Your search keyword '"Pál C"' showing total 13 results

1. Plasticity and Stereotypic Rewiring of the Transcriptome Upon Bacterial Evolution of Antibiotic Resistance.

Author

Grézal G, Spohn R, Méhi O, Dunai A, Lázár V, Bálint B, Nagy I, Pál C, and Papp B

Subjects

Microbial Sensitivity Tests, Drug Resistance, Microbial genetics, Escherichia coli genetics, Escherichia coli metabolism, Bacteria genetics, Drug Resistance, Bacterial genetics, Transcriptome, Anti-Bacterial Agents pharmacology

Abstract

Bacterial evolution of antibiotic resistance frequently has deleterious side effects on microbial growth, virulence, and susceptibility to other antimicrobial agents. However, it is unclear how these trade-offs could be utilized for manipulating antibiotic resistance in the clinic, not least because the underlying molecular mechanisms are poorly understood. Using laboratory evolution, we demonstrate that clinically relevant resistance mutations in Escherichia coli constitutively rewire a large fraction of the transcriptome in a repeatable and stereotypic manner. Strikingly, lineages adapted to functionally distinct antibiotics and having no resistance mutations in common show a wide range of parallel gene expression changes that alter oxidative stress response, iron homeostasis, and the composition of the bacterial outer membrane and cell surface. These common physiological alterations are associated with changes in cell morphology and enhanced sensitivity to antimicrobial peptides. Finally, the constitutive transcriptomic changes induced by resistance mutations are largely distinct from those induced by antibiotic stresses in the wild type. This indicates a limited role for genetic assimilation of the induced antibiotic stress response during resistance evolution. Our work suggests that diverse resistance mutations converge on similar global transcriptomic states that shape genetic susceptibility to antimicrobial compounds., (© The Author(s) 2023. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.)

Published

2023

2. Corrigendum to: Limited evolutionary conservation of multidrug resistance and collateral sensitivity.

Author

Apjok G, Boross G, Nyerges Á, Fekete G, Lázár V, Papp B, Pál C, and Csörgő B

Published

2021

3. Suboptimal Global Transcriptional Response Increases the Harmful Effects of Loss-of-Function Mutations.

Author

Kovács K, Farkas Z, Bajić D, Kalapis D, Daraba A, Almási K, Kintses B, Bódi Z, Notebaart RA, Poyatos JF, Kemmeren P, Holstege FCP, Pál C, and Papp B

Subjects

Gene Deletion, Saccharomyces cerevisiae, Transcriptome, Gene Expression Regulation, Fungal, Loss of Function Mutation

Abstract

The fitness impact of loss-of-function mutations is generally assumed to reflect the loss of specific molecular functions associated with the perturbed gene. Here, we propose that rewiring of the transcriptome upon deleterious gene inactivation is frequently nonspecific and mimics stereotypic responses to external environmental change. Consequently, transcriptional response to gene deletion could be suboptimal and incur an extra fitness cost. Analysis of the transcriptomes of ∼1,500 single-gene deletion Saccharomyces cerevisiae strains supported this scenario. First, most transcriptomic changes are not specific to the deleted gene but are rather triggered by perturbations in functionally diverse genes. Second, gene deletions that alter the expression of dosage-sensitive genes are especially harmful. Third, by elevating the expression level of downregulated genes, we could experimentally mitigate the fitness defect of gene deletions. Our work shows that rewiring of genomic expression upon gene inactivation shapes the harmful effects of mutations., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2021

4. Limited Evolutionary Conservation of the Phenotypic Effects of Antibiotic Resistance Mutations.

Author

Apjok G, Boross G, Nyerges Á, Fekete G, Lázár V, Papp B, Pál C, and Csörgő B

Subjects

ATP-Binding Cassette Transporters genetics, Escherichia coli, Escherichia coli Proteins genetics, Genetic Fitness, Mutation, Potassium Channels genetics, Salmonella enterica, Species Specificity, Biological Evolution, Drug Resistance, Bacterial genetics

