WITHIN‐ AND BETWEEN‐GENERATION EFFECTS OF TEMPERATURE ON THE MORPHOLOGY AND PHYSIOLOGY OF
            <i>DROSOPHILA MELANOGASTER</i>

Crill, Wayne D.; Huey, Raymond B.; Gilchrist, George W.

doi:10.1111/j.1558-5646.1996.tb02361.x

Cited by 146 publications

(136 citation statements)

References 94 publications

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“…Studies on natural populations of chorus frogs (Pseudacris triseriata) and wood frogs have also demonstrated that frogs metamorphosing later and of smaller mass experience lower survival in the wild, although the cause of this lower survival rate is not clear (Smith 1983;Berven 1990). Studies on other taxa have shown that phenotypic plasticity exhibited early in ontogeny can affect traits (Taylor 1988;Milbrath et al 1993;Crill et al 1996;de Moed et al 1997) and performance (Ravelli et al 1976;Woollacott et al 1989;Haywood and Perrins 1992;Merilä and Svensson 1997;Pechenik et al 1996b) later in ontogeny, but rarely do we observe such dramatic and rapid impacts of larval environments on juvenile survival.…”

Section: Discussionmentioning

confidence: 94%

“…While we have abundant evidence that early environments can affect subsequent performance (growth, fecundity, and survival), we have a poor understanding of the underlying mechanisms that are responsible. One reason for this poor understanding is that few investigators examine the behavioral, physiological, and morphological traits expressed both early and later on in ontogeny (but see Tollrian 1995;Crill et al 1996;de Moed et al 1997), even though these trait changes are what collectively determine performance. Thus, we need to know how early environments affect both the subsequent traits of individuals as well as the subsequent performance of individuals.…”

Section: Introductionmentioning

confidence: 98%

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The impact of larval predators and competitors on the morphology and fitness of juvenile treefrogs

2003

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Studies of phenotypic plasticity typically focus on traits in single ontogenetic stages. However, plastic responses can be induced in multiple ontogenetic stages and traits induced early in ontogeny may have lasting effects. We examined how gray treefrog larvae altered their morphology in four different larval environments and whether different larval environments affected the survival, growth, development, and morphology of juvenile frogs at metamorphosis. We then reared these juveniles in terrestrial environments under high and low intraspecific competition to determine whether the initial differences in traits at metamorphosis affected subsequent survival and growth, whether the initial phenotypic differences converged over time, and whether competition in the terrestrial environment induced further phenotypic changes. Larval and juvenile environments both affected treefrog traits. Larval predators induced relatively deep tail fins and short bodies, but there was no impact on larval development. In contrast, larval competitors induced relatively short tails and long bodies, reduced larval growth, and slowed larval development. At metamorphosis, larval predators had no effect on juvenile growth or relative morphology while larval competitors produced juveniles that were smaller and possessed relatively shorter limbs and shorter bodies. After 1 month of terrestrial competition among the juvenile frogs, the initial differences in juvenile morphology did not converge. There were no differences in growth due to larval treatment but there were differences in survival. Individuals that experienced low competition as tadpoles experienced near perfect survival as juvenile frogs but individuals that experienced high competition as tadpoles suffered an 18% decrease in survival as juvenile frogs. There were also morphological responses to juvenile competition, but these changes appear to be due, at least in part, to allometric effects. Collectively, these results demonstrate that larval environments can have profound impacts on the traits and fitness of organisms later in ontogeny.

