Evolutionary and demographic consequences of temperature-induced masculinization under climate warming: the effects of mate choice

Nemesházi, Edina; Kövér, Szilvia; Bókony, Veronika

doi:10.1186/s12862-021-01747-3

Cited by 22 publications

(27 citation statements)

References 63 publications

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“…In such species, environmental influences can override the effect of genes during sex determination in early life, resulting in sex reversal whereby individuals develop phenotypic sex discordant with their genetic sex (Alho et al, 2010;Baroiller and D'Cotta, 2016;Holleley et al, 2016;Lambert et al, 2019;Nemesházi et al, 2020). Theoretical studies predict that sex reversal has far-reaching consequences for demography, population persistence, sex chromosome loss and evolutionary transitions between sex-determination systems (Grossen et al, 2011;Quinn et al, 2011;Bókony et al, 2017;Wedekind, 2017;Schwanz et al, 2020;Nemesházi et al, 2021). Studying these consequences empirically is especially important in light of the ongoing rapid human-induced environmental alterations, including climate change and chemical pollution, which may increase sex-reversal frequency in nature (Nemesházi et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…Understanding this issue would be highly valuable for at least three reasons. First, it would facilitate forecasting the effects of sex reversal on demography and evolution, because many of these theoretically predicted effects critically depend on the viability and reproductive success of sex-reversed individuals (Grossen et al, 2011;Bókony et al, 2017;Nemesházi et al, 2021). Second, it would provide insight into the ultimate and/or proximate drivers of sex reversal.…”

Section: Introductionmentioning

confidence: 99%

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Sex Reversal and Performance in Fitness-Related Traits During Early Life in Agile Frogs

et al. 2021

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Sex reversal is a mismatch between genetic sex (sex chromosomes) and phenotypic sex (reproductive organs and secondary sexual traits). It can be induced in various ectothermic vertebrates by environmental perturbations, such as extreme temperatures or chemical pollution, experienced during embryonic or larval development. Theoretical studies and recent empirical evidence suggest that sex reversal may be widespread in nature and may impact individual fitness and population dynamics. So far, however, little is known about the performance of sex-reversed individuals in fitness-related traits compared to conspecifics whose phenotypic sex is concordant with their genetic sex. Using a novel molecular marker set for diagnosing genetic sex in agile frogs (Rana dalmatina), we investigated fitness-related traits in larvae and juveniles that underwent spontaneous female-to-male sex reversal in the laboratory. We found only a few differences in early life growth, development, and larval behavior between sex-reversed and sex-concordant individuals, and altogether these differences did not clearly support either higher or lower fitness prospects for sex-reversed individuals. Putting these results together with earlier findings suggesting that sex reversal triggered by heat stress may be associated with low fitness in agile frogs, we propose the hypothesis that the fitness consequences of sex reversal may depend on its etiology.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Sex Reversal and Performance in Fitness-Related Traits During Early Life in Agile Frogs

et al. 2021

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“…They may adjust their allocation patterns to a given environment in an economical manner [ 6 , 7 ]. This allocation flexibility, in response to environmental variations, is thought to maximise the growth rate or fitness of plants to increase competition [ 8 – 10 ]. In dense populations, plants usually allocate more biomass to aboveground parts, maximising light assimilation and photosynthesis by increasing height [ 11 ].…”

Section: Introductionmentioning

confidence: 99%

The significance of biomass allocation to population growth of the invasive species Ambrosia artemisiifolia and Ambrosia trifida with different densities

Zhao

Liu

et al. 2021

BMC Ecol Evo

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Background Ambrosia artemisiifolia and Ambrosia trifida are globally distributed harmful and invasive weeds. High density clusters play an important role in their invasion. For these two species, the early settled populations are distributed at low densities, but they can rapidly achieve high population densities in a short period of time. However, their response to intraspecific competition to improve the fitness for rapid growth and maintenance of high population densities remains unclear. Therefore, to determine how these species form and maintain high population densities, individual biomass allocations patterns between different population densities (low and high), and plasticity during seedling, vegetative, breeding and mature stages were compared. In 2019, we harvested seeds at different population densities and compared them, and in 2020, we compared the number of regenerated plants across the two population densities. Results Most biomass was invested in the stems of both species. Ambrosia trifida had the highest stem biomass distribution, of up to 78%, and the phenotypic plasticity of the stem was the highest. Path analysis demonstrated that at low-density, total biomass was the biggest contributor to seed production, but stem and leaf biomass was the biggest contributors to high-density populations. The number of seeds produced per plant was high in low-density populations, while the seed number per unit area was huge in high-density populations. In the second year, the number of low-density populations increased significantly. A. artemisiifolia and A. trifida accounted for 75.6% and 68.4% of the mature populations, respectively. Conclusions High input to the stem is an important means to regulate the growth of the two species to cope with different densities. These two species can ensure reproductive success and produce appropriate seed numbers. Therefore, they can maintain a stable population over time and quickly form cluster advantages. In the management, early detection of both species and prevention of successful reproduction by chemical and mechanical means are necessary to stop cluster formation and spread.

