Your search keyword '"Compensatory Mutations"' showing total 9 results

1. Bioinformatics Analysis of Mutations Sheds Light on the Evolution of Dengue NS1 Protein With Implications in the Identification of Potential Functional and Druggable Sites.

Author

Sharma A, Krishna S, and Sowdhamini R

Subjects

Mutation, Computational Biology, Viral Nonstructural Proteins genetics, Dengue

Abstract

Non-structural protein (NS1) is a 350 amino acid long conserved protein in the dengue virus. Conservation of NS1 is expected due to its importance in dengue pathogenesis. The protein is known to exist in dimeric and hexameric states. The dimeric state is involved in its interaction with host proteins and viral replication, and the hexameric state is involved in viral invasion. In this work, we performed extensive structure and sequence analysis of NS1 protein, and uncovered the role of NS1 quaternary states in its evolution. A three-dimensional modeling of unresolved loop regions in NS1 structure is performed. "Conserved" and "Variable" regions within NS1 protein were identified from sequences obtained from patient samples and the role of compensatory mutations in selecting destabilizing mutations were identified. Molecular dynamics (MD) simulations were performed to extensively study the effect of a few mutations on NS1 structure stability and compensatory mutations. Virtual saturation mutagenesis, predicting the effect of every individual amino acid substitution on NS1 stability sequentially, revealed virtual-conserved and variable sites. The increase in number of observed and virtual-conserved regions across NS1 quaternary states suggest the role of higher order structure formation in its evolutionary conservation. Our sequence and structure analysis could enable in identifying possible protein-protein interfaces and druggable sites. Virtual screening of nearly 10,000 small molecules, including FDA-approved drugs, permitted us to recognize six drug-like molecules targeting the dimeric sites. These molecules could be promising due to their stable interactions with NS1 throughout the simulation., (© The Author(s) 2023. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.)

Published

2023

2. The Structural Determinants of Intra-Protein Compensatory Substitutions.

Author

Chaurasia S and Dutheil JY

Subjects

Amino Acid Motifs, Mutation, Phylogeny, Sequence Alignment, Evolution, Molecular, Proteins chemistry, Proteins genetics

Abstract

Compensatory substitutions happen when one mutation is advantageously selected because it restores the loss of fitness induced by a previous deleterious mutation. How frequent such mutations occur in evolution and what is the structural and functional context permitting their emergence remain open questions. We built an atlas of intra-protein compensatory substitutions using a phylogenetic approach and a dataset of 1,630 bacterial protein families for which high-quality sequence alignments and experimentally derived protein structures were available. We identified more than 51,000 positions coevolving by the mean of predicted compensatory mutations. Using the evolutionary and structural properties of the analyzed positions, we demonstrate that compensatory mutations are scarce (typically only a few in the protein history) but widespread (the majority of proteins experienced at least one). Typical coevolving residues are evolving slowly, are located in the protein core outside secondary structure motifs, and are more often in contact than expected by chance, even after accounting for their evolutionary rate and solvent exposure. An exception to this general scheme is residues coevolving for charge compensation, which are evolving faster than noncoevolving sites, in contradiction with predictions from simple coevolutionary models, but similar to stem pairs in RNA. While sites with a significant pattern of coevolution by compensatory mutations are rare, the comparative analysis of hundreds of structures ultimately permits a better understanding of the link between the three-dimensional structure of a protein and its fitness landscape., (© The Author(s) 2022. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.)

Published

2022

3. Compensating the Fitness Costs of Synonymous Mutations

Author

Joakim Näsvall, Anna Knöppel, and Dan I. Andersson

Subjects

0301 basic medicine, Silent mutation, Salmonella typhimurium, Ribosomal Proteins, 030106 microbiology, Mutant, Genetic Fitness, Biology, Gene dosage, protein synthesis, Evolutionsbiologi, Evolution, Molecular, 03 medical and health sciences, Ribosomal protein, Genetics, experimental evolution, RNA, Messenger, Molecular Biology, Gene, Ecology, Evolution, Behavior and Systematics, Discoveries, Silent Mutation, Experimental evolution, Evolutionary Biology, synonymous mutations, compensatory mutations, Salmonella enterica, bacterial fitness, 030104 developmental biology, Protein Biosynthesis, Synonymous substitution

