The role of transgenerational epigenetic inheritance in diversification and speciation

Pfennig, David W.; Servedio, Maria R.

doi:10.2478/ngi-2013-0002

Cited by 24 publications

(13 citation statements)

References 97 publications

(88 reference statements)

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“…Only recently has divergence in DNA methylation been proposed as a possible aid in speciation (Flatscher et al . ; Pfenning & Servedio ; Smith & Ritchie ), and several cases in the literature support this hypothesis (Shaposhnikov ; Field et al . ; Anway et al .…”

Section: Introductionmentioning

confidence: 85%

“…Epigenetic contributions to speciation, and reproductive isolation specifically, are poorly understood, but have seen increased interest in recent years (reviewed in Smith & Ritchie ; Pfenning & Servedio ; Lafon‐Placette & Köhler ; Skinner ). Perhaps the best‐studied epigenetic contributors to reproductive isolation in animals are learning (reviewed in Verzijden et al .…”

Section: Discussionmentioning

confidence: 99%

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Epigenetic divergence as a potential first step in darter speciation

et al. 2016

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Recent studies show that epigenetic variation in the form of DNA methylation may serve as a substrate for selection. Theory suggests that heritable epigenetic marks that increase fitness should increase in frequency in a population, and these changes may result in novel morphology, behaviour, or physiology, and ultimately reproductive isolation. Therefore, epigenetic variation might provide the first substrate for selection during the course of evolutionary divergence. This hypothesis predicts that populations in the earliest stages of divergence will differentiate in their methylome prior to any genetic differentiation. While several studies have investigated natural epigenetic variation, empirical studies that test predictions about its role in speciation are surprisingly scarce. Here, we investigate DNA methylation variation using an isoschizomeric digest method, Methyl-Sensitive Amplified Polymorphism, across multiple stages of evolutionary divergence in natural populations of North American stream fishes. We show that epigenetic differentiation between methylomes is greater than genetic divergence among closely related populations across two river drainages. Additionally, we demonstrate that epigenetic divergence is a stronger predictor of the strength of behavioural reproductive isolation and suggest that changes in the methylome could influence the evolution of reproductive isolation between species. Our findings suggest a role for epigenetics not only in the initiation of divergence, but also in the maintenance of species boundaries over greater evolutionary timescales.

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Section: Introductionmentioning

confidence: 85%

Section: Discussionmentioning

confidence: 99%

Epigenetic divergence as a potential first step in darter speciation

et al. 2016

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“…body size, ornamentation, condition) and mating preferences for these traits can be altered by G Â E and parental effects [18]. However, empirical studies explicitly demonstrating the interaction between parental environment, offspring environment and offspring mate choice are scarce (but see examples of sexual imprinting [19,20]).…”

Section: Introductionmentioning

confidence: 99%

Within-generation and transgenerational plasticity of mate choice in oceanic stickleback under climate change

Fuxjäger

Wanzenböck

Ringler

et al. 2019

Phil. Trans. R. Soc. B

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One contribution of 13 to a theme issue 'The role of plasticity in phenotypic adaptation to rapid environmental change'.Plasticity, both within and across generations, can shape sexual traits involved in mate choice and reproductive success, and thus direct measures of fitness. Especially, transgenerational plasticity (TGP), where parental environment influences offspring plasticity in future environments, could compensate for otherwise negative effects of environmental change on offspring sexual traits. We conducted a mate choice experiment using stickleback (Gasterosteus aculeatus) with different thermal histories (ambient 178C or elevated 218C) within and across generations under simulated ocean warming using outdoor mesocosms. Parentage analysis of egg clutches revealed that maternal developmental temperature and reproductive (mesocosm) environment affected egg size, with females that developed at 178C laying smaller eggs in 218C mesocosms, likely owing to metabolic costs at elevated temperature. Paternal developmental temperature interacted with the reproductive environment to influence mating success, particularly under simulated ocean warming, with males that developed at 218C showing lower overall mating success compared with 178C males, but higher mating success in 218C mesocosms. Furthermore, mating success of males was influenced by the interaction between F1 developmental temperature and F0 parent acclimation temperature, demonstrating the potential role of both TGP and within-generation plasticity in shaping traits involved in sexual selection and mate choice, potentially facilitating rapid responses to environmental change.This article is part of the theme issue 'The role of plasticity in phenotypic adaptation to rapid environmental change'.

