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1. Laboratory evolution of synthetic electron transport system variants reveals a larger metabolic respiratory system and its plasticity

Author

Anand, Amitesh, Patel, Arjun, Chen, Ke, Olson, Connor A, Phaneuf, Patrick V, Lamoureux, Cameron, Hefner, Ying, Szubin, Richard, Feist, Adam M, and Palsson, Bernhard O

Subjects
Biological Sciences, Industrial Biotechnology, Biotechnology, Lung, Affordable and Clean Energy, Electron Transport, Escherichia coli, Proteome, Respiratory System, Systems Biology
Abstract

The bacterial respiratory electron transport system (ETS) is branched to allow condition-specific modulation of energy metabolism. There is a detailed understanding of the structural and biochemical features of respiratory enzymes; however, a holistic examination of the system and its plasticity is lacking. Here we generate four strains of Escherichia coli harboring unbranched ETS that pump 1, 2, 3, or 4 proton(s) per electron and characterized them using a combination of synergistic methods (adaptive laboratory evolution, multi-omic analyses, and computation of proteome allocation). We report that: (a) all four ETS variants evolve to a similar optimized growth rate, and (b) the laboratory evolutions generate specific rewiring of major energy-generating pathways, coupled to the ETS, to optimize ATP production capability. We thus define an Aero-Type System (ATS), which is a generalization of the aerobic bioenergetics and is a metabolic systems biology description of respiration and its inherent plasticity.

Published
2022

2. iModulonDB: a knowledgebase of microbial transcriptional regulation derived from machine learning

Author

Rychel, Kevin, Decker, Katherine, Sastry, Anand V, Phaneuf, Patrick V, Poudel, Saugat, and Palsson, Bernhard O

Subjects
Biotechnology, Genetics, Infection, Bacillus subtilis, Bacterial Proteins, Databases, Genetic, Escherichia coli, Gene Expression Profiling, Gene Expression Regulation, Bacterial, Gene Regulatory Networks, Internet, Knowledge Bases, Machine Learning, Software, Staphylococcus aureus, Transcription Factors, Transcription, Genetic, Transcriptome, Environmental Sciences, Biological Sciences, Information and Computing Sciences, Developmental Biology
Abstract

Independent component analysis (ICA) of bacterial transcriptomes has emerged as a powerful tool for obtaining co-regulated, independently-modulated gene sets (iModulons), inferring their activities across a range of conditions, and enabling their association to known genetic regulators. By grouping and analyzing genes based on observations from big data alone, iModulons can provide a novel perspective into how the composition of the transcriptome adapts to environmental conditions. Here, we present iModulonDB (imodulondb.org), a knowledgebase of prokaryotic transcriptional regulation computed from high-quality transcriptomic datasets using ICA. Users select an organism from the home page and then search or browse the curated iModulons that make up its transcriptome. Each iModulon and gene has its own interactive dashboard, featuring plots and tables with clickable, hoverable, and downloadable features. This site enhances research by presenting scientists of all backgrounds with co-expressed gene sets and their activity levels, which lead to improved understanding of regulator-gene relationships, discovery of transcription factors, and the elucidation of unexpected relationships between conditions and genetic regulatory activity. The current release of iModulonDB covers three organisms (Escherichia coli, Staphylococcus aureus and Bacillus subtilis) with 204 iModulons, and can be expanded to cover many additional organisms.

Published
2021

4. Causal mutations from adaptive laboratory evolution are outlined by multiple scales of genome annotations and condition-specificity

Author

Phaneuf, Patrick V, Yurkovich, James T, Heckmann, David, Wu, Muyao, Sandberg, Troy E, King, Zachary A, Tan, Justin, Palsson, Bernhard O, and Feist, Adam M

Subjects
Human Genome, Genetics, Escherichia coli, Escherichia coli Proteins, Genome, Laboratories, Mutation, Adaptive laboratory evolution, Mutation functional analysis, Mutation meta-analysis, Mutation convergence, Multiscale genome annotation, Biological Sciences, Information and Computing Sciences, Medical and Health Sciences, Bioinformatics
Abstract

BackgroundAdaptive Laboratory Evolution (ALE) has emerged as an experimental approach to discover mutations that confer phenotypic functions of interest. However, the task of finding and understanding all beneficial mutations of an ALE experiment remains an open challenge for the field. To provide for better results than traditional methods of ALE mutation analysis, this work applied enrichment methods to mutations described by a multiscale annotation framework and a consolidated set of ALE experiment conditions. A total of 25,321 unique genome annotations from various sources were leveraged to describe multiple scales of mutated features in a set of 35 Escherichia coli based ALE experiments. These experiments totalled 208 independent evolutions and 2641 mutations. Additionally, mutated features were statistically associated across a total of 43 unique experimental conditions to aid in deconvoluting mutation selection pressures.ResultsIdentifying potentially beneficial, or key, mutations was enhanced by seeking coding and non-coding genome features significantly enriched by mutations across multiple ALE replicates and scales of genome annotations. The median proportion of ALE experiment key mutations increased from 62%, with only small coding and non-coding features, to 71% with larger aggregate features. Understanding key mutations was enhanced by considering the functions of broader annotation types and the significantly associated conditions for key mutated features. The approaches developed here were used to find and characterize novel key mutations in two ALE experiments: one previously unpublished with Escherichia coli grown on glycerol as a carbon source and one previously published with Escherichia coli tolerized to high concentrations of L-serine.ConclusionsThe emergent adaptive strategies represented by sets of ALE mutations became more clear upon observing the aggregation of mutated features across small to large scale genome annotations. The clarification of mutation selection pressures among the many experimental conditions also helped bring these strategies to light. This work demonstrates how multiscale genome annotation frameworks and data-driven methods can help better characterize ALE mutations, and thus help elucidate the genotype-to-phenotype relationship of the studied organism.

