Project description:Microbial populations founded by a single clone and propagated under resource limitation can become polymorphic. We sought to understand how stable polymorphism arose in an Escherichia coli population that evolved for 765 generations under continuous glucose limitation. Apart from a 29 kb deletion in the dominant clone, no large-scale genomic changes distinguish evolved clones from their common ancestor. However, when co-evolved clones are cultured separately their transcriptional profiles differ markedly from that ancestor, and do so in ways that are consistent with our understanding of how E. coli adapts to glucose limitation. All adaptive clones exhibit reduced activity of the stationary-phase sigma factor σS and increased expression of glucose transport genes, including the glycoporin LamB and the galactose transporter MglABC. Other expression differences, such as up-regulation of acetyl-CoA synthetase, are clone-specific and confirm previous reports of acetate cross-feeding in this system. When co-evolved clones are cultured together, transcription profiling reveals another class of genes whose expression in the dominant clone differs from that observed when the clone is cultured by itself. Many of these genes are part of the CpxR-mediated stress response. CpxR activation in monoculture likely results from extracellular accumulation of acetate that is removed by acetate-scavenging strains in co-culture. Targeted gene sequencing reveals that global regulatory mutations in σS as well as small-scale regulatory mutations in the maltose and acetyl CoA synthetase operons contribute to the evolution of cross-feeding. Finally, we identified two mutations in the founder that likely pre-disposed the experimental population to develop specialists that thrive on overflow metabolites. Subsequent mutations that lead to specialization emphasize the importance of compensatory rather than gain-of-function mutations in this system. Observations that polymorphism readily evolves in an asexual population, that adaptive mutants arise without large-scale change in genome architecture, and that morphs have both common and unique patterns of gene expression influenced by whether they are cultured separately or together, underscore the importance of regulatory change, founder genotype, and the biotic environment in the adaptive evolution of microbes. Four isolates of E. coli evolved under long-term glucose limitation were grown in glucose-limited chemostat culture to steady state. Each isolate was grown separately (i.e in monoculture) in triplicate and three of the four (CV101, CV103, CV115 and CV116) were grown as a consortium in duplicate. Each experiment, or biological replicate, was sampled twice for monoculture experiments and once for consortium experiments. Total RNA from each sample was competitvely hybridized against total RNA from the common ancestor of the isolates grown at the same time in a separate chemostat using the same feed medium. For monoculture experiments, three hybridizations were done for each experiment: two hybridizations comparison for the first sample and a single hybridization for the second (with the exception of sample Jv116-1A which was only hybridized twice due to lack of sufficient RNA). For consortium experiments, two hybridizations were done for each biological replicate.

Project description:Microbial populations founded by a single clone and propagated under resource limitation can become polymorphic. We sought to understand how stable polymorphism arose in an Escherichia coli population that evolved for 765 generations under continuous glucose limitation. Apart from a 29 kb deletion in the dominant clone, no large-scale genomic changes distinguish evolved clones from their common ancestor. However, when co-evolved clones are cultured separately their transcriptional profiles differ markedly from that ancestor, and do so in ways that are consistent with our understanding of how E. coli adapts to glucose limitation. All adaptive clones exhibit reduced activity of the stationary-phase sigma factor σS and increased expression of glucose transport genes, including the glycoporin LamB and the galactose transporter MglABC. Other expression differences, such as up-regulation of acetyl-CoA synthetase, are clone-specific and confirm previous reports of acetate cross-feeding in this system. When co-evolved clones are cultured together, transcription profiling reveals another class of genes whose expression in the dominant clone differs from that observed when the clone is cultured by itself. Many of these genes are part of the CpxR-mediated stress response. CpxR activation in monoculture likely results from extracellular accumulation of acetate that is removed by acetate-scavenging strains in co-culture. Targeted gene sequencing reveals that global regulatory mutations in σS as well as small-scale regulatory mutations in the maltose and acetyl CoA synthetase operons contribute to the evolution of cross-feeding. Finally, we identified two mutations in the founder that likely pre-disposed the experimental population to develop specialists that thrive on overflow metabolites. Subsequent mutations that lead to specialization emphasize the importance of compensatory rather than gain-of-function mutations in this system. Observations that polymorphism readily evolves in an asexual population, that adaptive mutants arise without large-scale change in genome architecture, and that morphs have both common and unique patterns of gene expression influenced by whether they are cultured separately or together, underscore the importance of regulatory change, founder genotype, and the biotic environment in the adaptive evolution of microbes.