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“…Justification for this 410 approach is as follows: in general, rDNA is a stable molecule that is widely used to infer the presence (and potential activity) of a population. In contrast, rRNA is an ephemeral molecule 412 that is only produced by growing cells, which require ribosomes for protein synthesis (95 Last, epigenetic processes can also affect the temporal scale of eco-evolutionary 420 processes by allowing organisms to rapidly respond to environmental signals and pass this response on to its offspring (99). Epigenetic processes refer to non-genetic mechanisms (i.e., not 422 directly related to differences in nucleotide sequence) that cause variability in gene expression that can result in phenotypic variation subject to natural selection.…”

Section: F Temporal Scale and The Evolutionary Ecology Of Microbes -mentioning

confidence: 99%

Evolutionary ecology of microorganisms: from the tamed to the wild

Lennon

Denef

2015

Preprint

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PrePrints 2 ABSTRACTAn overarching goal of biology is to understand how evolutionary and ecological processes 24 generate and maintain biodiversity. While evolutionary biologists interested in biodiversity tend to focus on the mechanisms controlling rates of evolution and how this influences the 26 phylogenetic relationship among species, ecologists attempt to explain the distribution and abundance of taxa based upon interactions among species and their environment. Recently, a 28 more concerted effort has been made to integrate some of the theoretical and empirical approaches from the fields of ecology and evolutionary biology. This integration has been 30 motivated in part by the growing evidence that evolution can happen on "rapid" or contemporary time scales, suggesting that eco-evolutionary feedbacks can alter system dynamics in ways that 32 cannot be predicted based on ecological principles alone. As such, it may be inappropriate to ignore evolutionary processes when attempting to understand ecological phenomena in natural 34 and managed ecosystems. In this chapter, we highlight why it is particularly important to consider eco-evolutionary feedbacks for microbial populations. We emphasize some of the major 36 processes that are thought to influence the strength of eco-evolutionary dynamics, provide an overview of methods used to quantify the relative importance of ecology and evolution, and 38showcase the importance of considering evolution in a community context and how this may influence the dynamics and stability of microbial systems under novel environmental conditions. HIGHLIGHTS• Evolutionary processes can occur on "rapid" or contemporary time scales 48• Rapid evolution may be particularly important for understanding dynamics of microbial systems 50• Evolutionary change can influence ecological processes, which can result in feedbacks that influence system behavior 52 A. Overview: interplay between ecological and evolutionary processes 54An overarching goal of biology is to understand how evolutionary and ecological processes generate and maintain biodiversity. Despite this seemingly unified goal, historically, 56 the fields of evolutionary biology and ecology have largely advanced in isolation of one another.While evolutionary biologists interested in biodiversity tend to focus on the mechanisms 58 controlling rates of evolution and how this influences the phylogenetic relationship among species, ecologists attempt to explain the distribution and abundance of taxa based upon 60 interactions among species and their environment. Recently, a more concerted effort has been made to integrate some of the theoretical and empirical approaches from the fields of ecology 62 and evolutionary biology. This integration has been motivated in part by the growing evidence that evolution can happen on "rapid" or contemporary time scales (1). When this occurs, 64 evolutionary changes can select for functional traits and behaviors of species in ways that influence ecological processes, such as population dynamics, th...

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The role of transgenerational epigenetic inheritance in diversification and speciation

Cited by 24 publications

References 97 publications

Epigenetic divergence as a potential first step in darter speciation

Epigenetic divergence as a potential first step in darter speciation

Within-generation and transgenerational plasticity of mate choice in oceanic stickleback under climate change

Evolutionary ecology of microorganisms: from the tamed to the wild

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