Published
2020

5. Synthetic cross-phyla gene replacement and evolutionary assimilation of major enzymes

Author

Sandberg, Troy E, Szubin, Richard, Phaneuf, Patrick V, and Palsson, Bernhard O

Subjects
Microbiology, Biological Sciences, Bioinformatics and Computational Biology, Genetics, Biotechnology, Human Genome, 2.2 Factors relating to the physical environment, Aetiology, Escherichia coli, Gene Transfer, Horizontal, Genome, Genomics, Humans, Sequence Analysis, DNA, Ecology, Evolutionary biology, Environmental management
Abstract

The ability of DNA to produce a functional protein even after transfer to a foreign host is of fundamental importance in both evolutionary biology and biotechnology, enabling horizontal gene transfer in the wild and heterologous expression in the lab. However, the influence of genetic particulars on DNA functionality in a new host is poorly understood, as are the evolutionary mechanisms of assimilation and refinement. Here, we describe an automation-enabled large-scale experiment wherein Escherichia coli strains were evolved in parallel after replacement of the genes pgi or tpiA with orthologous DNA from donor species spanning all domains of life, from humans to hyperthermophilic archaea. Via analysis of hundreds of clones evolved for 50,000+ cumulative generations across dozens of independent lineages, we show that orthogene-upregulating mutations can completely mitigate fitness defects that result from initial non-functionality, with coding sequence changes unnecessary. Gene target, donor species and genomic location of the swap all influenced outcomes-both the nature of adaptive mutations (often synonymous) and the frequency with which strains successfully evolved to assimilate the foreign DNA. Additionally, time series DNA sequencing and replay evolution experiments revealed transient copy number expansions, the contingency of lineage outcome on first-step mutations and the ability for strains to escape from suboptimal local fitness maxima. Overall, this study establishes the influence of various DNA and protein features on cross-species genetic interchangeability and evolutionary outcomes, with implications for both horizontal gene transfer and rational strain design.

Published
2020

6. Kinetic profiling of metabolic specialists demonstrates stability and consistency of in vivo enzyme turnover numbers

Author

Heckmann, David, Campeau, Anaamika, Lloyd, Colton J, Phaneuf, Patrick V, Hefner, Ying, Carrillo-Terrazas, Marvic, Feist, Adam M, Gonzalez, David J, and Palsson, Bernhard O

Subjects
Genetics, Biotechnology, Human Genome, Escherichia coli, Escherichia coli Proteins, Gene Knockout Techniques, Genome, Kinetics, Machine Learning, Models, Biological, Proteomics, in vivo, turnover number, proteomics, k(cat), gene knockout, kcat
Abstract

Enzyme turnover numbers (k cats) are essential for a quantitative understanding of cells. Because k cats are traditionally measured in low-throughput assays, they can be inconsistent, labor-intensive to obtain, and can miss in vivo effects. We use a data-driven approach to estimate in vivo k cats using metabolic specialist Escherichia coli strains that resulted from gene knockouts in central metabolism followed by metabolic optimization via laboratory evolution. By combining absolute proteomics with fluxomics data, we find that in vivo k cats are robust against genetic perturbations, suggesting that metabolic adaptation to gene loss is mostly achieved through other mechanisms, like gene-regulatory changes. Combining machine learning and genome-scale metabolic models, we show that the obtained in vivo k cats predict unseen proteomics data with much higher precision than in vitro k cats. The results demonstrate that in vivo k cats can solve the problem of inconsistent and low-coverage parameterizations of genome-scale cellular models.

Published
2020

7. Laboratory evolution reveals general and specific tolerance mechanisms for commodity chemicals

Author

Lennen, Rebecca M., Lim, Hyun Gyu, Jensen, Kristian, Mohammed, Elsayed T., Phaneuf, Patrick V., Noh, Myung Hyun, Malla, Sailesh, Börner, Rosa A., Chekina, Ksenia, Özdemir, Emre, Bonde, Ida, Koza, Anna, Maury, Jérôme, Pedersen, Lasse E., Schöning, Lars Y., Sonnenschein, Nikolaus, Palsson, Bernhard O., Nielsen, Alex T., Sommer, Morten O.A., Herrgård, Markus J., and Feist, Adam M.

