Regional epigenetic variation in asexual snail populations among urban and rural lakes

Thorson, Jennifer L. M.; Smithson, Mark W.; Sadler‐Riggleman, Ingrid; Beck, Daniel; Dybdahl, Mark F.; Skinner, Michael K.

doi:10.1093/eep/dvz020

Cited by 24 publications

(18 citation statements)

References 32 publications

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“…Alteration of environmental conditions (i.e. water flow) was found to associate with adaptive phenotypic variation that correlated with epigenetic alterations [ 117 , 118 ]. Chrosomus eos-neogaeus is a hybrid clonal fish that inhabits lakes and intermittent stream environments that has epigenetic variation in the divergent environments [ 119 , 120 ].…”

Section: Epigenetic Transgenerational Inheritance and Evolutionmentioning

confidence: 99%

Role of environmentally induced epigenetic transgenerational inheritance in evolutionary biology: Unified Evolution Theory

Skinner

Nilsson

2021

Environmental Epigenetics

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The current evolutionary biology theory primarily involves genetic alterations and random DNA sequence mutations to generate the phenotypic variation required for Darwinian natural selection to act. This neo-Darwinian evolution is termed the Modern Evolution Synthesis and has been the primary paradigm for nearly 100 years. Although environmental factors have a role in neo-Darwinian natural selection, Modern Evolution Synthesis does not consider environment to impact the basic molecular processes involved in evolution. An Extended Evolutionary Synthesis has recently developed that extends the modern synthesis to consider non-genetic processes. Over the past few decades, environmental epigenetics research has been demonstrated to regulate genetic processes and directly generate phenotypic variation independent of genetic sequence alterations. Therefore, the environment can on a molecular level through non-genetic (i.e. epigenetic) mechanisms directly influence phenotypic variation, genetic variation, inheritance and adaptation. This direct action of the environment to alter phenotype that is heritable is a neo-Lamarckian concept that can facilitate neo-Darwinian (i.e. Modern Synthesis) evolution. The integration of genetics, epigenetics, Darwinian theory, Lamarckian concepts, environment, and epigenetic inheritance provides a paradigm shift in evolution theory. The role of environmental-induced epigenetic transgenerational inheritance in evolution is presented to describe a more unified theory of evolutionary biology.

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Section: Epigenetic Transgenerational Inheritance and Evolutionmentioning

confidence: 99%

Role of environmentally induced epigenetic transgenerational inheritance in evolutionary biology: Unified Evolution Theory

Skinner

Nilsson

2021

Environmental Epigenetics

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“…Modifications in DNA methylation have been shown to associate with anthropogenic‐linked factors including feeding on anthropogenic‐provided food in baboons (Lea et al., 2016), exposure to pollution in humans (Baccarelli et al., 2009), and stress resilience in response to handling in tree swallows (Taff et al., 2019). A few studies have specifically investigated epigenetic variation in wild animals in the context of urbanization, revealing varied patterns (Garcia et al., 2019; McNew et al., 2017; Riyahi et al., 2015; Thorson et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

Urbanization is associated with modifications in DNA methylation in a small passerine bird

Watson

Powell

Salmón

et al. 2020

Evolutionary Applications

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Urbanization represents a fierce driver of phenotypic change, yet the molecular mechanisms underlying observed phenotypic patterns are poorly understood. Epigenetic changes are expected to facilitate more rapid adaption to changing or novel environments, such as our towns and cities, compared with slow changes in gene sequence. A comparison of liver and blood tissue from great tits Parus major originating from an urban and a forest site demonstrated that urbanization is associated with variation in genome‐wide patterns of DNA methylation. Combining reduced representation bisulphite sequencing with transcriptome data, we revealed habitat differences in DNA methylation patterns that suggest a regulated and coordinated response to the urban environment. In the liver, genomic sites that were differentially methylated between urban‐ and forest‐dwelling birds were over‐represented in regulatory regions of the genome and more likely to occur in expressed genes. DNA methylation levels were also inversely correlated with gene expression at transcription start sites. Furthermore, differentially methylated CpG sites, in liver, were over‐represented in pathways involved in (i) steroid biosynthesis, (ii) superoxide metabolism, (iii) secondary alcohol metabolism, (iv) chylomicron remodelling, (v) cholesterol transport, (vi) reactive oxygen species (ROS) metabolic process and (vii) epithelial cell proliferation. This corresponds with earlier studies identifying diet and exposure to ROS as two of the main drivers of divergence between organisms in urban and nonurban environments. Conversely, in blood, sites that were differentially methylated between urban‐ and forest‐dwelling birds were under‐represented in regulatory regions, more likely to occur in nonexpressed genes and not over‐represented in specific biological pathways. It remains to be determined whether diverging patterns of DNA methylation represent adaptive evolutionary responses and whether the conclusions can be more widely attributed to urbanization.

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“…The resulting populations have evolved habitat-specific differences in shell shape that were correlated with water current speed. [35,36] Methylated DNA immunoprecipitation (MeDIP) and Illumina sequencing of foot pad tissue from single specimens revealed significant genome-wide DNA methylation differences between lakes and rivers despite virtual genetic identity. [35,36] Epigenetic variation most likely helped to establish adaptive phenotypic plasticity in the invasive snail in less than 100 generations.…”

Section: Dependence Of Epigenetic Variation From Genetic Variationmentioning

confidence: 99%

“…[35,36] Methylated DNA immunoprecipitation (MeDIP) and Illumina sequencing of foot pad tissue from single specimens revealed significant genome-wide DNA methylation differences between lakes and rivers despite virtual genetic identity. [35,36] Epigenetic variation most likely helped to establish adaptive phenotypic plasticity in the invasive snail in less than 100 generations. This example suggests that in asexual reproducers epigenetic variation is largely independent from genetic variation.…”

Section: Dependence Of Epigenetic Variation From Genetic Variationmentioning

confidence: 99%

Paradigm shifts in animal epigenetics: Research on non‐model species leads to new insights into dependencies, functions and inheritance of DNA methylation

Vogt

2022

BioEssays

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Recent investigations with non-model species and whole-genome approaches have challenged several paradigms in animal epigenetics. They revealed that epigenetic variation in populations is not the mere consequence of genetic variation, but is a semi-independent or independent source of phenotypic variation, depending on mode of reproduction. DNA methylation is not positively correlated with genome size and phylogenetic position as earlier believed, but has evolved differently between and within higher taxa. Epigenetic marks are usually not completely erased in the zygote and germ cells as generalized from mouse, but often persist and can be transgenerationally inherited, making them evolutionarily relevant. Gene body methylation and promoter methylation are similar in vertebrates and invertebrates with well methylated genomes but transposon silencing through methylation is variable. The new data also suggest that animals use epigenetic mechanisms to cope with rapid environmental changes and to adapt to new environments. The main benefiters are asexual populations, invaders, sessile taxa and long-lived species.

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Regional epigenetic variation in asexual snail populations among urban and rural lakes

Cited by 24 publications

References 32 publications

Role of environmentally induced epigenetic transgenerational inheritance in evolutionary biology: Unified Evolution Theory

Role of environmentally induced epigenetic transgenerational inheritance in evolutionary biology: Unified Evolution Theory

Urbanization is associated with modifications in DNA methylation in a small passerine bird

Paradigm shifts in animal epigenetics: Research on non‐model species leads to new insights into dependencies, functions and inheritance of DNA methylation

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