Abstract

Synonymous mutations do not change the sequence of the polypeptide but they may still influence fitness. We investigated in Salmonella enterica how four synonymous mutations in the rpsT gene (encoding ribosomal protein S20) reduce fitness (i.e., growth rate) and the mechanisms by which this cost can be genetically compensated. The reduced growth rates of the synonymous mutants were correlated with reduced levels of the rpsT transcript and S20 protein. In an adaptive evolution experiment, these fitness impairments could be compensated by mutations that either caused up-regulation of S20 through increased gene dosage (due to duplications), increased transcription of the rpsT gene (due to an rpoD mutation or mutations in rpsT), or increased translation from the rpsT transcript (due to rpsT mutations). We suggest that the reduced levels of S20 in the synonymous mutants result in production of a defective subpopulation of 30S subunits lacking S20 that reduce protein synthesis and bacterial growth and that the compensatory mutations restore S20 levels and the number of functional ribosomes. Our results demonstrate how specific synonymous mutations can cause substantial fitness reductions and that many different types of intra- and extragenic compensatory mutations can efficiently restore fitness. Furthermore, this study highlights that also synonymous sites can be under strong selection, which may have implications for the use of dN/dS ratios as signature for selection.

Published

2016

4. Microevolution of a Zoonotic Helicobacter Population Colonizing the Stomach of a Human Host before and after Failed Treatment

Author

Thomas Schott, Pradeep Kumar Kondadi, Mirko Rossi, Marja-Liisa Hänninen, Departments of Faculty of Veterinary Medicine, and Food Hygiene and Environmental Health

Subjects

DNA, Bacterial, Letter, Population, 413 Veterinary science, medicine.disease_cause, Genome, Helicobacter Infections, Evolution, Molecular, 03 medical and health sciences, Open Reading Frames, Helicobacter, Genetics, medicine, Pyloric Antrum, Humans, Selection, Genetic, education, Ecology, Evolution, Behavior and Systematics, Alleles, 030304 developmental biology, Comparative genomics, 0303 health sciences, Mutation, education.field_of_study, Polymorphism, Genetic, biology, 030306 microbiology, Population size, Microevolution, compensatory mutations, biology.organism_classification, Helicobacter heilmannii sensu lato, Helicobacter bizzozeronii, resistance mutations, Genome, Bacterial, Reference genome

Abstract

To investigate the microevolution of Helicobacter bizzozeronii in the human stomach, comparative genomics of antrum-derived populations, obtained 3 months before (T(0)) and 6 months after (T(1)) an unsuccessful eradication treatment, was performed. For each time point, the DNA of bacterial mass, representing the population diversity in three biopsies, was mixed in equal amounts and sequenced using Illumina technology. Polymorphic sites (PSs) were detected by mapping the reads against an isogenic reference genome, derived from a corpus isolate obtained at T(0). The total numbers of PSs detected in the H. bizzozeronii population at T(0) and T(1) were 128 and 223, affecting 81 and 134 coding sequences, respectively. At T(0) in 91.4% of the PSs the mutation appeared at a frequency of 50% or less. On the contrary, in the majority of the PSs observed in T(1) (71.3%) the mutation had a frequency75%. Although only a minority of mutations were fixed in the antrum-derived population at T(0), a certain level of allelic variability, compared with the corpus-derived reference genome, was present and most likely arose as consequence of the long-term colonization of the patient. The treatment probably induced a sudden decrease of population size, selecting a subpopulation, which acted as founder for the new population at T(1) characterized by a higher number of fixed mutations. These data demonstrate that genome plasticity is an important common prerequisite among gastric Helicobacter species for adaptation to the stomach environment allowing the bacterium to evolve rapidly once a selective pressure is applied.