Published
2023
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8. Adaptive evolution reveals a tradeoff between growth rate and oxidative stress during naphthoquinone-based aerobic respiration

Author

Anand, Amitesh, Chen, Ke, Yang, Laurence, Sastry, Anand V, Olson, Connor A, Poudel, Saugat, Seif, Yara, Hefner, Ying, Phaneuf, Patrick V, Xu, Sibei, Szubin, Richard, Feist, Adam M, and Palsson, Bernhard O

Subjects
Genetics, Aerobiosis, Biological Evolution, Electron Transport, Escherichia coli, Naphthoquinones, Oxidative Stress, Oxo-Acid-Lyases, Oxygen, Reactive Oxygen Species, respiration, naphthoquinone, oxidative stress, genome-scale model
Abstract

Evolution fine-tunes biological pathways to achieve a robust cellular physiology. Two and a half billion years ago, rapidly rising levels of oxygen as a byproduct of blooming cyanobacterial photosynthesis resulted in a redox upshift in microbial energetics. The appearance of higher-redox-potential respiratory quinone, ubiquinone (UQ), is believed to be an adaptive response to this environmental transition. However, the majority of bacterial species are still dependent on the ancient respiratory quinone, naphthoquinone (NQ). Gammaproteobacteria can biosynthesize both of these respiratory quinones, where UQ has been associated with aerobic lifestyle and NQ with anaerobic lifestyle. We engineered an obligate NQ-dependent γ-proteobacterium, Escherichia coli ΔubiC, and performed adaptive laboratory evolution to understand the selection against the use of NQ in an oxic environment and also the adaptation required to support the NQ-driven aerobic electron transport chain. A comparative systems-level analysis of pre- and postevolved NQ-dependent strains revealed a clear shift from fermentative to oxidative metabolism enabled by higher periplasmic superoxide defense. This metabolic shift was driven by the concerted activity of 3 transcriptional regulators (PdhR, RpoS, and Fur). Analysis of these findings using a genome-scale model suggested that resource allocation to reactive oxygen species (ROS) mitigation results in lower growth rates. These results provide a direct elucidation of a resource allocation tradeoff between growth rate and ROS mitigation costs associated with NQ usage under oxygen-replete condition.

Published
2019

9. The genetic basis for adaptation of model-designed syntrophic co-cultures.

Author

Lloyd, Colton J, King, Zachary A, Sandberg, Troy E, Hefner, Ying, Olson, Connor A, Phaneuf, Patrick V, O'Brien, Edward J, Sanders, Jon G, Salido, Rodolfo A, Sanders, Karenina, Brennan, Caitriona, Humphrey, Gregory, Knight, Rob, and Feist, Adam M

Subjects
Escherichia coli, Coculture Techniques, Adaptation, Physiological, Mutation, Genes, Bacterial, Algorithms, Models, Biological, Biological Evolution, Bioinformatics, Mathematical Sciences, Biological Sciences, Information and Computing Sciences
Abstract

Understanding the fundamental characteristics of microbial communities could have far reaching implications for human health and applied biotechnology. Despite this, much is still unknown regarding the genetic basis and evolutionary strategies underlying the formation of viable synthetic communities. By pairing auxotrophic mutants in co-culture, it has been demonstrated that viable nascent E. coli communities can be established where the mutant strains are metabolically coupled. A novel algorithm, OptAux, was constructed to design 61 unique multi-knockout E. coli auxotrophic strains that require significant metabolite uptake to grow. These predicted knockouts included a diverse set of novel non-specific auxotrophs that result from inhibition of major biosynthetic subsystems. Three OptAux predicted non-specific auxotrophic strains-with diverse metabolic deficiencies-were co-cultured with an L-histidine auxotroph and optimized via adaptive laboratory evolution (ALE). Time-course sequencing revealed the genetic changes employed by each strain to achieve higher community growth rates and provided insight into mechanisms for adapting to the syntrophic niche. A community model of metabolism and gene expression was utilized to predict the relative community composition and fundamental characteristics of the evolved communities. This work presents new insight into the genetic strategies underlying viable nascent community formation and a cutting-edge computational method to elucidate metabolic changes that empower the creation of cooperative communities.

Published
2019

10. ALEdb 1.0: a database of mutations from adaptive laboratory evolution experimentation

Author

Phaneuf, Patrick V, Gosting, Dennis, Palsson, Bernhard O, and Feist, Adam M

Subjects
Genetics, Adaptation, Physiological, Bacteriological Techniques, Computational Biology, Databases, Genetic, Directed Molecular Evolution, Escherichia coli, Escherichia coli Proteins, Genes, Bacterial, Internet, Mutation, Polymorphism, Single Nucleotide, Reproducibility of Results, Environmental Sciences, Biological Sciences, Information and Computing Sciences, Developmental Biology
Abstract