Abstract

Multidrug-resistant clinical isolates are common in certain pathogens, but rare in others. This pattern may be due to the fact that mutations shaping resistance have species-specific effects. To investigate this issue, we transferred a range of resistance-conferring mutations and a full resistance gene into Escherichia coli and closely related bacteria. We found that resistance mutations in one bacterial species frequently provide no resistance, in fact even yielding drug hypersensitivity in close relatives. In depth analysis of a key gene involved in aminoglycoside resistance (trkH) indicated that preexisting mutations in other genes-intergenic epistasis-underlie such extreme differences in mutational effects between species. Finally, reconstruction of adaptive landscapes under multiple antibiotic stresses revealed that mutations frequently provide multidrug resistance or elevated drug susceptibility (i.e., collateral sensitivity) only with certain combinations of other resistance mutations. We conclude that resistance and collateral sensitivity are contingent upon the genetic makeup of the bacterial population, and such contingency could shape the long-term fate of resistant bacteria. These results underlie the importance of species-specific treatment strategies., (© The Author(s) 2019. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2019

5. CRISPR-interference-based modulation of mobile genetic elements in bacteria.

Author

Nyerges Á, Bálint B, Cseklye J, Nagy I, Pál C, and Fehér T

Abstract

Spontaneous mutagenesis of synthetic genetic constructs by mobile genetic elements frequently results in the rapid loss of engineered functions. Previous efforts to minimize such mutations required the exceedingly time-consuming manipulation of bacterial chromosomes and the complete removal of insertional sequences (ISes). To this aim, we developed a single plasmid-based system (pCRIS) that applies CRISPR-interference to inhibit the transposition of bacterial ISes. pCRIS expresses multiple guide RNAs to direct inactivated Cas9 (dCas9) to simultaneously silence IS 1 , IS 3 , IS 5 and IS 150 at up to 38 chromosomal loci in Escherichia coli , in vivo . As a result, the transposition rate of all four targeted ISes dropped to negligible levels at both chromosomal and episomal targets. Most notably, pCRIS, while requiring only a single plasmid delivery performed within a single day, provided a reduction of IS-mobility comparable to that seen in genome-scale chromosome engineering projects. The fitness cost of multiple IS-knockdown, detectable in flask-and-shaker systems was readily outweighed by the less frequent inactivation of the transgene, as observed in green fluorescent protein (GFP)-overexpression experiments. In addition, global transcriptomics analysis revealed only minute alterations in the expression of untargeted genes. Finally, the transposition-silencing effect of pCRIS was easily transferable across multiple E. coli strains. The plasticity and robustness of our IS-silencing system make it a promising tool to stabilize bacterial genomes for synthetic biology and industrial biotechnology applications.

Published

2019

6. Indispensability of Horizontally Transferred Genes and Its Impact on Bacterial Genome Streamlining.

Author

Karcagi I, Draskovits G, Umenhoffer K, Fekete G, Kovács K, Méhi O, Balikó G, Szappanos B, Györfy Z, Fehér T, Bogos B, Blattner FR, Pál C, Pósfai G, and Papp B

Subjects

Biological Evolution, Escherichia coli genetics, Evolution, Molecular, Genes, Bacterial, Phylogeny, Gene Transfer, Horizontal, Genome Size, Genome, Bacterial

Abstract

Why are certain bacterial genomes so small and compact? The adaptive genome streamlining hypothesis posits that selection acts to reduce genome size because of the metabolic burden of replicating DNA. To reveal the impact of genome streamlining on cellular traits, we reduced the Escherichia coli genome by up to 20% by deleting regions which have been repeatedly subjects of horizontal transfer in nature. Unexpectedly, horizontally transferred genes not only confer utilization of specific nutrients and elevate tolerance to stresses, but also allow efficient usage of resources to build new cells, and hence influence fitness in routine and stressful environments alike. Genome reduction affected fitness not only by gene loss, but also by induction of a general stress response. Finally, we failed to find evidence that the advantage of smaller genomes would be due to a reduced metabolic burden of replicating DNA or a link with smaller cell size. We conclude that as the potential energetic benefit gained by deletion of short genomic segments is vanishingly small compared with the deleterious side effects of these deletions, selection for reduced DNA synthesis costs is unlikely to shape the evolution of small genomes., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2016

