Maternal effects on phenotypic plasticity in larvae of the salamander Hynobius retardatus

Michimae, Hirofumi; Nishimura, Kinya; Tamori, Yoichiro; Wakahara, Masami

doi:10.1007/s00442-009-1319-8

Cited by 18 publications

(28 citation statements)

References 43 publications

(54 reference statements)

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“…Offspring from larger cockroach, echinoid, salamander and frog eggs have higher phenotypic plasticity (Doughty 2002, Holbrook andSchal 2004;McAlister 2007;Michimae et al, 2009;Martin and Pfennig, 2010). This study suggests that with evolutionary egg size increases, more traits are added to the suite of traits responding to egg size variation and the response of each trait to yolk quantity variation increases.…”

Section: Trait Integration Evolution Of Plasticity and The Value Ofmentioning

confidence: 74%

“…Smith and Fretwell 1974) (Grime 1979) and a previous study of the responses of A. barbouri and A. texanum to oxygen (Landberg 2010) suggest that low-resource environments select for phenotypes that are stress tolerant and have low magnitudes of plasticity whereas high-resource environments select for phenotypes that have the ability to take advantage of resources and have high plasticity. Empirical support for an increase in phenotypic plasticity with egg size comes from both within and between species (McAlister 2007; Michimae et al, 2009). If high maternal investment in yolk has acted as a high-resource selective environment, phenotypic plasticity is expected to increase in A. barbouri.…”

Section: Introductionmentioning

confidence: 99%

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Evolution of maternal egg size effects in sister salamander species

Landberg

2014

Int. J. Dev. Biol.

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Egg size varies genetically and with the maternal environment. It is correlated with and can act as a resource fueling variation in many other key life history traits. This study examined hypotheses about how plastic responses of offspring to yolk variation evolve (and contribute to phenotypic evolution) when maternal investment in egg size evolves. I used a split-clutch, controlled, surgical experiment with a longitudinal (repeated-measures) design to examine the effects of yolk removal on sister salamander species with distinct egg and larval phenotypes. Yolk removal had large effects in the derived larger-egged species, A. barbouri, and greatly reduced effects in A. texanum. Early hatching and smaller larval body size was only found in A. barbouri and survival rates decreased more in A. barbouri. These results provide strong experimental evidence that as female salamanders evolve greater yolk investment in each egg, offspring coevolve an increased magnitude of phenotypic plasticity in response to yolk variation across a suite of life history traits. Yolk therefore acts as an integrator of phenotypes that allows females to modify modules of life history traits together (facilitating adaptation). When organisms invade new environments, complex integrated phenotypes may evolve via correlated responses to increased maternal investment, yet individual traits can be coupled or decoupled to yolk quantity variation in different species.

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Section: Trait Integration Evolution Of Plasticity and The Value Ofmentioning

confidence: 74%

Section: Introductionmentioning

confidence: 99%

Evolution of maternal egg size effects in sister salamander species

Landberg

2014

Int. J. Dev. Biol.

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“…Clutches were then returned to the aviary and reared in 10 l of aged tap water. Subsamples were weighed, counted (range: 13 -40 eggs sample 21 ), photographed underwater against a scale bar, then freeze-dried at 2518C with a vacuum of 0.120 mbar for 24 h (eggs dried in 2013 only). Mean dry egg mass was then calculated from the three subsamples.…”

Section: Materials and Methods (A) Experimental Design And Data Collecmentioning

confidence: 99%

“…Larger larval size can also confer an advantage in coping with both abiotic [19,20] and biotic [9,16] stressors. Maternal influence on egg size can also alter the probability of offspring developing a competitive morphology under crowded conditions [21]. Thus, maternal provisioning influences the expression of plasticity through variation in offspring body size.…”

Section: Introductionmentioning

confidence: 99%

Maternal body condition influences magnitude of anti-predator response in offspring

Bennett

Murray

2014

Proc. R. Soc. B.