Adaptive Laboratory Evolution (ALE) has emerged as an experimental approach to discover causal mutations that confer desired phenotypic functions. ALE not only represents a controllable experimental approach to systematically discover genotype-phenotype relationships, but also allows for the revelation of the series of genetic alterations required to acquire the new phenotype. Numerous ALE studies have been published, providing a strong impetus for developing databases to warehouse experimental evolution information and make it retrievable for large-scale analysis. Here, the first step towards establishing this resource is presented: ALEdb (http://aledb.org). This initial release contains over 11 000 mutations that have been discovered from eleven ALE publications. ALEdb (i) is a web-based platform that comprehensively reports on ALE acquired mutations and their conditions, (ii) reports key mutations using previously established trends, (iii) enables a search-driven workflow to enhance user mutation functional analysis through mutation cross-reference, (iv) allows exporting of mutation query results for custom analysis, (v) includes a bibliome describing the databased experiment publications and (vi) contains experimental evolution mutations from multiple model organisms. Thus, ALEdb is an informative platform which will become increasingly revealing as the number of reported ALE experiments and identified mutations continue to expand.

Published
2019

18. Laboratory Evolution, Transcriptomics, and Modeling Reveal Mechanisms of Paraquat Tolerance

Author

Rychel, Kevin, primary, Tan, Justin, additional, Patel, Arjun, additional, Lamoureux, Cameron, additional, Hefner, Ying, additional, Szubin, Richard, additional, Johnsen, Josefin, additional, Mohamed, Elsayed Tharwat Tolba, additional, Phaneuf, Patrick V., additional, Anand, Amitesh, additional, Olson, Connor A., additional, Park, Joon Ho, additional, Sastry, Anand V., additional, Yang, Laurence, additional, Feist, Adam M., additional, and Palsson, Bernhard, additional

Published
2023
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19. Lab evolution, transcriptomics, and modeling reveal mechanisms of paraquat tolerance

Author

Rychel, Kevin, primary, Tan, Justin, additional, Patel, Arjun, additional, Lamoureux, Cameron, additional, Hefner, Ying, additional, Szubin, Richard, additional, Johnsen, Josefin, additional, Mohamed, Elsayed Tharwat Tolba, additional, Phaneuf, Patrick V., additional, Anand, Amitesh, additional, Olson, Connor A., additional, Park, Joon Ho, additional, Sastry, Anand V., additional, Yang, Laurence, additional, Feist, Adam M., additional, and Palsson, Bernhard O., additional

Published
2022
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22. Escherichia coli Data-Driven Strain Design Using Aggregated Adaptive Laboratory Evolution Mutational Data

Author

Phaneuf, Patrick V., primary, Zielinski, Daniel C., additional, Yurkovich, James T., additional, Johnsen, Josefin, additional, Szubin, Richard, additional, Yang, Lei, additional, Kim, Se Hyeuk, additional, Schulz, Sebastian, additional, Wu, Muyao, additional, Dalldorf, Christopher, additional, Ozdemir, Emre, additional, Lennen, Rebecca M., additional, Palsson, Bernhard O., additional, and Feist, Adam M., additional

Published
2021
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23. Data-Driven Strain Design Using Aggregated Adaptive Laboratory Evolution Mutational Data

Author

Phaneuf, Patrick V., primary, Zielinski, Daniel C., additional, Yurkovich, James T., additional, Johnsen, Josefin, additional, Szubin, Richard, additional, Yang, Lei, additional, Kim, Se Hyeuk, additional, Schulz, Sebastian, additional, Wu, Muyao, additional, Dalldorf, Christopher, additional, Ozdemir, Emre, additional, Palsson, Bernhard O., additional, and Feist, Adam M., additional

Published
2021
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24. IModulonDB:A knowledgebase of microbial transcriptional regulation derived from machine learning

Author

Rychel, Kevin, Decker, Katherine, Sastry, Anand V., Phaneuf, Patrick V., Poudel, Saugat, Palsson, Bernhard O., Rychel, Kevin, Decker, Katherine, Sastry, Anand V., Phaneuf, Patrick V., Poudel, Saugat, and Palsson, Bernhard O.

Abstract

Independent component analysis (ICA) of bacterial transcriptomes has emerged as a powerful tool for obtaining co-regulated, independently-modulated gene sets (iModulons), inferring their activities across a range of conditions, and enabling their association to known genetic regulators. By grouping and analyzing genes based on observations from big data alone, iModulons can provide a novel perspective into how the composition of the transcriptome adapts to environmental conditions. Here, we present iModulonDB (imodulondb.org), a knowledgebase of prokaryotic transcriptional regulation computed from high-quality transcriptomic datasets using ICA. Users select an organism from the home page and then search or browse the curated iModulons that make up its transcriptome. Each iModulon and gene has its own interactive dashboard, featuring plots and tables with clickable, hoverable, and downloadable features. This site enhances research by presenting scientists of all backgrounds with co-expressed gene sets and their activity levels, which lead to improved understanding of regulator-gene relationships, discovery of transcription factors, and the elucidation of unexpected relationships between conditions and genetic regulatory activity. The current release of iModulonDB covers three organisms (Escherichia coli, Staphylococcus aureus and Bacillus subtilis) with 204 iModulons, and can be expanded to cover many additional organisms.

