similar to that observed in cells defective for dnaQ, the gene encoding the proofreading function of DNA polymerase III. In particular, the relative proportions and sites of occurrence of A:T-->T:A transversions are similar in mutA and mutD5 (an allele of dnaQ) cells. Interestingly, transversions are also the predominant base substitutions induced in dnaE173 cells in which a missense mutation in the alpha subunit of polymerase III abolishes proofreading without affecting the 3'-->5' exonuclease activity of the epsilon subunit.

Error-prone DNA polymerases: when making a mistake is the only way to get ahead

Cells have high-fidelity polymerases whose task is to accurately replicate the genome, and low-fidelity polymerases with specialized functions. Although some of these low-fidelity polymerases are exceptional in their ability to replicate damaged DNA and restore the undamaged sequence, they are error prone on undamaged DNA. In fact, these error-prone polymerases are sometimes used in circumstances where the capacity to make errors has a selective advantage. The mutagenic potential of the error-prone polymerases requires that their expression, activity, and access to undamaged DNA templates be regulated. Here we review these specialized polymerases with an emphasis on their biological roles.

Driving change: the evolution of alternative genetic codes

Pioneering studies in the 1960s that elucidated the genetic code suggested that all extant forms of life use the same genetic code. This early presumption has subsequently been challenged by the discovery of deviations of the universal genetic code in prokaryotes, eukaryotic nuclear genomes and mitochondrial genomes. These studies have revealed that the genetic code is still evolving despite strong negative forces working against the fixation of mutations that result in codon reassignment. Recent data from in vitro, in vivo and in silico comparative genomics studies are revealing significant, previously overlooked links between modified nucleosides in tRNAs, genetic code ambiguity, genome base composition, codon usage and codon reassignment.

Escherichia coli cells bearing a ribosomal ambiguity mutation in rpsD have a mutator phenotype that correlates with increased mistranslation

Escherichia coli cells bearing certain mutations in rpsD (coding for the 30S ribosomal protein S4) show a ribosomal ambiguity (Ram) phenotype characterized by increased translational error rates. Here we show that spontaneous mutagenesis increases in Ram cells bearing the rpsD14 allele, suggesting that the recently described translational stress-induced mutagenesis pathway is activated in Ram cells.