Project description:Microbial populations founded by a single clone and propagated under resource limitation can become polymorphic. We sought to understand how stable polymorphism arose in an Escherichia coli population that evolved for 765 generations under continuous glucose limitation. Apart from a 29 kb deletion in the dominant clone, no large-scale genomic changes distinguish evolved clones from their common ancestor. However, when co-evolved clones are cultured separately their transcriptional profiles differ markedly from that ancestor, and do so in ways that are consistent with our understanding of how E. coli adapts to glucose limitation. All adaptive clones exhibit reduced activity of the stationary-phase sigma factor σS and increased expression of glucose transport genes, including the glycoporin LamB and the galactose transporter MglABC. Other expression differences, such as up-regulation of acetyl-CoA synthetase, are clone-specific and confirm previous reports of acetate cross-feeding in this system. When co-evolved clones are cultured together, transcription profiling reveals another class of genes whose expression in the dominant clone differs from that observed when the clone is cultured by itself. Many of these genes are part of the CpxR-mediated stress response. CpxR activation in monoculture likely results from extracellular accumulation of acetate that is removed by acetate-scavenging strains in co-culture. Targeted gene sequencing reveals that global regulatory mutations in σS as well as small-scale regulatory mutations in the maltose and acetyl CoA synthetase operons contribute to the evolution of cross-feeding. Finally, we identified two mutations in the founder that likely pre-disposed the experimental population to develop specialists that thrive on overflow metabolites. Subsequent mutations that lead to specialization emphasize the importance of compensatory rather than gain-of-function mutations in this system. Observations that polymorphism readily evolves in an asexual population, that adaptive mutants arise without large-scale change in genome architecture, and that morphs have both common and unique patterns of gene expression influenced by whether they are cultured separately or together, underscore the importance of regulatory change, founder genotype, and the biotic environment in the adaptive evolution of microbes.

Project description:In some of the earliest uses of genome-wide gene-expression microarrays and array-based Comparative Genomic Hybridization (aCGH), a set of diploid yeasts that had undergone experimental evolution under aerobic glucose limitation was used to explore how gene expression and genome structure had responded to this selection pressure. To more deeply understand how adaptation to one environment might constrain or enhance performance in another we have now identified the adaptive mutations in this set of clones using whole-genome sequencing, and have assessed whether the evolved clones had become generalists or specialists by assaying their fitness under three contrasting growth environments: aerobic and anaerobic glucose limitation and aerobic acetate limitation. Additionally, evolved clones and their common ancestor were assayed for gene expression, biomass estimates and residual substrate levels under the alternative growth conditions. Relative fitnesses were evaluated by competing each clone against a common reference strain in each environment. Unexpectedly, we found that the evolved clones also outperformed their ancestor under strictly fermentative and strictly oxidative growth conditions. We conclude that yeasts evolving under aerobic glucose limitation become generalists for carbon limitation, as the mutations selected for in one environment are advantageous in others. High-throughput sequencing of the evolved clones uncovered mutations in genes involved in glucose sensing, signaling, and transport that in part explain these physiological phenotypes, with different sets of mutations found in independently-evolved clones. Earlier gene expression data from aerobic glucose-limited cultures had revealed a shift from fermentation towards respiration in all evolved clones explaining increased fitness in that condition. However, because the evolved clones also show higher fitness under strictly anaerobic conditions and under conditions requiring strictly respirative growth, this switch cannot be the sole source of adaptive benefit. Furthermore, because independently evolved clones are genetically distinct we conclude that there are multiple mutational paths leading to the generalist phenotype. Strain Name: Parental strain (CP1AB) or evolved clones (E1 - E5) Media: aerobic / anaerobic 36 hybridizations

Project description:In some of the earliest uses of genome-wide gene-expression microarrays and array-based Comparative Genomic Hybridization (aCGH), a set of diploid yeasts that had undergone experimental evolution under aerobic glucose limitation was used to explore how gene expression and genome structure had responded to this selection pressure. To more deeply understand how adaptation to one environment might constrain or enhance performance in another we have now identified the adaptive mutations in this set of clones using whole-genome sequencing, and have assessed whether the evolved clones had become generalists or specialists by assaying their fitness under three contrasting growth environments: aerobic and anaerobic glucose limitation and aerobic acetate limitation. Additionally, evolved clones and their common ancestor were assayed for gene expression, biomass estimates and residual substrate levels under the alternative growth conditions. Relative fitnesses were evaluated by competing each clone against a common reference strain in each environment. Unexpectedly, we found that the evolved clones also outperformed their ancestor under strictly fermentative and strictly oxidative growth conditions. We conclude that yeasts evolving under aerobic glucose limitation become generalists for carbon limitation, as the mutations selected for in one environment are advantageous in others. High-throughput sequencing of the evolved clones uncovered mutations in genes involved in glucose sensing, signaling, and transport that in part explain these physiological phenotypes, with different sets of mutations found in independently-evolved clones. Earlier gene expression data from aerobic glucose-limited cultures had revealed a shift from fermentation towards respiration in all evolved clones explaining increased fitness in that condition. However, because the evolved clones also show higher fitness under strictly anaerobic conditions and under conditions requiring strictly respirative growth, this switch cannot be the sole source of adaptive benefit. Furthermore, because independently evolved clones are genetically distinct we conclude that there are multiple mutational paths leading to the generalist phenotype. Strain Name: Parental strain (CP1AB) or evolved clones (E1 - E5) Media: aerobic / anaerobic

