Journal: Journal of Evolutionary Biology

Abbreviation

J Evol Biol

Publisher

Oxford University Press

Journal Volumes

ISSN

1010-061X
1420-9101

Description

Filters

2024 - 20268
Reset filters

Search Results

Publications 1 - 8 of 8
  • Evidence for toxin-encoding coinfections driving intransitive dynamics between allelopathic phenotypes in natural yeast populations
    Item type: Journal Article
    Travers-Cook, Tommy J.; Gonzalez-Gonzalez, Emmy; Jokela, Jukka; et al. (2026)
    Journal of Evolutionary Biology
    Competitive intransitivity, or non-hierarchical competitive interactions, such as those exemplified by the rock-paper-scissors game where no single competitor wins outright, has been proposed as a key mechanism for maintaining biodiversity; however, empirical evidence supporting the importance of intransitivity remains limited. Natural populations of Saccharomyces cerevisiae often include strains harboring totivirus-satellite coinfections that encode a lethal toxic glycoprotein capable of eliminating competing yeast strains. Killer strains are sparsely distributed in natural populations, despite their assumed competitive advantage. Yeast isolates occasionally exhibit toxin resistance, but it remains untested whether they can outcompete and replace killer strains. Similarly, the persistence of toxin-susceptible yeast is not well understood-particularly whether they can invade resistant populations in the absence of killers, thereby completing an intransitive loop. In a multi-year collection of yeast isolates from vineyards across New Zealand, we observed a near-complete disappearance of a previously common killer yeast genotype of S. cerevisiae over consecutive years. Using space-time-shift competition assays, we demonstrate that strains sympatric to this killer genotype were universally toxin-resistant, unlike the allopatric strains that were frequently eliminated in competition assays. Furthermore, the extinction of the focal killer genotype appears to have enabled the emergence of toxin-susceptible competitors in sites formerly occupied by the killer genotype. Our findings suggest that the competitive advantage of toxin production is evident in natural populations but appears to be eroded when resistance evolves in competitors of the focal killer genotype. We suggest that such killer-resistant-susceptible polymorphisms are being maintained by evolutionary dynamics akin to rock-paper-scissors-like intransitivity, driven by the invasion of susceptible strains after costly resistance has driven killer strains to extinction in natural populations, all being driven by toxin-encoding coinfections.
  • Positive and negative frequency-dependent parasitism in naturally co-occurring diploid sexual and polyploid asexual Lumbriculus variegatus
    Item type: Journal Article
    Tardent, Nadine; Schlegel, Tamara; Jokela, Jukka; et al. (2025)
    Journal of Evolutionary Biology
    Polyploidization is an important evolutionary force. It drives sympatric speciation through reproductive isolation of different cytotypes, and often leads to loss of sexual reproduction in polyploid lineages. Polyploidization and asexuality can change how other species engage in ecological interactions with the polyploid lineage and may change coevolutionary dynamics. Here, we quantified the phenotypic divergence in the freshwater oligochaete worm Lumbriculus variegatus, the California blackworm, among its co-occurring sexual diploid (Lineage II) and asexual polyploid (Lineage I) lineages. We further investigated variation in parasite communities and infection prevalence among sympatric and allopatric diploid/polyploid populations. 10 out of 18 populations showed co-existence of both lineages, with 7 populations harbouring only the polyploid lineage. Both worm lineages hosted endoparasitic nematodes, an ectoparasitic rotifer, and one potentially symbiotic gut ciliate. The parasite community similarity and overlapping size range of diploid and polyploid worms points to the ecological similarity of the worm lineages, despite the substantial ploidy and reproductive strategy differentiation. Although parasite prevalence varied independently of worm lineage, the prevalence was associated with the frequency of local cytotypes. Specifically, the rotifer prevalence was highest on the rare local cytotype, and nematode prevalence was highest on the common local cytotype. These results suggest the presence of both positive and negative frequency-dependent parasitism, which may contribute to the co-existence in the L. variegatus species complex.
  • Opening the species box: what parsimonious microscopic models of speciation have to say about macroevolution
    Item type: Review Article
    Couvert, Elisa; Bienvenu, François; Duchamps, Jean-Jil; et al. (2024)
    Journal of Evolutionary Biology