Published
2021

25. Escherichia coli Data-Driven Strain Design Using Aggregated Adaptive Laboratory Evolution Mutational Data

Author

Phaneuf, Patrick V, Zielinski, Daniel C, Yurkovich, James T, Johnsen, Josefin, Szubin, Richard, Yang, Lei, Kim, Se Hyeuk, Schulz, Sebastian, Wu, Muyao, Dalldorf, Christopher, Ozdemir, Emre, Lennen, Rebecca M, Palsson, Bernhard O, Feist, Adam M, Phaneuf, Patrick V, Zielinski, Daniel C, Yurkovich, James T, Johnsen, Josefin, Szubin, Richard, Yang, Lei, Kim, Se Hyeuk, Schulz, Sebastian, Wu, Muyao, Dalldorf, Christopher, Ozdemir, Emre, Lennen, Rebecca M, Palsson, Bernhard O, and Feist, Adam M

Abstract

Microbes are being engineered for an increasingly large and diverse set of applications. However, the designing of microbial genomes remains challenging due to the general complexity of biological systems. Adaptive Laboratory Evolution (ALE) leverages nature's problem-solving processes to generate optimized genotypes currently inaccessible to rational methods. The large amount of public ALE data now represents a new opportunity for data-driven strain design. This study describes how novel strain designs, or genome sequences not yet observed in ALE experiments or published designs, can be extracted from aggregated ALE data and demonstrates this by designing, building, and testing three novel Escherichia coli strains with fitnesses comparable to ALE mutants. These designs were achieved through a meta-analysis of aggregated ALE mutations data (63 Escherichia coli K-12 MG1655 based ALE experiments, described by 93 unique environmental conditions, 357 independent evolutions, and 13 957 observed mutations), which additionally revealed global ALE mutation trends that inform on ALE-derived strain design principles. Such informative trends anticipate ALE-derived strain designs as largely gene-centric, as opposed to noncoding, and composed of a relatively small number of beneficial variants (approximately 6). These results demonstrate how strain design efforts can be enhanced by the meta-analysis of aggregated ALE data.

Published
2021

26. Additional file 1 of Causal mutations from adaptive laboratory evolution are outlined by multiple scales of genome annotations and condition-specificity

Author

Phaneuf, Patrick V., Yurkovich, James T., Heckmann, David, Muyao Wu, Sandberg, Troy E., King, Zachary A., Tan, Justin, Palsson, Bernhard O., and Feist, Adam M.

Subjects
ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, ComputingMilieux_COMPUTERSANDEDUCATION, Data_FILES, ComputerApplications_COMPUTERSINOTHERSYSTEMS
Abstract

Additional file 1: Supplementary figures and tables.

Published
2020
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27. Causal mutations from adaptive laboratory evolution are outlined by multiple scales of genome annotations and condition-specificity

Author

Phaneuf, Patrick V., Yurkovich, James T., Heckmann, David, Wu, Muyao, Sandberg, Troy E., King, Zachary A., Tan, Justin, Palsson, Bernhard O., Feist, Adam M., Phaneuf, Patrick V., Yurkovich, James T., Heckmann, David, Wu, Muyao, Sandberg, Troy E., King, Zachary A., Tan, Justin, Palsson, Bernhard O., and Feist, Adam M.

Abstract

Background: Adaptive Laboratory Evolution (ALE) has emerged as an experimental approach to discover mutations that confer phenotypic functions of interest. However, the task of finding and understanding all beneficial mutations of an ALE experiment remains an open challenge for the field. To provide for better results than traditional methods of ALE mutation analysis, this work applied enrichment methods to mutations described by a multiscale annotation framework and a consolidated set of ALE experiment conditions. A total of 25,321 unique genome annotations from various sources were leveraged to describe multiple scales of mutated features in a set of 35 Escherichia coli based ALE experiments. These experiments totalled 208 independent evolutions and 2641 mutations. Additionally, mutated features were statistically associated across a total of 43 unique experimental conditions to aid in deconvoluting mutation selection pressures. Results: Identifying potentially beneficial, or key, mutations was enhanced by seeking coding and non-coding genome features significantly enriched by mutations across multiple ALE replicates and scales of genome annotations. The median proportion of ALE experiment key mutations increased from 62%, with only small coding and non-coding features, to 71% with larger aggregate features. Understanding key mutations was enhanced by considering the functions of broader annotation types and the significantly associated conditions for key mutated features. The approaches developed here were used to find and characterize novel key mutations in two ALE experiments: one previously unpublished with Escherichia coli grown on glycerol as a carbon source and one previously published with Escherichia coli tolerized to high concentrations of L-serine. Conclusions: The emergent adaptive strategies represented by sets of ALE mutations became more clear upon observing the aggregation of mutated features across small to

Published
2020

28. The Bitome: digitized genomic features reveal fundamental genome organization

Author

Lamoureux, Cameron R., Choudhary, Kumari Sonal, King, Zachary A., Sandberg, Troy E., Gao, Ye, Sastry, Anand V., Phaneuf, Patrick V., Choe, Donghui, Cho, Byung-Kwan, Palsson, Bernhard O., Lamoureux, Cameron R., Choudhary, Kumari Sonal, King, Zachary A., Sandberg, Troy E., Gao, Ye, Sastry, Anand V., Phaneuf, Patrick V., Choe, Donghui, Cho, Byung-Kwan, and Palsson, Bernhard O.