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Organisms exhibit plasticity in response to their environment, but there is large variation even within populations in the expression and magnitude of response. Maternal influence alters offspring survival through size advantages in growth and development. However, the relationship between maternal influence and variation in plasticity in response to predation risk is unknown. We hypothesized that variation in the magnitude of plastic responses between families is at least partly due to maternal provisioning and examined the relationship between maternal condition, egg provisioning and magnitude of plastic response to perceived predation risk (by dragonfly larvae: Aeshna spp.) in northern leopard frogs (Lithobates pipiens). Females in better body condition tended to lay more (clutch size) larger (egg diameter) eggs. Tadpoles responded to predation risk by increasing relative tail depth (morphology) and decreasing activity (behaviour). We found a positive relationship between morphological effect size and maternal condition, but no relationship between behavioural effect size and maternal condition. These novel findings suggest that limitations imposed by maternal condition can constrain phenotypic variation, ultimately influencing the capacity of populations to respond to environmental change.

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“…In general, our work suggests that for organisms with complex life cycles, the impacts of offensive phenotypes on predator and prey populations will be mediated not just by changes in survival, but by changes in their life-history traits which will also depend on environmental conditions in both the larval and adult environments (Altwegg & Reyer 2003). We suggest that spatial and temporal variation in the population densities of R. pirica and H. retardatus may be driven by variation in factors affecting the expression of offensive phenotypes of H. retardatus larvae (Michimae & Wakahara 2002;Michimae 2006;Kishida, Trussell & Nishimura 2009;Michimae et al 2009). For example, H. retardatus salamander larvae exhibit offensive phenotypes more frequently when in the presence of small tadpoles than with large tadpoles (Michimae & Wakahara 2002), and less frequently when in the presence of predatory dragonfly larvae (Kishida, Trussell & Nishimura 2009;Kishida et al 2011).…”

Section: Discussionmentioning

confidence: 99%

Inducible offences affect predator–prey interactions and life‐history plasticity in both predators and prey

Kishida

Costa

Tezuka

et al. 2013

Journal of Animal Ecology

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1. Phenotypic plasticity can have strong impacts on predator-prey interactions. Although much work has examined the effects of inducible defences, less understood is how inducible offences in predators affect predator-prey interactions and predator and prey phenotypes. 2. Here, we examine the impacts of an inducible offence on the interactions and life histories of a cohort of predatory Hynobius retardatus salamander larvae and their prey, Rana pirica tadpoles. We examined larval (duration, survival) and post-metamorphic (size) traits of both species after manipulating the presence/absence of tadpoles and salamanders with offensive (broadened gape width) or non-offensive phenotypes in pond enclosures. 3. Offensive phenotype salamanders reduced tadpole survival and metamorph emergence by 58% compared to tadpole-only treatments, and by over 30% compared to non-offensive phenotypes. Average time to metamorphosis of frogs was delayed by 30% in the presence of sal-amanders, although this was independent of salamander phenotype. Thus, offensive phenotype salamanders reduced the number of tadpoles remaining in the pond over time by reducing tadpole survival, not by altering patterns of metamorph emergence. Offensive phenotypes also caused tadpoles to metamorphose 19% larger than no salamander treatments and 6% larger than non-offensive phenotype treatments. Pooled across salamander treatments , tadpoles caused salamanders to reach metamorphosis faster and larger. Moreover, in the presence of tadpoles, offensive phenotype salamanders metamorphosed 25% faster and 5% larger than non-offensive phenotype salamanders, but in their absence, neither their size nor larval period differed from non-offensive phenotype individuals. 4. To our knowledge, this study is the first to demonstrate that inducible offences in predators can have strong impacts on predator and prey phenotypes across multiple life stages. Since early metamorphosis at a larger size has potential fitness advantages, the impacts of offensive phenotypes on frog and salamander life histories likely have significant consequences for individuals and populations. Furthermore, increased predation on tadpoles likely causes offensive phenotype individuals to have strong impacts on pond communities. Future studies should examine the fitness consequences of morphological and life-history plasticity across multiple life stages and should address the population and community level consequences of offensive phenotypes.

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Maternal effects on phenotypic plasticity in larvae of the salamander Hynobius retardatus

Cited by 18 publications

References 43 publications

Evolution of maternal egg size effects in sister salamander species

Evolution of maternal egg size effects in sister salamander species

Maternal body condition influences magnitude of anti-predator response in offspring

Inducible offences affect predator–prey interactions and life‐history plasticity in both predators and prey

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