    In the last two decades, lineage-based models of diversification, where species are viewed as particles that can divide (speciate) or die (become extinct) at rates depending on some evolving trait, have been very popular tools to study macroevolutionary processes. Here, we argue that this approach cannot be used to break down the inner workings of species diversification and that "opening the species box" is necessary to understand the causes of macroevolution, but that too detailed speciation models also fail to make robust macroevolutionary predictions. We set up a general framework for parsimonious models of speciation that rely on a minimal number of mechanistic principles: (a) reproductive isolation is caused by excessive dissimilarity between genotypes; (b) dissimilarity results from a balance between differentiation processes and homogenizing processes; and (c) dissimilarity can feed back on these processes by decelerating homogenization. We classify such models according to the main homogenizing process: (a) clonal evolution models (ecological drift), (b) models of genetic isolation (gene flow), and (c) models of isolation by distance (spatial drift). We review these models and their specific predictions on macroscopic variables such as species abundances, speciation rates, interfertility relationships, or phylogenetic tree structure. We propose new avenues of research by displaying conceptual questions remaining to be solved and new models to address them: the failure of speciation at secondary contact, the feedback of dissimilarity on homogenization, and the emergence in space of breeding barriers.
  • Detecting directional epistasis and dominance from cross-line analyses in alpine populations of Arabidopsis thaliana
    Item type: Journal Article
    Le Rouzic, Arnaud; Roumet, Marie; Widmer, Alex; et al. (2024)
    Journal of Evolutionary Biology
    The contribution of non-additive genetic effects to the genetic architecture of fitness and to the evolutionary potential of populations has been a topic of theoretical and empirical interest for a long time. Yet, the empirical study of these effects in natural populations remains scarce, perhaps because measuring dominance and epistasis relies heavily on experimental line crosses. In this study, we explored the contribution of dominance and epistasis in natural alpine populations of Arabidopsis thaliana for 2 fitness traits, the dry biomass and the estimated number of siliques, measured in a greenhouse. We found that, on average, crosses between inbred lines of A. thaliana led to mid-parent heterosis for dry biomass but outbreeding depression for an estimated number of siliques. While heterosis for dry biomass was due to dominance, we found that outbreeding depression for an estimated number of siliques could be attributed to the breakdown of beneficial epistatic interactions. We simulated and discussed the implication of these results for the adaptive potential of the studied populations, as well as the use of line-cross analyses to detect non-additive genetic effects.
  • The Clade Replacement Theory: a framework to study age-dependent extinction
    Item type: Journal Article
    Calderón del Cid, Carlos; Villalobos, Fabricio; Dobrovolski, Ricardo; et al. (2024)
    Journal of Evolutionary Biology
    There is no scientific consensus about whether and how species’ evolutionary age, or the elapsed time since their origination, might affect their probability of going extinct. Different age-dependent extinction (ADE) patterns have been proposed in theoretical and empirical studies, while the existence of a consistent and universal pattern across the tree of life remains debated. If evolutionary age predicts species extinction probability, then the study of ADE should comprise the elapsed time and the ecological process acting on species from their origin to their extinction or to the present for extant species. Additionally, given that closely related species share traits associated with fitness, evolutionary proximity could generate similar ADE patterns. Considering the historical context and extinction selectivity based on evolutionary relatedness, we build on previous theoretical work to formalize the Clade Replacement Theory (CRT) as a framework that considers the ecological and evolutionary aspects of species age and extinction probability to produce testable predictions on ADE patterns. CRT’s domain is the diversification dynamics of two or more clades competing for environmental space throughout time, and its propositions or derived hypotheses are as follows: (i) incumbency effects by an early arriving clade that limit the colonization and the diversification of a younger clade leading to a negative ADE scenario (younger species more prone to extinction than older ones) and (ii) an ecological shift triggered by an environmental change that imposes a new selective regime over the environmental space and leads to a positive ADE scenario (extinction probability increasing with age). From these propositions, we developed the prediction that the ADE scenario would be defined by whether an ecological shift happens or not. We discuss how the CRT could be tested with empirical data and provide examples where it could be applied. We hope this article will provide a common ground to unify results from different fields and foster new empirical tests of the mechanisms derived here while providing insights into CRT theoretical structuration.