7. Perturbation of iron homeostasis promotes the evolution of antibiotic resistance.

Author

Méhi O, Bogos B, Csörgő B, Pál F, Nyerges A, Papp B, and Pál C

Subjects

Escherichia coli K12 drug effects, Evolution, Molecular, Gene Expression Profiling, Gene Expression Regulation, Bacterial drug effects, Homeostasis, Mutagenesis, Oxidative Stress, Anti-Bacterial Agents pharmacology, Bacterial Proteins genetics, Ciprofloxacin pharmacology, Drug Resistance, Bacterial, Escherichia coli K12 genetics, Iron metabolism, Repressor Proteins genetics

Abstract

Evolution of antibiotic resistance in microbes is frequently achieved by acquisition of spontaneous mutations during antimicrobial therapy. Here, we demonstrate that inactivation of a central transcriptional regulator of iron homeostasis (Fur) facilitates laboratory evolution of ciprofloxacin resistance in Escherichia coli. To decipher the underlying molecular mechanisms, we first performed a global transcriptome analysis and demonstrated that the set of genes regulated by Fur changes substantially in response to antibiotic treatment. We hypothesized that the impact of Fur on evolvability under antibiotic pressure is due to the elevated intracellular concentration of free iron and the consequent enhancement of oxidative damage-induced mutagenesis. In agreement with expectations, overexpression of iron storage proteins, inhibition of iron transport, or anaerobic conditions drastically suppressed the evolution of resistance, whereas inhibition of the SOS response-mediated mutagenesis had only a minor effect. Finally, we provide evidence that a cell permeable iron chelator inhibits the evolution of resistance. In sum, our work revealed the central role of iron metabolism in the de novo evolution of antibiotic resistance, a pattern that could influence the development of novel antimicrobial strategies., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2014

8. Conditional DNA repair mutants enable highly precise genome engineering.

Author

Nyerges Á, Csorgő B, Nagy I, Latinovics D, Szamecz B, Pósfai G, and Pál C

Subjects

Adenosine Triphosphatases genetics, Alleles, Escherichia coli genetics, Escherichia coli Proteins genetics, MutL Proteins, MutS DNA Mismatch-Binding Protein genetics, Oligodeoxyribonucleotides, Temperature, DNA Mismatch Repair, Genetic Engineering methods, Genome, Bacterial, Mutation

Abstract

Oligonucleotide-mediated multiplex genome engineering is an important tool for bacterial genome editing. The efficient application of this technique requires the inactivation of the endogenous methyl-directed mismatch repair system that in turn leads to a drastically elevated genomic mutation rate and the consequent accumulation of undesired off-target mutations. Here, we present a novel strategy for mismatch repair evasion using temperature-sensitive DNA repair mutants and temporal inactivation of the mismatch repair protein complex in Escherichia coli. Our method relies on the transient suppression of DNA repair during mismatch carrying oligonucleotide integration. Using temperature-sensitive control of methyl-directed mismatch repair protein activity during multiplex genome engineering, we reduced the number of off-target mutations by 85%, concurrently maintaining highly efficient and unbiased allelic replacement.

Published

2014

9. Competition between transposable elements and mutator genes in bacteria.

Author

Fehér T, Bogos B, Méhi O, Fekete G, Csörgo B, Kovács K, Pósfai G, Papp B, Hurst LD, and Pál C

Subjects

DNA Mismatch Repair genetics, Escherichia coli growth & development, Evolution, Molecular, Genetic Fitness, Genotype, Host-Pathogen Interactions genetics, Mutagenesis, Insertional genetics, Operon genetics, DNA Transposable Elements genetics, Escherichia coli genetics, Genes, Bacterial genetics, Mutation genetics, Mutation Rate

