Evolution of Fitness Trade-Offs in Locally Adapted Populations of <i>Pseudomonas fluorescens</i>

Schick, Alana; Bailey, Susan F.; Kassen, Rees

doi:10.1086/682932

Cited by 52 publications

(49 citation statements)

References 33 publications

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“…This trend is consistent with a Fisher's geometric model of adaptation in a multipeaked landscape (Martin and Lenormand ; Schick et al. ).…”

Section: Discussionsupporting

confidence: 88%

“…It is worth mentioning that the negative response to on-pathway substrates displayed a tendency to become more negative through time (Table 1). This trend is consistent with a Fisher's geometric model of adaptation in a multipeaked landscape (Martin and Lenormand 2015;Schick et al 2015). This conclusion that specialization evolves among metabolic pathways is consistent with well-established trade-offs between major metabolic systems such as autotrophy versus heterotrophy (Reboud and Bell 1997) or fermentation versus respiration (Novak et al 2006;Frank 2010).…”

Section: The Grain Of Specializationsupporting

confidence: 87%

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Experimental evolution of the grain of metabolic specialization in yeast

Samani

Bell

2016

Ecology and Evolution

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Adaptation to any given environment may be accompanied by a cost in terms of reduced growth in the ancestral or some alternative environment. Ecologists explain the cost of adaptation through the concept of a trade‐off, by which gaining a new trait involves losing another trait. Two mechanisms have been invoked to explain the evolution of trade‐offs in ecological systems, mutational degradation, and functional interference. Mutational degradation occurs when a gene coding a specific trait is not under selection in the resident environment; therefore, it may be degraded through the accumulation of mutations that are neutral in the resident environment but deleterious in an alternative environment. Functional interference evolves if the gene or a set of genes have antagonistic effects in two or more ecologically different traits. Both mechanisms pertain to a situation where the selection and the alternative environments are ecologically different. To test this hypothesis, we conducted an experiment in which 12 experimental populations of wild yeast were each grown in a minimal medium supplemented with a single substrate. We chose 12 different carbon substrates that were metabolized through similar and different pathways in order to represent a wide range of ecological conditions. We found no evidence for trade‐offs between substrates on the same pathway. The indirect response of substrates on other pathways, however, was consistently negative, with little correlation between the direct and indirect responses. We conclude that the grain of specialization in this case is the metabolic pathway and that specialization appears to evolve through mutational degradation.

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“…This trend is consistent with a Fisher's geometric model of adaptation in a multipeaked landscape (Martin and Lenormand ; Schick et al. ).…”

Section: Discussionsupporting

confidence: 88%

Section: The Grain Of Specializationsupporting

confidence: 87%

Experimental evolution of the grain of metabolic specialization in yeast

Samani

Bell

2016

Ecology and Evolution

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“…All models that explore the conditions for the evolution and coexistence of specialists and generalists (for example, Wilson and Yoshimura, 1994;Egas et al, 2004;Abrams, 2006Abrams, , 2012Nurmi and Parvinen, 2008) assume that generalists trade off their ability to exploit multiple niches for their efficiency in any one. Indeed, were there no cost to being a generalist, generalists would always replace specialists, so the coexistence of these two strategies requires the existence of such costs, which are, however, seldom evaluated (Kassen, 2002;Palaima, 2007;Satterwhite and Cooper, 2015;Schick et al, 2015). Here, work with the plant pathogen Agrobacterium tumefaciens permits us to contribute new observations that help elucidate these questions of the evolution of generalist versus specialist strategies and competition and coexistence of the two types of strategies within their constructed niches.…”

Section: Introductionmentioning

confidence: 99%

Fitness costs restrict niche expansion by generalist niche-constructing pathogens

et al. 2016

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We investigated the molecular and ecological mechanisms involved in niche expansion, or generalism, versus specialization in sympatric plant pathogens. Nopaline-type and octopine-type Agrobacterium tumefaciens engineer distinct niches in their plant hosts that provide different nutrients: nopaline or octopine, respectively. Previous studies revealed that nopaline-type pathogens may expand their niche to also assimilate octopine in the presence of nopaline, but consequences of this phenomenon on pathogen dynamics in planta were not known. Here, we provided molecular insight into how the transport protein NocT can bind octopine as well as nopaline, contributing to niche expansion. We further showed that despite the ability for niche expansion, nopaline-type pathogens had no competitive advantage over octopine-type pathogens in co-infected plants. We also demonstrated that a single nucleotide polymorphism in the nocR gene was sufficient to allow octopine assimilation by nopaline-type strains even in absence of nopaline. The evolved nocR bacteria had higher fitness than their ancestor in octopine-rich transgenic plants but lower fitness in tumors induced by octopine-type pathogens. Overall, this work elucidates the specialization of A. tumefaciens to particular opine niches and explains why generalists do not always spread despite the advantage associated with broader nutritional niches.

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“…In other words, alleles that increase fitness in one environment are necessarily suboptimal in others (thus, trade-offs could contribute to the maintenance of variation within populations; Levene 1953;Huang et al 2014). Despite widespread evidence of local adaptation among populations (Leimu and Fischer 2008;Hereford 2009;Sanford and Kelly 2011), evidence for genetic trade-offs within populations has been more elusive, and most examples come from experimental evolution in microbial systems (e.g., Rodríguez-Verdugo et al 2014;Schick et al 2015). Without evidence for within-population fitness trade-offs, it is not possible to distinguish whether trade-offs are a cause or consequence of ecological specialization (Futuyma and Moreno 1988).…”

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confidence: 99%

Genomic evidence that resource-based trade-offs limit host-range expansion in a seed beetle

2016

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Trade-offs have often been invoked to explain the evolution of ecological specialization. Phytophagous insects have been especially well studied, but there has been little evidence that resource-based trade-offs contribute to the evolution of host specialization in this group. Here, we combine experimental evolution and partial genome resequencing of replicate seed beetle selection lines to test the trade-off hypothesis and measure the repeatability of evolution. Bayesian estimates of selection coefficients suggest that rapid adaptation to a poor host (lentil) was mediated by standing genetic variation at multiple genetic loci and involved many of the same variants in replicate lines. Sublines that were then switched back to the ancestral host (mung bean) showed a more gradual and variable (less repeatable) loss of adaptation to lentil. We were able to obtain estimates of variance effective population sizes from genome-wide differences in allele frequencies within and between lines. These estimates were relatively large, which suggests that the contribution of genetic drift to the loss of adaptation following reversion was small. Instead, we find that some alleles that were favored on lentil were selected against during reversion on mung bean, consistent with the genetic trade-off hypothesis.

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Evolution of Fitness Trade-Offs in Locally Adapted Populations of Pseudomonas fluorescens

Cited by 52 publications

References 33 publications

Experimental evolution of the grain of metabolic specialization in yeast

Experimental evolution of the grain of metabolic specialization in yeast

Fitness costs restrict niche expansion by generalist niche-constructing pathogens

Genomic evidence that resource-based trade-offs limit host-range expansion in a seed beetle

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