Abstract

A genome contains the information underlying an organism's form and function. Yet, we lack formal framework to represent and study this information. Here, we introduce the Bitome, a matrix composed of binary digits (bits) representing the genomic positions of genomic features. We form a Bitome for the genome of Escherichia coli K-12 MG1655. We find that: (i) genomic features are encoded unevenly, both spatially and categorically; (ii) coding and intergenic features are recapitulated at high resolution; (iii) adaptive mutations are skewed towards genomic positions with fewer features; and (iv) the Bitome enhances prediction of adaptively mutated and essential genes. The Bitome is a formal representation of a genome and may be used to study its fundamental organizational properties.

Published
2020

29. Synthetic cross-phyla gene replacement and evolutionary assimilation of major enzymes

Author

Sandberg, Troy E., Szubin, Richard, Phaneuf, Patrick V., Palsson, Bernhard O., Sandberg, Troy E., Szubin, Richard, Phaneuf, Patrick V., and Palsson, Bernhard O.

Abstract

The ability of DNA to produce a functional protein even after transfer to a foreign host is of fundamental importance in both evolutionary biology and biotechnology, enabling horizontal gene transfer in the wild and heterologous expression in the lab. However, the influence of genetic particulars on DNA functionality in a new host is poorly understood, as are the evolutionary mechanisms of assimilation and refinement. Here, we describe an automation-enabled large-scale experiment wherein Escherichia coli strains were evolved in parallel after replacement of the genes pgi or tpiA with orthologous DNA from donor species spanning all domains of life, from humans to hyperthermophilic archaea. Via analysis of hundreds of clones evolved for 50,000+ cumulative generations across dozens of independent lineages, we show that orthogene-upregulating mutations can completely mitigate fitness defects that result from initial non-functionality, with coding sequence changes unnecessary. Gene target, donor species and genomic location of the swap all influenced outcomes—both the nature of adaptive mutations (often synonymous) and the frequency with which strains successfully evolved to assimilate the foreign DNA. Additionally, time series DNA sequencing and replay evolution experiments revealed transient copy number expansions, the contingency of lineage outcome on first-step mutations and the ability for strains to escape from suboptimal local fitness maxima. Overall, this study establishes the influence of various DNA and protein features on cross-species genetic interchangeability and evolutionary outcomes, with implications for both horizontal gene transfer and rational strain design.

Published
2020

30. Adaptive laboratory evolution of Escherichia coli under acid stress

Author

Du, Bin, Olson, Connor A., Sastry, Anand V, Fang, Xin, Phaneuf, Patrick V., Chen, Ke, Wu, Muyao, Szubin, Richard, Xu, Sibei, Gao, Ye, Hefner, Ying, Feist, Adam M, Palsson, Bernhard O, Du, Bin, Olson, Connor A., Sastry, Anand V, Fang, Xin, Phaneuf, Patrick V., Chen, Ke, Wu, Muyao, Szubin, Richard, Xu, Sibei, Gao, Ye, Hefner, Ying, Feist, Adam M, and Palsson, Bernhard O

Abstract

The ability of Escherichia coli to tolerate acid stress is important for its survival and colonization in the human digestive tract. Here, we performed adaptive laboratory evolution of the laboratory strain E. coli K-12 MG1655 at pH 5.5 in glucose minimal medium. After 800 generations, six independent populations under evolution had reached 18.0 % higher growth rates than their starting strain at pH 5.5, while maintaining comparable growth rates to the starting strain at pH 7. We characterized the evolved strains and found that: (1) whole genome sequencing of isolated clones from each evolved population revealed mutations in rpoC appearing in five of six sequenced clones; and (2) gene expression profiles revealed different strategies to mitigate acid stress, which are related to amino acid metabolism and energy production and conversion. Thus, a combination of adaptive laboratory evolution, genome resequencing and expression profiling revealed, on a genome scale, the strategies that E. coli uses to mitigate acid stress.

Published
2020

33. Adaptive laboratory evolution of Escherichia coli under acid stress

Author

Du, Bin, primary, Olson, Connor A., additional, Sastry, Anand V., additional, Fang, Xin, additional, Phaneuf, Patrick V., additional, Chen, Ke, additional, Wu, Muyao, additional, Szubin, Richard, additional, Xu, Sibei, additional, Gao, Ye, additional, Hefner, Ying, additional, Feist, Adam M., additional, and Palsson, Bernhard O., additional

Published
2020
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34. The genetic basis for adaptation of model-designed syntrophic co-cultures

Author

Lloyd, Colton J., King, Zachary A., Sandberg, Troy E., Hefner, Ying, Olson, Connor A., Phaneuf, Patrick V., O'Brien, Edward J., Sanders, Jon G., Salido, Rodolfo A., Sanders, Karenina, Brennan, Caitriona, Humphrey, Gregory, Knight, Rob, Feist, Adam M., Lloyd, Colton J., King, Zachary A., Sandberg, Troy E., Hefner, Ying, Olson, Connor A., Phaneuf, Patrick V., O'Brien, Edward J., Sanders, Jon G., Salido, Rodolfo A., Sanders, Karenina, Brennan, Caitriona, Humphrey, Gregory, Knight, Rob, and Feist, Adam M.

