From metamorphosis to maturity in complex life cycles: equal performance of different juvenile life history pathways

Schmidt, Benedikt R.; Hödl, Walter; Schaub, Michael

doi:10.1890/11-0892.1

Cited by 81 publications

(69 citation statements)

References 51 publications

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“…Our results indicate that survival differs between ontogenetic stages and that the survival rate increases with age. This is in accordance with previous studies suggesting that post‐metamorphosis survival is positively correlated with age and size in vertebrates (Stearns, ), and especially in amphibians (Altwegg & Reyer, ; Schmidt, Hödl & Schaub, ). In the latter, larger and older individuals outperform smaller and younger ones in osmoregulation and hydroregulation performance (Wells, ), which decreases mortality risks and the cost of biological functions such as dispersal.…”

Section: Discussionmentioning

confidence: 98%

Slow life history and rapid extreme flood: demographic mechanisms and their consequences on population viability in a threatened amphibian

et al. 2015

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Summary In the Northern Hemisphere, an increase in both the frequency and magnitude of violent flooding events has been reported due to climate change. According to life history theory, one might postulate that in ‘slow’ species: (i) environmental canalisation may act as a selective force that minimises to some extent adult survival variations caused by catastrophic flood and (ii) extreme flooding events would cause important variations in recruitment and young survival. Hence, it may be hypothesised that (iii) the population growth rate of ‘slow’ species might be relatively insensitive to changes in the frequency of extreme climatic events if adult survival remains largely unaffected. In this study, we investigated how extreme rainfall events resulting in severe flood impact population dynamics of a long‐lived endangered amphibian, the yellow‐bellied toad (Bombina variegata: Bombinatoridae). To address this issue, we used capture–recapture (CR) data collected on two populations (768 and 1154 individuals identified) in southern France and developed multi‐event CR models. Our results indicated that extreme flooding did not cause any variation in sub‐adult or adult survival, whereas recruitment and juvenile survival were negatively impacted. Furthermore, our simulations indicated that the population growth rate was only marginally sensitive to potential changes in the frequency of extreme flooding in the future. Hence, we suggest that extreme flooding does not appear to be a proximal factor of extinction risk for this endangered amphibian species.

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Section: Discussionmentioning

confidence: 98%

Slow life history and rapid extreme flood: demographic mechanisms and their consequences on population viability in a threatened amphibian

et al. 2015

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“…Indeed, in vertebrates including amphibians catch-up growth is associated with permanently altered HPI axis activity and may be related to differing coping styles to extrinsic stressors [60], [64]. Another intrinsic factor that may be related to these hatching time, development and growth patterns is sex [65]. Studies of birds have found hatching to differ among the sexes and to potentially be an adaptive maternal effect [49]–[51].…”

Section: Discussionmentioning

confidence: 99%

Physiological, Behavioral and Maternal Factors That Contribute to Size Variation in Larval Amphibian Populations

2013

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Size variance among similarly aged individuals within populations is a pattern common to many organisms that is a result of interactions between intrinsic and extrinsic traits of individuals. While genetic and maternal effects, as well as physiological and behavioral traits have been shown to contribute to size variation in animal populations, teasing apart the influence of such factors on individual growth rates remain a challenge. Furthermore, tracing the effects of these interactions across life stages and in shaping adult phenotypes also requires further exploration. In this study we investigated the relationship between genetics, hatching patterns, behaviors, neuroendocrine stress axis activity and variance in growth and metamorphosis among same-aged larval amphibians. Through parallel experiments we found that in the absence of conspecific interactions, hatch time and to a lesser extent egg clutch identity (i.e. genetics and maternal effects) influenced the propensity for growth and development in individual tadpoles and determined metamorphic traits. Within experimental groups we found that variance in growth rates was associated with size-dependent foraging behaviors and responses to food restriction. We also found an inverse relationship between glucocorticoid (GC) hormone levels and body mass and developmental stage among group-reared tadpoles, which suggests that GC expression plays a role in regulating differing within-population growth trajectories in response to density-dependent conditions. Taken together these findings suggest that factors that influence hatching conditions can have long-term effects on growth and development. These results also raise compelling questions regarding the extent to which maternal and genetic factors influence physiological and behavioral profiles in amphibians.

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“…Thus, while larval life stages may be viable targets for remediation, preservation of sufficient high-quality adult habitat remains critical (Harper et al 2008) and additional experiments examining effects of contaminants on terrestrial adult amphibians are needed (Hopkins and Rowe 2010). Moreover, because reductions in body size are a common sublethal effect of contaminants (Boone and Bridges 2003) that may persist into terrestrial life stages (Todd et al 2012), future studies should rigorously evaluate size-specific survival of amphibians in field (e.g., Schmidt et al 2012). Finally, our study provides a habitat-based framework (Akcakaya 2000) for incorporating environmental stochasticity into models of population-level responses of amphibians to ecological or environmental stressors.…”

Section: Discussionmentioning

confidence: 99%

Making leaps in amphibian ecotoxicology: translating individual‐level effects of contaminants to population viability

Willson

Hopkins

Bergeron

et al. 2012

Ecological Applications

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Abstract. Concern that environmental contaminants contribute to global amphibian population declines has prompted extensive experimental investigation, but individual-level experimental results have seldom been translated to population-level processes. We used our research on the effects of mercury (Hg) on American toads (Bufo americanus) as a model for bridging the gap between individual-level contaminant effects and amphibian population viability. We synthesized the results of previous field and laboratory studies examining effects of Hg throughout the life cycle of B. americanus and constructed a comprehensive demographic population model to evaluate the consequences of Hg exposure on population dynamics. Our model explicitly considered density-dependent larval survival, which is known to be an important driver of amphibian population dynamics, and incorporated two important factors that have seldom been considered in previous amphibian modeling studies: environmental stochasticity and sublethal effects. We demonstrated that decreases in embryonic survival and sublethal effects (e.g., reduced body size) that delay maturation have minor effects on population dynamics, whereas contaminant effects that reduce late-larval or post-metamorphic survival have important population-level consequences. We found that excessive Hg exposure through maternal transfer or larval diet, alone, had minor effects on B. americanus populations. Simultaneous maternal and dietary exposure resulted in reduced population size and a dramatic increase in extinction probability, but explicit prediction of population-level effects was dependent on the strength of larval density dependence. Our results suggest that environmental contaminants can influence amphibian population viability, but that highly integrative approaches are needed to translate individual-level effects to populations.

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From metamorphosis to maturity in complex life cycles: equal performance of different juvenile life history pathways

Cited by 81 publications

References 51 publications

Slow life history and rapid extreme flood: demographic mechanisms and their consequences on population viability in a threatened amphibian

Slow life history and rapid extreme flood: demographic mechanisms and their consequences on population viability in a threatened amphibian

Physiological, Behavioral and Maternal Factors That Contribute to Size Variation in Larval Amphibian Populations

Making leaps in amphibian ecotoxicology: translating individual‐level effects of contaminants to population viability

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