Your search keyword '"Pál C"' showing total 6 results

1. How selection shapes the short- and long-term dynamics of molecular evolution.

Author

Pál C and Papp B

Subjects

Mutation, Evolution, Molecular

Published

2023

2. Improved bacterial recombineering by parallelized protein discovery.

Author

Wannier TM, Nyerges A, Kuchwara HM, Czikkely M, Balogh D, Filsinger GT, Borders NC, Gregg CJ, Lajoie MJ, Rios X, Pál C, and Church GM

Subjects

Genetic Engineering, Genome, Bacterial, Mutation, Bacterial Proteins genetics, Escherichia coli genetics, Pseudomonas aeruginosa genetics, Recombination, Genetic

Abstract

Exploiting bacteriophage-derived homologous recombination processes has enabled precise, multiplex editing of microbial genomes and the construction of billions of customized genetic variants in a single day. The techniques that enable this, multiplex automated genome engineering (MAGE) and directed evolution with random genomic mutations (DIvERGE), are however, currently limited to a handful of microorganisms for which single-stranded DNA-annealing proteins (SSAPs) that promote efficient recombineering have been identified. Thus, to enable genome-scale engineering in new hosts, efficient SSAPs must first be found. Here we introduce a high-throughput method for SSAP discovery that we call "serial enrichment for efficient recombineering" (SEER). By performing SEER in Escherichia coli to screen hundreds of putative SSAPs, we identify highly active variants PapRecT and CspRecT. CspRecT increases the efficiency of single-locus editing to as high as 50% and improves multiplex editing by 5- to 10-fold in E. coli , while PapRecT enables efficient recombineering in Pseudomonas aeruginosa , a concerning human pathogen. CspRecT and PapRecT are also active in other, clinically and biotechnologically relevant enterobacteria. We envision that the deployment of SEER in new species will pave the way toward pooled interrogation of genotype-to-phenotype relationships in previously intractable bacteria., Competing Interests: Competing interest statement: G.M.C. has related financial interests in EnEvolv, GRO Biosciences, and 64-x. G.M.C., C.J.G., M.J.L., and X.R. have submitted a patent application relating to pieces of this work (WO2017184227A2). T.M.W., G.T.F., and G.M.C. have submitted a patent application related to the improved single-stranded DNA-annealing proteins variants referenced here. A.N. and C.P. have submitted a patent application related to directed evolution with random genomic mutations (DIvERGE) (PCT/EP2017/082574 [WO2018108987] Mutagenizing Intracellular Nucleic Acids).

Published

2020

3. Directed evolution of multiple genomic loci allows the prediction of antibiotic resistance.

Author

Nyerges Á, Csörgő B, Draskovits G, Kintses B, Szili P, Ferenc G, Révész T, Ari E, Nagy I, Bálint B, Vásárhelyi BM, Bihari P, Számel M, Balogh D, Papp H, Kalapis D, Papp B, and Pál C

Subjects

Anti-Bacterial Agents pharmacology, Bacteria drug effects, Ciprofloxacin pharmacology, Drug Resistance, Multiple, Bacterial drug effects, Evolution, Molecular, Genomics methods, Mutation genetics, Mutation Rate, Trimethoprim pharmacology, Bacteria genetics, Drug Resistance, Multiple, Bacterial genetics, Genetic Loci genetics, Genome, Bacterial genetics

Abstract

Antibiotic development is frequently plagued by the rapid emergence of drug resistance. However, assessing the risk of resistance development in the preclinical stage is difficult. Standard laboratory evolution approaches explore only a small fraction of the sequence space and fail to identify exceedingly rare resistance mutations and combinations thereof. Therefore, new rapid and exhaustive methods are needed to accurately assess the potential of resistance evolution and uncover the underlying mutational mechanisms. Here, we introduce directed evolution with random genomic mutations (DIvERGE), a method that allows an up to million-fold increase in mutation rate along the full lengths of multiple predefined loci in a range of bacterial species. In a single day, DIvERGE generated specific mutation combinations, yielding clinically significant resistance against trimethoprim and ciprofloxacin. Many of these mutations have remained previously undetected or provide resistance in a species-specific manner. These results indicate pathogen-specific resistance mechanisms and the necessity of future narrow-spectrum antibacterial treatments. In contrast to prior claims, we detected the rapid emergence of resistance against gepotidacin, a novel antibiotic currently in clinical trials. Based on these properties, DIvERGE could be applicable to identify less resistance-prone antibiotics at an early stage of drug development. Finally, we discuss potential future applications of DIvERGE in synthetic and evolutionary biology., Competing Interests: Conflict of interest statement: Á.N., B.C., B.K., and C.P. have filed a patent application toward the European Patent Office. I.N., B.B., B.M.V., and P.B. had consulting positions at SeqOmics Biotechnology Ltd. at the time the study was conceived. SeqOmics Biotechnology Ltd. was not directly involved in the design and execution of the experiments or in the writing of the manuscript., (Copyright © 2018 the Author(s). Published by PNAS.)