Published

2012

5. Limits to Compensatory Mutations: Insights from Temperature-Sensitive Alleles.

Author

Tomala K, Zrebiec P, and Hartl DL

Subjects

Alleles, Amino Acid Sequence, Conserved Sequence, Orotidine-5'-Phosphate Decarboxylase genetics, Saccharomyces cerevisiae, Structure-Activity Relationship, Temperature, Mutation, Saccharomyces cerevisiae Proteins genetics

Abstract

Previous experiments with temperature-sensitive mutants of the yeast enzyme orotidine 5'-phosphate decarboxylase (encoded in gene URA3) yielded the unexpected result that reversion occurs only through exact reversal of the original mutation (Jakubowska A, Korona R. 2009. Lack of evolutionary conservation at positions important for thermal stability in the yeast ODCase protein. Mol Biol Evol. 26(7):1431-1434.). We recreated a set of these mutations in which the codon had two nucleotide substitutions, making exact reversion much less likely. We screened these double mutants for reversion and obtained a number of compensatory mutations occurring at alternative sites in the molecule. None of these compensatory mutations fully restored protein performance. The mechanism of partial compensation is consistent with a model in which protein stabilization is additive, as the same secondary mutations can compensate different primary alternations. The distance between primary and compensatory residues precludes direct interaction between the sites. Instead, most of the compensatory mutants were clustered in proximity to the catalytic center. All of the second-site compensatory substitutions occurred at relatively conserved sites, and the amino acid replacements were to residues found at these sites in a multispecies alignment of the protein. Based on the estimated distribution of changes in Gibbs free energy among a large number of amino acid replacements, we estimate that, for most proteins, the probability that a second-site mutation would have a sufficiently large stabilizing effect to offset a temperature-sensitive mutation in the order of 10-4 or less. Hence compensation is likely to take place only for slightly destabilizing mutations because highly stabilizing mutations are exceeding rare., (© The Author(s) 2019. 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

2019

6. Plasticity of Promoter-Core Sequences Allows Bacteria to Compensate for the Loss of a Key Global Regulatory Gene.

Author

Lamrabet O, Plumbridge J, Martin M, Lenski RE, Schneider D, and Hindré T

Subjects

Escherichia coli, Gene Deletion, Mutation, Phenotype, Biological Evolution, Cyclic AMP Receptor Protein genetics, Escherichia coli Proteins genetics, Gene Expression Regulation, Bacterial, Gene Regulatory Networks, Promoter Regions, Genetic

Abstract

Transcription regulatory networks (TRNs) are of central importance for both short-term phenotypic adaptation in response to environmental fluctuations and long-term evolutionary adaptation, with global regulatory genes often being targets of natural selection in laboratory experiments. Here, we combined evolution experiments, whole-genome resequencing, and molecular genetics to investigate the driving forces, genetic constraints, and molecular mechanisms that dictate how bacteria can cope with a drastic perturbation of their TRNs. The crp gene, encoding a major global regulator in Escherichia coli, was deleted in four different genetic backgrounds, all derived from the Long-Term Evolution Experiment (LTEE) but with different TRN architectures. We confirmed that crp deletion had a more deleterious effect on growth rate in the LTEE-adapted genotypes; and we showed that the ptsG gene, which encodes the major glucose-PTS transporter, gained CRP (cyclic AMP receptor protein) dependence over time in the LTEE. We then further evolved the four crp-deleted genotypes in glucose minimal medium, and we found that they all quickly recovered from their growth defects by increasing glucose uptake. We showed that this recovery was specific to the selective environment and consistently relied on mutations in the cis-regulatory region of ptsG, regardless of the initial genotype. These mutations affected the interplay of transcription factors acting at the promoters, changed the intrinsic properties of the existing promoters, or produced new transcription initiation sites. Therefore, the plasticity of even a single promoter region can compensate by three different mechanisms for the loss of a key regulatory hub in the E. coli TRN., (© The Author(s) 2019. 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

2019

7. Microevolution of a zoonotic Helicobacter population colonizing the stomach of a human host before and after failed treatment

Author

University of Helsinki, Faculty of Veterinary Medicine, Schott, Thomas, Kondadi, Pradeep Kumar, Hänninen, Marja-Liisa, Rossi, Mirko, University of Helsinki, Faculty of Veterinary Medicine, Schott, Thomas, Kondadi, Pradeep Kumar, Hänninen, Marja-Liisa, and Rossi, Mirko