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“…Due to their sex-chromosome genotype, sex-reversed individuals may be unable to produce daughters or sons (Wedekind, 2017), and therefore may be selected against by sex-ratio selection (Schwanz & Georges, 2021;see also Fig S11a,d in Nemesházi et al, 2021a). Also, sex-reversed individuals may perform poorly in traits that influence survival (Mikó et al, 2021;Nemesházi et al, 2020) or sexually selected traits (Nemesházi, Kövér, et al, 2021). In such situations, we can expect resistance to sex reversal to be adaptive in environments where sex-reversing stressors are pervasive.…”

Section: Introductionmentioning

confidence: 99%

“…In ectothermic animals, various environmental stimuli can cause a developmental effect rarely seen in endotherms: sex reversal, whereby individuals exposed to such stimuli during their embryonic or larval life-phase develop the sexual phenotype opposite to their genetic sex (Baroiller & D'Cotta, 2016;Flament, 2016;Whiteley, Castelli, Dissanayake, Holleley, & Georges, 2021). Sex reversal occurs in fish, amphibians, and reptiles in nature (Alho, Matsuba, & Merilä, 2010;Baroiller & D'Cotta, 2016;Lambert, Tran, Kilian, Ezaz, & Skelly, 2019;Nemesházi et al, 2020;Whiteley et al, 2021;Xu et al, 2021), and theoretical studies caution that it may have far-reaching consequences including skewed sex ratios, sex-chromosome evolution, and even population extinction (Bókony, Kövér, Nemesházi, Liker, & Székely, 2017;Grossen, Neuenschwander, & Perrin, 2011;Nemesházi, Kövér, & Bókony, 2021;Perrin, 2009;Schwanz, Georges, Holleley, & Sarre, 2020;Wedekind, 2017). Laboratory experiments show that sex reversal can be induced by anthropogenic stressors like chemical pollution and elevated temperature (Flament, 2016;Lambert, Smylie, Roman, Freidenburg, & Skelly, 2018;Mikó et al, 2021;Tamschick et al, 2016), thus, we may expect that the contemporary and future increase in the levels of anthropogenic stressors will influence the rates of sex reversal in freeliving populations of ectothermic vertebrates.…”

Section: Introductionmentioning

confidence: 99%

Novel genetic sex markers reveal unexpected lack of, and similar susceptibility to, sex reversal in free-living common toads in both natural and anthropogenic habitats

Nemesházi

Sramkó

Laczkó

et al. 2021

Preprint

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Anthropogenic environmental changes are affecting biodiversity and microevolution worldwide. Ectothermic vertebrates are especially vulnerable, since their sexual development can be disrupted by environmental changes, which can cause sex reversal, a mismatch between genetic and phenotypic sex, potentially leading to sex-ratio distortion and population decline. Despite these implications, we have scarce empirical knowledge on the incidence of sex reversal in nature. Populations in anthropogenic environments may experience sex reversal more frequently, or alternatively, they may adapt to resist sex reversal. To test these alternative hypotheses, we developed PCR-based genetic sex markers for the common toad (Bufo bufo). We assessed the prevalence of sex reversal in wild populations living in natural, agricultural and urban habitats, and the susceptibility of the same populations to two ubiquitous estrogenic pollutants in a common-garden experiment. We found negligible sex-reversal frequency in free-living adults despite the presence of various endocrine-disrupting pollutants in their breeding ponds. Individuals from different habitat types showed similar susceptibility to sex reversal in the laboratory: all genetic males developed female phenotype when exposed to 1 µg/L 17α- ethinylestradiol (EE2) during larval development, whereas no sex reversal occurred in response to 1 ng/L EE2 and a glyphosate-based herbicide with 3 µg/L or 3 mg/L glyphosate. The latter results do not support that populations in anthropogenic habitats would have either increased propensity for or higher tolerance to chemically induced sex reversal. Thus, the surprisingly low sex-reversal frequency in wild toads compared to other ectothermic vertebrates studied before might indicate idiosyncratic, potentially species-specific resistance to sex reversal.

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Evolutionary and demographic consequences of temperature-induced masculinization under climate warming: the effects of mate choice

Cited by 22 publications

References 63 publications

Sex Reversal and Performance in Fitness-Related Traits During Early Life in Agile Frogs

Sex Reversal and Performance in Fitness-Related Traits During Early Life in Agile Frogs

The significance of biomass allocation to population growth of the invasive species Ambrosia artemisiifolia and Ambrosia trifida with different densities

Novel genetic sex markers reveal unexpected lack of, and similar susceptibility to, sex reversal in free-living common toads in both natural and anthropogenic habitats

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