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Section: Discussionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 98%

The impact of larval predators and competitors on the morphology and fitness of juvenile treefrogs

2003

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“…In ectotherms, some traits important in locomotion, such as the number of body segments and muscle structure, are highly responsive to the temperature experienced early in development (e.g. Lindsey 1966;Lindsey and Harrington 1972;Stickland et al 1988;Shine and Harlow 1993;Partridge et al 1994;Crill et al 1996;Johnston and McLay 1997). Temperatures close to the upper and lower thermal tolerance limits generate a high probability for phenodeviants as a result of developmental stress (Smith-Gill 1983;Møller and Swaddle 1997).…”

Section: Discussionmentioning

confidence: 98%

Effects of induced variation in anuran larval development on postmetamorphic energy reserves and locomotion

2002

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Anuran larvae exhibit high levels of phenotypic plasticity in growth and developmental rates in response to variation in temperature and food availability. We tested the hypothesis that alteration of developmental pathways during the aquatic larval stage should affect the postmetamorphic performance of the Iberian painted frog (Discoglossus galganoi). We exposed tadpoles to different temperatures and food types (animal- vs. plant-based diets) to induce variation in the length of the larval period and body size at metamorphosis. In this species, larval period varied with temperature but was unaffected by diet composition. In contrast, size at metamorphosis was shaped by the interaction between food quality and temperature; tadpoles fed on an animal-based diet became bulkier metamorphs than those fed on plant-based food at high (22°C) but not at low (12°C) temperature. Body condition of newly metamorphosed frogs was unrelated to the temperature or food type experienced during the premetamorphic stage. Frogs maintained at high temperature during the larval period showed reduced jumping ability, especially when fed on the plant-based diet. However, when considering size-independent jumping ability, cold-reared individuals exhibited the lowest performance, and herbivores reared at 17°C the highest. Cold-reared (12°C) frogs accumulated larger amounts of energy reserves than individuals raised at 17°C or 22°C. This was still the case after correction for differences in body mass, thus indicating some size-independent effect of developmental temperature. Despite the higher lipid content of the carnivorous diet, the differences in energy reserves between herbivores and carnivores were relatively weak and associated with differences in body size. These results suggest that the consequences of environmental variation in the larval habitat can extend to the terrestrial phase and influence juvenile growth and survival.

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“…Alternatively, geographic variation in metabolic rates can be related to a high thermal sensitivity during early stages of development. The temperature of embryonic development can induce long-lasting or permanent phenotypic change in morphology and muscle structure (Ta˚ning, 1952;Crill et al, 1996). This source of developmental instability can have an influence on metabolic rates.…”

Section: Introductionmentioning

confidence: 99%

Microgeographic variation in metabolic rate and energy storage of brown trout: countergradient selection or thermal sensitivity?

2006

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We examined the influence of habitat size, growth opportunity, and the thermal conditions experienced during early development on the standard metabolic rate (SMR) of juvenile brown trout (Salmo trutta) from six natural populations to contrast the hypothesis of countergradient selection in metabolic rate. The study populations differed significantly in SMR. Population means for SMR changed in response to the temperature experienced during the yolkabsorption stage, when the risk of oxygen deficit increases and the vulnerability to hypoxia is highest. We also found a strong negative correlation between the temperature experienced during the first 2 months after yolk resorption and SMR, which supports the hypothesis of countergradient variation. Moreover, we detected a strong negative correlation between an index of growth opportunity and relative lipid content, suggesting that the risk of energy shortfall could be a major force in the evolution of storage strategies. Our results suggest that temperature can shape the evolution of metabolic rate during the yolk-absorptive stage or the first feeding stage, while energy storage levels may be more sensitive to thermal constraints acting on growth rates.

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WITHIN‐ AND BETWEEN‐GENERATION EFFECTS OF TEMPERATURE ON THE MORPHOLOGY AND PHYSIOLOGY OF DROSOPHILA MELANOGASTER

Cited by 146 publications

References 94 publications

The impact of larval predators and competitors on the morphology and fitness of juvenile treefrogs

The impact of larval predators and competitors on the morphology and fitness of juvenile treefrogs

Effects of induced variation in anuran larval development on postmetamorphic energy reserves and locomotion

Microgeographic variation in metabolic rate and energy storage of brown trout: countergradient selection or thermal sensitivity?

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