Abstract

To investigate the microevolution of Helicobacter bizzozeronii in the human stomach, comparative genomics of antrum-derived populations, obtained 3 months before (T0) and 6 months after (T1) an unsuccessful eradication treatment, was performed. For each time point, the DNA of bacterial mass, representing the population diversity in three biopsies, was mixed in equal amounts and sequenced using Illumina technology. Polymorphic sites (PSs) were detected by mapping the reads against an isogenic reference genome, derived from a corpus isolate obtained at T0. The total numbers of PSs detected in the H. bizzozeronii population at T0 and T1 were 128 and 223, affecting 81 and 134 coding sequences, respectively. At T0 in 91.4% of the PSs the mutation appeared at a frequency of 50% or less. On the contrary, in the majority of the PSs observed in T1 (71.3%) the mutation had a frequency >75%. Although only a minority of mutations were fixed in the antrum-derived population at T0, a certain level of allelic variability, compared with the corpus-derived reference genome, was present and most likely arose as consequence of the long-term colonization of the patient. The treatment probably induced a sudden decrease of population size, selecting a subpopulation, which acted as founder for the new population at T1 characterized by a higher number of fixed mutations. These data demonstrate that genome plasticity is an important common prerequisite among gastric Helicobacter species for adaptation to the stomach environment allowing the bacterium to evolve rapidly once a selective pressure is applied.

Published

2012

8. Compensating the Fitness Costs of Synonymous Mutations.

Author

Knöppel A, Näsvall J, and Andersson DI

Subjects

Evolution, Molecular, Protein Biosynthesis genetics, RNA, Messenger genetics, Ribosomal Proteins metabolism, Salmonella enterica metabolism, Salmonella typhimurium genetics, Genetic Fitness, Ribosomal Proteins genetics, Salmonella enterica genetics, Silent Mutation

Abstract

Synonymous mutations do not change the sequence of the polypeptide but they may still influence fitness. We investigated in Salmonella enterica how four synonymous mutations in the rpsT gene (encoding ribosomal protein S20) reduce fitness (i.e., growth rate) and the mechanisms by which this cost can be genetically compensated. The reduced growth rates of the synonymous mutants were correlated with reduced levels of the rpsT transcript and S20 protein. In an adaptive evolution experiment, these fitness impairments could be compensated by mutations that either caused up-regulation of S20 through increased gene dosage (due to duplications), increased transcription of the rpsT gene (due to an rpoD mutation or mutations in rpsT), or increased translation from the rpsT transcript (due to rpsT mutations). We suggest that the reduced levels of S20 in the synonymous mutants result in production of a defective subpopulation of 30S subunits lacking S20 that reduce protein synthesis and bacterial growth and that the compensatory mutations restore S20 levels and the number of functional ribosomes. Our results demonstrate how specific synonymous mutations can cause substantial fitness reductions and that many different types of intra- and extragenic compensatory mutations can efficiently restore fitness. Furthermore, this study highlights that also synonymous sites can be under strong selection, which may have implications for the use of dN/dS ratios as signature for selection., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2016

9. Compensatory Mutations Restore Fitness During the Evolution of Dihydrofolate Reductase

Author

Brown, Kyle M., Costanzo, Marna, Xu, Wenxin, Roy, Scott, and Hartl, Daniel L.

Subjects

drug resistance, malaria, phenotypic robustness, mutational landscapes, compensatory mutations

Abstract

Whether a trade-off exists between robustness and evolvability is an important issue for protein evolution. While traditional viewpoints have assumed that existing functions must be compromised by the evolution of novel activities, recent research has suggested that existing phenotypes can be robust to the evolution of novel protein functions. Enzymes that are targets of antibiotics that are competitive inhibitors must evolve decreased drug affinity while maintaining their function and sustaining growth. Utilizing a transgenic Saccharomyces cerevisiae model expressing the dihydrofolate reductase (DHFR) enzyme from the malarial parasite Plasmodium falciparum, we examine the robustness of growth rate to drug-resistance mutations. We assay the growth rate and resistance of all 48 combinations of 6 DHFR point mutations associated with increased drug resistance in field isolates of the parasite. We observe no consistent relationship between growth and resistance phenotypes among the DHFR alleles. The three evolutionary pathways that dominate DHFR evolution show that mutating with increased resistance can compensate for initial declines in growth rate from previously acquired mutations. In other words, resistance mutations that occur later in evolutionary trajectories can compensate for the fitness consequences of earlier mutations. Our results suggest that high levels of resistance may be selected for without necessarily jeopardizing overall fitness., Organismic and Evolutionary Biology

Published

2010