Project description:The experimental evolution of laboratory populations of microbes provides an opportunity to observe the evolutionary dynamics of adaptation in real time.Until very recently, however, such studies have been limited by our inability to systematically find mutations in evolved organisms.We overcome this limitation by using a variety of DNA microarray-based techniques to characterize genetic changes, including point mutations, structural changes, and insertion variation, that resulted from the experimental adaptation of 24 haploid and diploid cultures of Saccharomyces cerevisiae to growth in glucose-, sulfate, or phosphate-limited chemostats for ~ 200 generations.We identified frequent genomic amplifications and rearrangements as well as novel retrotransposition events associated with adaptation.Global mutation detection in 10 clonal isolates identified 32 point mutations. On the basis of mutation frequencies, we infer that these mutations and the subsequent dynamics of adaptation are determined by the batch phase of growth prior to initiation of continuous phase in the chemostat.We relate these genotypic changes to phenotypic outcomes, namely global patterns of gene expression, and to increases in fitness by 5-50%. We found that the spectrum of available mutations in glucose or phosphate-limited environments combined with the batch phase population dynamics early in our experiments to allow several distinct genotypic and phenotypic evolutionary pathways in response to these nutrient limitations. By contrast, sulfate-limited populations were much more constrained in both genotypic and phenotypic outcomes.Thus, the reproducibility of evolution varies with specific selective pressures reflecting the constraints inherent in the system-level organization of metabolic processes in the cell.We were able to relate some of the observed adaptive mutations (e.g. transporter gene amplifications) to known features of the relevant metabolic pathways, but many of the mutations pointed to genes not previously associated with the relevant physiology. Thus, in addition to answering basic mechanistic questions about evolutionary mechanisms our work suggests that experimental evolution can also shed light on the function and regulation of individual metabolic pathways. Keywords: gene expression, CGH, and TSE analysis consult individual records for details of analysis This Dataset consists of several experiments: Gene expression experiments found in Figure 1a of paper: Design: RNA from each evolved clone or population grown in chemostat culture is compared to RNA from matching ancestor strains grown in the same conditions. Samples: GSM339025-GSM339088 CGH experiments found in Figure 2A, Figure 3, and Table S2: Experiment design: DNA from each evolved clone or population is hybridized vs DNA from the matched ancestor strain Samples: GSM339089-GSM339146 CGH experiments found in Table S3: Experiment design: DNA from each segregant derived from an evolved strain is hybridized vs DNA from the matched ancestor strain Samples: GSM339147-GSM339158 Gel band CGH experiments found in Figure S1: Experiment design: Chromosomes from evolved strains were run on a gel and excised. DNA from the bands is hybridized vs matched ancestor genomic DNA Samples: GSM339159-GSM339184 TSE CGH experiments found in Table S4: Experiment design: DNA linked to Ty1/Ty2 sequences was extracted from evolved strains and ancestor strains, and compared to ancestral extracted or genomic DNA as indicated. Samples: GSM339185-GSM339212 CGH experiments for experiments in Figure S7: Experiment design: DNA from 2 strains transformed with a SUL1 plasmid hybridized vs DNA from the matched ancestor strain Samples: GSM339213 and GSM339214

Project description:The Low MP laboratory strain BY4741 was subjected to a stepwise selection procedure during 120-150 generations, enabling enrichment for beneficial mutations that allow growth at increasing pH. In order to identify the mutations responsible for the ability to grow at high pH, we used tiling arrays to genotype the Low MP ancestor and three evolved strains: two clones from two independent lines that had acquired the ability to grow at pH 8.5 and pH 8.6 (A8.5 and C8.6) and one clone from an intermediate stage of line C (C8.0). The identity and nature of the mutated alleles was further confirmed by direct DNA sequencing. <br>

Project description:We developed and validated a small-footprint array of miniature chemostats built from readily available parts for low cost. Physiological and experimental evolution results were similar to larger volume chemostats. The ministat array provides a compact, inexpensive, and accessible platform for traditional chemostat experiments, functional genomics, and chemical screening applications. Three experiments are gene expression comparisons between three ministat cultures and a single Sixfors sample. The four CGH arrays are individual clones evolved in four sulfate limitation ministats compared to a wt ancestor strain.

Project description:Analysis of copy number variation in evolved haploid, diploid, tetraploid strains. All experimental samples were compared to the same reference strain S288C. The samples include the progenitor strains for the haploid, diploid, and tetraploid evolution experiments, and single colony isolates (clones) from the evolving populations at given time points. Evolved clones were analyzed at generation 250 unless the name is followed by gen35, gen55 or gen500, in which case those generations were analyzed.

Project description:During a 1,000 generations evolution experiment, two types of bacteria (S and L) repeatedly diverged from a common ancestor (A) in a fully sympatric seasonal environment containing glucose and acetate. We compare the transcription profile of the two derived types and the common ancestor in order to investigate the metabolic modifications associated with this adaptive diversification event. Keywords: time point, experimental evolution