Abstract

Understanding the fundamental characteristics of microbial communities could have far reaching implications for human health and applied biotechnology. Despite this, much is still unknown regarding the genetic basis and evolutionary strategies underlying the formation of viable synthetic communities. By pairing auxotrophic mutants in co-culture, it has been demonstrated that viable nascent E. coli communities can be established where the mutant strains are metabolically coupled. A novel algorithm, OptAux, was constructed to design 61 unique multi-knockout E. coli auxotrophic strains that require significant metabolite uptake to grow. These predicted knockouts included a diverse set of novel non-specific auxotrophs that result from inhibition of major biosynthetic subsystems. Three OptAux predicted non-specific auxotrophic strains-with diverse metabolic deficiencies-were co-cultured with an L-histidine auxotroph and optimized via adaptive laboratory evolution (ALE). Time-course sequencing revealed the genetic changes employed by each strain to achieve higher community growth rates and provided insight into mechanisms for adapting to the syntrophic niche. A community model of metabolism and gene expression was utilized to predict the relative community composition and fundamental characteristics of the evolved communities. This work presents new insight into the genetic strategies underlying viable nascent community formation and a cutting-edge computational method to elucidate metabolic changes that empower the creation of cooperative communities.

Published
2019

35. Aledb 1.0: A database of mutations from adaptive laboratory evolution experimentation

Author

Phaneuf, Patrick V., Gosting, Dennis, Palsson, Bernhard O., Feist, Adam M., Phaneuf, Patrick V., Gosting, Dennis, Palsson, Bernhard O., and Feist, Adam M.

Abstract

Adaptive Laboratory Evolution (ALE) has emerged as an experimental approach to discover causal mutations that confer desired phenotypic functions. ALE not only represents a controllable experimental approach to systematically discover genotypephenotype relationships, but also allows for the revelation of the series of genetic alterations required to acquire the new phenotype. Numerous ALE studies have been published, providing a strong impetus for developing databases to warehouse experimental evolution information and make it retrievable for large-scale analysis. Here, the first step towards establishing this resource is presented: ALEdb (http: //aledb.org). This initial release contains over 11 000 mutations that have been discovered from eleven ALE publications. ALEdb (i) is a web-based platform that comprehensively reports on ALE acquired mutations and their conditions, (ii) reports key mutations using previously established trends, (iii) enables a search-driven workflow to enhance user mutation functional analysis through mutation crossreference, (iv) allows exporting of mutation query results for custom analysis, (v) includes a bibliome describing the databased experiment publications and (vi) contains experimental evolution mutations from multiple model organisms. Thus, ALEdb is an informative platform which will become increasingly revealing as the number of reported ALE experiments and identified mutations continue to expand.

Published
2019

36. Additional file 6 of Reframing gene essentiality in terms of adaptive flexibility

Author

Guzmรกn, Gabriela I., Olson, Connor A., Hefner, Ying, Phaneuf, Patrick V., Catoiu, Edward, Lais B. Crepaldi, Micas, Lucas Goldschmidt, Palsson, Bernhard O., and Feist, Adam M.

Subjects
body regions, nervous system, fungi
Abstract

Secondary structure of tRNA His and observed hisR mutations. This file (.pdf) contains a figure showing the secondary structure of tRNA His and observed hisR mutations aligned with tRNA numbering convention. (PDF 272 kb)

Published
2018
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37. Additional file 7 of Reframing gene essentiality in terms of adaptive flexibility

Author

Guzmรกn, Gabriela I., Olson, Connor A., Hefner, Ying, Phaneuf, Patrick V., Catoiu, Edward, Lais B. Crepaldi, Micas, Lucas Goldschmidt, Palsson, Bernhard O., and Feist, Adam M.

Abstract

Genome duplication amplification events observed in cysK, carA, and ptsI experiments. This file (.pdf) contains a figure showing the read depth coverage (y-axis) plotted against the genome position (x-axis) for flask 1 population samples for A. cysK, B. carA, C. and ptsI experiments. (PDF 316 kb)

Published
2018
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38. Additional file 8 of Reframing gene essentiality in terms of adaptive flexibility

Author

GuzmĂĄn, Gabriela I., Olson, Connor A., Hefner, Ying, Phaneuf, Patrick V., Catoiu, Edward, Lais B. Crepaldi, Micas, Lucas Goldschmidt, Palsson, Bernhard O., and Feist, Adam M.