Abstract

Although both genotypes with elevated mutation rate (mutators) and mobilization of insertion sequence (IS) elements have substantial impact on genome diversification, their potential interactions are unknown. Moreover, the evolutionary forces driving gradual accumulation of these elements are unclear: Do these elements spread in an initially transposon-free bacterial genome as they enable rapid adaptive evolution? To address these issues, we inserted an active IS1 element into a reduced Escherichia coli genome devoid of all other mobile DNA. Evolutionary laboratory experiments revealed that IS elements increase mutational supply and occasionally generate variants with especially large phenotypic effects. However, their impact on adaptive evolution is small compared with mismatch repair mutator alleles, and hence, the latter impede the spread of IS-carrying strains. Given their ubiquity in natural populations, such mutator alleles could limit early phase of IS element evolution in a new bacterial host. More generally, our work demonstrates the existence of an evolutionary conflict between mutation-promoting mechanisms.

Published

2012

10. Integration of horizontally transferred genes into regulatory interaction networks takes many million years.

Author

Lercher MJ and Pál C

Subjects

Phylogeny, Escherichia coli genetics, Escherichia coli Proteins genetics, Evolution, Molecular, Gene Transfer, Horizontal, Genome, Bacterial

Abstract

Adaptation of bacteria to new or changing environments is often associated with the uptake of foreign genes through horizontal gene transfer. However, it has remained unclear how (and how fast) new genes are integrated into their host's cellular networks. Combining the regulatory and protein interaction networks of Escherichia coli with comparative genomics tools, we provide the first systematic analysis of this issue. Genes transferred recently have fewer interaction partners compared to nontransferred genes in both regulatory and protein interaction networks. Thus, horizontally transferred genes involved in complex regulatory and protein-protein interactions are rarely favored by selection. Only few protein-protein interactions are gained after the initial integration of genes following the transfer event. In contrast, transferred genes are gradually integrated into the regulatory network of their host over evolutionary time. During adaptation to the host cellular environment, horizontally transferred genes recruit existing transcription factors of the host, reflected in the fast evolutionary rates of the cis-regulatory regions of transferred genes. Further, genes resulting from increasingly ancient transfer events show increasing numbers of transcriptional regulators as well as improved coregulation with interacting proteins. Fine-tuned integration of horizontally transferred genes into the regulatory network spans more than 8-22 million years and encompasses accelerated evolution of regulatory regions, stabilization of protein-protein interactions, and changes in codon usage.

Published

2008

11. Horizontal gene transfer depends on gene content of the host.

Author

Pál C, Papp B, and Lercher MJ

Subjects

Genetic Variation genetics, Genome, Bacterial genetics, Base Composition genetics, Chromosome Mapping methods, Escherichia coli physiology, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Gene Transfer, Horizontal genetics, Signal Transduction genetics

Abstract

Horizontal gene transfer is a major contributor to the evolution of bacterial genomes. We examine this process through a combination of comparative genomics and in silico analysis of the Escherichia coli metabolic network. We validate our horizontal transfer estimates by confirming the predicted gradual amelioration of GC content over time. We find that the chance of acquiring a gene by horizontal transfer is up to six times higher if an enzyme that catalyses a coupled metabolite flux is already encoded in the host genome.

Published

2005

12. Does the recombination rate affect the efficiency of purifying selection? The yeast genome provides a partial answer.

Author

Pál C, Papp B, and Hurst LD

Subjects

Animals, Fungal Proteins genetics, Gene Expression Regulation, Fungal, Genome, Fungal, Candida albicans genetics, Recombination, Genetic, Saccharomyces cerevisiae genetics, Selection, Genetic

Published

2001

13. Highly expressed genes in yeast evolve slowly.

Author

Pál C, Papp B, and Hurst LD

Subjects

Gene Conversion, Models, Genetic, RNA, Messenger metabolism, Software, Transcription, Genetic, Evolution, Molecular, Fungal Proteins genetics, Saccharomyces cerevisiae genetics

Published

2001