  • High specificity of symbiont-conferred resistance in an aphid-parasitoid field community
    Item type: Journal Article
    Gimmi, Elena; Vorburger, Christoph (2024)
    Journal of Evolutionary Biology
    Host-parasite coevolution is mediated by genetic interactions between the antagonists and may lead to reciprocal adaptation. In the black bean aphid, Aphis fabae fabae, resistance to parasitoids can be conferred by the heritable bacterial endosymbiont Hamiltonella defensa. H. defensa has been shown to be variably protective against different parasitoid species, and different genotypes of the black bean aphid's main parasitoid Lysiphlebus fabarum. However, these results were obtained using haphazard combinations of laboratory-reared insect lines with different origins, making it unclear how representative they are of natural, locally (co)adapted communities. We therefore comprehensively sampled the parasitoids of a natural A. f. fabae population and measured the ability of the five most abundant species to parasitize aphids carrying the locally prevalent H. defensa haplotypes. H. defensa provided resistance only against the dominant parasitoid L. fabarum (70% of all parasitoids), but not against less abundant parasitoids, and resistance to L. fabarum acted in a genotype-specific manner (G x G interactions between H. defensa and L. fabarum). These results confirm that strong species- and genotype-specificity of symbiont-conferred resistance is indeed a hallmark of wild A. f. fabae populations, and they are consistent with symbiont-mediated adaptation of aphids to the parasitoids posing the highest risk.
  • A test of specific adaptation to symbiont-conferred host resistance in natural populations of a parasitoid wasp
    Item type: Journal Article
    Henry, Youn; Dahirel, Maxime; Wallisch, Jesper; et al. (2025)
    Journal of Evolutionary Biology
    Parasitoids are important natural enemies of insects, imposing strong selection for the evolution of resistance. In aphids, the heritable endosymbiont Hamiltonella defensa is a key determinant of resistance, making symbiont-conferred defence a potential target for specific adaptation by parasitoids. We tested this hypothesis in the aphid parasitoid Lysiphlebus fabarum and four of its host species, Aphis fabae fabae, A. hederae, A. urticata, and A. ruborum. The parasitoids show host-associated genetic differentiation indicative of host specialization, and each of these aphid species harbours their own 1-3 distinct strains of H. defensa. We introduced eight H. defensa strains from all four aphid species into a common host background (a laboratory strain of symbiont-free A. fabae fabae) and then tested the ability of 35 field-collected L. fabarum lines from the same four hosts to parasitize the H. defensa-carrying aphids. The origin of symbionts affected parasitism success, with strains from A. fabae fabae and A. hederae conferring strong protection, and strains from A. urticata and A. ruborum providing virtually no protection. For one strain each from A. fabae fabae and A. hederae, we found a signature of specific adaptation by parasitoids, as parasitoids able to overcome their protection mostly came from the same hosts as the symbiont strains. Two other strains were so strongly protective that they permitted very little parasitism independent of where parasitoids came from. While not fully conclusive, these results are consistent with specialized parasitoids adapting to certain defensive symbionts of their host species, supporting the notion of symbiont-mediated coevolution.
  • Evolution of intermediate latency strategies in seasonal parasites
    Item type: Journal Article
    MacDonald, Hannelore; Brisson, Dustin (2024)
    Journal of Evolutionary Biology
    Traditional mechanistic trade-offs between transmission and parasite latency period length are foundational for nearly all theories on the evolution of parasite life-history strategies. Prior theoretical studies demonstrate that seasonal host activity can generate a trade-off for obligate-host killer parasites that selects for intermediate latency periods in the absence of a mechanistic trade-off between transmission and latency period lengths. Extensions of these studies predict that host seasonal patterns can lead to evolutionary bistability for obligate-host killer parasites in which two evolutionarily stable strategies, a shorter and longer latency period, are possible. Here we demonstrate that these conclusions from previously published studies hold for non-obligate host killer parasites. That is, seasonal host activity can select for intermediate parasite latency periods for non-obligate killer parasites in the absence of a trade-off between transmission and latency period length and can maintain multiple evolutionarily stable parasite life-history strategies. These results reinforce the hypothesis that host seasonal activity can act as a major selective force on parasite life-history evolution by extending the narrower prior theory to encompass a greater range of disease systems.
Publications 1 - 8 of 8