Abstract

FBA simulations for genes listed in Table 1. This file (.pdf) contains a table of simulations demonstrating the same predicted behavior in both the iJO1366 model corresponding to the MG1655 genotype and a modified iJO1366 model corresponding to the BW25113 genotype.(PDF 79 kb)

Published
2018
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39. Additional file 2 of Reframing gene essentiality in terms of adaptive flexibility

Author

GuzmĂĄn, Gabriela I., Olson, Connor A., Hefner, Ying, Phaneuf, Patrick V., Catoiu, Edward, Lais B. Crepaldi, Micas, Lucas Goldschmidt, Palsson, Bernhard O., and Feist, Adam M.

Abstract

Growth curves of five false positive replicate strains (ptsI, serB, proA, proB, and carA) in separate subplots are displayed. This file (.pdf) contains a figure that is an extension of Figure 1B, as the same curves for these cases are displayed; however, specific labeling of each curve with their associated experiment (exp.) number is provided in the legend of each subplot. The experiment number corresponds to those numbers listed in Table 2. (PDF 183 kb)

Published
2018
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40. Additional file 3 of Reframing gene essentiality in terms of adaptive flexibility

Author

GuzmĂĄn, Gabriela I., Olson, Connor A., Hefner, Ying, Phaneuf, Patrick V., Catoiu, Edward, Lais B. Crepaldi, Micas, Lucas Goldschmidt, Palsson, Bernhard O., and Feist, Adam M.

Abstract

Contingency table examples showing the likelihood of mutational convergence. This file (.pdf) contains a figure of contingency table examples showing the likelihood of mutational convergence between two samples. p-values calculated from Fisherâ s exact test are reported for four examples. (PDF 97 kb)

Published
2018
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41. Additional file 1 of Reframing gene essentiality in terms of adaptive flexibility

Author

Guzmรกn, Gabriela I., Olson, Connor A., Hefner, Ying, Phaneuf, Patrick V., Catoiu, Edward, Lais B. Crepaldi, Micas, Lucas Goldschmidt, Palsson, Bernhard O., and Feist, Adam M.

Abstract

All FP KO strains considered in this study. This file (.pdf) contains a table listing all false positive KO strains considered for extended growth tests. Additional information regarding proposed conditional essentiality is also provided as well as a comparison to a previous study [22]. (PDF 67 kb)

Published
2018
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43. Adaptive laboratory evolution ofEscherichia coliunder acid stress

Author

Du, Bin, primary, Olson, Connor A., additional, Sastry, Anand V., additional, Fang, Xin, additional, Phaneuf, Patrick V., additional, Chen, Ke, additional, Wu, Muyao, additional, Szubin, Richard, additional, Xu, Sibei, additional, Gao, Ye, additional, Hefner, Ying, additional, Feist, Adam M., additional, and Palsson, Bernhard O., additional

Published
2019
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47. Additional file 5 of Reframing gene essentiality in terms of adaptive flexibility

Author

Guzmรกn, Gabriela I., Olson, Connor A., Hefner, Ying, Phaneuf, Patrick V., Catoiu, Edward, Lais B. Crepaldi, Micas, Lucas Goldschmidt, Palsson, Bernhard O., and Feist, Adam M.

Subjects
body regions, nervous system, fungi, 3. Good health
Abstract

Mutations observed in starting strains grown in LB rich medium. This file (.pdf) contains a table listing mutations identified in the PCR-confirmed Keio strains that were used in the extended growth tests on minimal medium. (PDF 49 kb)

48. iModulonDB 2.0: dynamic tools to facilitate knowledge-mining and user-enabled analyses of curated transcriptomic datasets.

Author

Catoiu EA, Krishnan J, Li G, Lou XA, Rychel K, Yuan Y, Bajpe H, Patel A, Choe D, Shin J, Burrows J, Phaneuf PV, Zielinski DC, and Palsson BO

Abstract

iModulons-sets of co-expressed genes identified through independent component analysis (ICA) of high-quality transcriptomic datasets-provide an unbiased, modular view of an organism's transcriptional regulatory network. Established in 2020, iModulonDB (iModulonDB.org) serves as a centralized repository of curated iModulon sets, enabling users to explore iModulons and download the associated transcriptomic data. This update reflects a significant expansion of the database-19 new ICA decompositions (+633%) spanning 8 925 expression profiles (+1370%), 503 studies (+2290%) and 12 additional organisms (+400%)-and introduces new features to help scientists decipher the mechanisms governing prokaryotic transcriptional regulation. To facilitate comprehension of the underlying expression profiles, the updated user-interface displays essential information about each data-generating study (e.g. the experimental conditions and publication abstract). Dashboards now include condition-specific coloring and highlight data generated from genetically perturbed strains, enabling users to rapidly interpret disruptions in transcriptional regulation. New interactive graphs rapidly convey omics-derived indicators (e.g. the explained variance of ICA decompositions, genetic overlap between iModulons and regulons). Direct links to operon diagrams (BioCyc) and protein-protein interaction networks (STRING) provide users with seamless access to external resources for further assessment of iModulons. Lastly, a new suite of search-driven and species-wide analysis tools promotes user-engagement with iModulons, reinforcing iModulonDB's role as a dynamic, interactive knowledgebase of prokaryotic transcriptional regulation., (© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2024
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