Published

2018

4. A highly precise and portable genome engineering method allows comparison of mutational effects across bacterial species.

Author

Nyerges Á, Csörgő B, Nagy I, Bálint B, Bihari P, Lázár V, Apjok G, Umenhoffer K, Bogos B, Pósfai G, and Pál C

Subjects

Bacteria genetics, Bacteria classification, Genetic Engineering, Genome, Bacterial, Mutation

Abstract

Currently available tools for multiplex bacterial genome engineering are optimized for a few laboratory model strains, demand extensive prior modification of the host strain, and lead to the accumulation of numerous off-target modifications. Building on prior development of multiplex automated genome engineering (MAGE), our work addresses these problems in a single framework. Using a dominant-negative mutant protein of the methyl-directed mismatch repair (MMR) system, we achieved a transient suppression of DNA repair in Escherichia coli, which is necessary for efficient oligonucleotide integration. By integrating all necessary components into a broad-host vector, we developed a new workflow we term pORTMAGE. It allows efficient modification of multiple loci, without any observable off-target mutagenesis and prior modification of the host genome. Because of the conserved nature of the bacterial MMR system, pORTMAGE simultaneously allows genome editing and mutant library generation in other biotechnologically and clinically relevant bacterial species. Finally, we applied pORTMAGE to study a set of antibiotic resistance-conferring mutations in Salmonella enterica and E. coli. Despite over 100 million y of divergence between the two species, mutational effects remained generally conserved. In sum, a single transformation of a pORTMAGE plasmid allows bacterial species of interest to become an efficient host for genome engineering. These advances pave the way toward biotechnological and therapeutic applications. Finally, pORTMAGE allows systematic comparison of mutational effects and epistasis across a wide range of bacterial species.

Published

2016

5. Network-level architecture and the evolutionary potential of underground metabolism.

Author

Notebaart RA, Szappanos B, Kintses B, Pál F, Györkei Á, Bogos B, Lázár V, Spohn R, Csörgő B, Wagner A, Ruppin E, Pál C, and Papp B

Subjects

Adaptation, Physiological genetics, Computer Simulation, Enzymes genetics, Enzymes metabolism, Escherichia coli K12 genetics, Escherichia coli K12 metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Genome, Bacterial, Models, Biological, Phenotype, Biological Evolution, Metabolic Networks and Pathways genetics

Abstract

A central unresolved issue in evolutionary biology is how metabolic innovations emerge. Low-level enzymatic side activities are frequent and can potentially be recruited for new biochemical functions. However, the role of such underground reactions in adaptation toward novel environments has remained largely unknown and out of reach of computational predictions, not least because these issues demand analyses at the level of the entire metabolic network. Here, we provide a comprehensive computational model of the underground metabolism in Escherichia coli. Most underground reactions are not isolated and 45% of them can be fully wired into the existing network and form novel pathways that produce key precursors for cell growth. This observation allowed us to conduct an integrated genome-wide in silico and experimental survey to characterize the evolutionary potential of E. coli to adapt to hundreds of nutrient conditions. We revealed that underground reactions allow growth in new environments when their activity is increased. We estimate that at least ∼20% of the underground reactions that can be connected to the existing network confer a fitness advantage under specific environments. Moreover, our results demonstrate that the genetic basis of evolutionary adaptations via underground metabolism is computationally predictable. The approach used here has potential for various application areas from bioengineering to medical genetics.

Published

2014

6. Plasticity of genetic interactions in metabolic networks of yeast.

Author

Harrison R, Papp B, Pál C, Oliver SG, and Delneri D

Subjects

Environment, Gene Deletion, Gene Expression Regulation, Fungal, Genes, Fungal, Models, Genetic, Phylogeny, Gene Regulatory Networks, Metabolic Networks and Pathways genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Systems Biology

Abstract

Why are most genes dispensable? The impact of gene deletions may depend on the environment (plasticity), the presence of compensatory mechanisms (mutational robustness), or both. Here, we analyze the interaction between these two forces by exploring the condition-dependence of synthetic genetic interactions that define redundant functions and alternative pathways. We performed systems-level flux balance analysis of the yeast (Saccharomyces cerevisiae) metabolic network to identify genetic interactions and then tested the model's predictions with in vivo gene-deletion studies. We found that the majority of synthetic genetic interactions are restricted to certain environmental conditions, partly because of the lack of compensation under some (but not all) nutrient conditions. Moreover, the phylogenetic cooccurrence of synthetically interacting pairs is not significantly different from random expectation. These findings suggest that these gene pairs have at least partially independent functions, and, hence, compensation is only a byproduct of their evolutionary history. Experimental analyses that used multiple gene deletion strains not only confirmed predictions of the model but also showed that investigation of false predictions may both improve functional annotation within the model and also lead to the discovery of higher-order genetic interactions. Our work supports the view that functional redundancy may be more apparent than real, and it offers a unified framework for the evolution of environmental adaptation and mutational robustness.

Published

2007