Your search keyword '"thermal reaction norms"' showing total 39 results

1. The apparent seasonal biphenism in Drosophila suzukii stems in reality from continuous reaction norms.

Author

Colinet, Hervé and Kustre, Alexiane

Subjects

DROSOPHILA suzukii, PHENOTYPIC plasticity, LOW temperatures, PHENOTYPES, PEST control

Abstract

The spotted wing drosophila (SWD) is supposed to show only two distinct seasonal phenotypes: the dark, diapausing winter morph (WM) and the light, reproductively active summer morph (SM). It is unclear if these phenotypes result from a true developmental switch or from the expression of extreme phenotypes of continuous thermal reaction norms. This study aims to investigate this question by examining traits across a range of temperatures. Using 12 developmental temperatures (8 to 30 °C), we assessed traits including viability, growth, morphology, cold tolerance, metabolic rate, and ovarian maturation. Gradual increases in temperature induced gradual changes in all these traits, indicating classical nonlinear thermal reaction norms. Low temperatures (14 °C and below) produced flies with extended development, dark color, larger size, increased cold tolerance, reduced metabolism, and delayed oogenesis, characteristic of the WM. Given the months required for emergence and egg maturation at cold, distinct generations of SWD may develop in discrete environments resulting in an apparent biphenism. What appears to be distinct phenotypes (WM and SM) may actually result from continuous thermal reaction norms. This implies the need for precise terminology in SWD. We recommend using terms like 'winter‐acclimated' or 'winter phenotype' rather than 'winter morph'. © 2024 The Author(s). Pest Management Science published by John Wiley & Sons Ltd on behalf of Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2025

2. Re‐Equilibrating Sex Ratios: Adjustment of Reaction Norms in Species With Temperature‐Dependent Sex Determination.

Author

Santidrián Tomillo, Pilar

Subjects

*SEX determination, *NATURAL selection, *SEX ratio, *CLIMATE change, *SEA turtles

Abstract

Fisher's general principle for sex allocation holds that population sex ratios are typically balanced because parents producing the rare sex are benefited and the rare sex alternates over time. In species that have temperature‐dependent sex determination (TSD), thermal reaction norms need to be adjusted at the population level to avoid extremely biased sex ratios and extinction. Extant species with TSD experienced drastic climatic changes in the geological past and must necessarily have mechanisms of adaptation. I propose here a conceptual framework to explain how TSD curves could be adjusted by means of natural selection, based on Fisher's equilibrium sex‐ratio principle. Through a process that alternatively favors mothers that tend to produce the rare sex under new temperatures, sex ratios eventually return toward a theoretical equilibrium. Prerequisites for this model are variability among mothers in the tendency to produce a particular sex at a given temperature (i.e., variability in the thermal reaction norm), inheritance of this trend, and higher fitness of the rare sex. This straightforward mechanism could facilitate thermal adaptation in species with TSD over multiple generations. [ABSTRACT FROM AUTHOR]

Published

2024

3. Evidence for evolutionary adaptation of mixotrophic nanoflagellates to warmer temperatures.

Author

Lepori‐Bui, Michelle, Paight, Christopher, Eberhard, Ean, Mertz, Conner M., and Moeller, Holly V.

Subjects

*ATMOSPHERIC carbon dioxide, *CARBON cycle, *BIOGEOCHEMICAL cycles, *COLD adaptation, *TEMPERATURE

Abstract

Mixotrophs, organisms that combine photosynthesis and heterotrophy to gain energy, play an important role in global biogeochemical cycles. Metabolic theory predicts that mixotrophs will become more heterotrophic with rising temperatures, potentially creating a positive feedback loop that accelerates carbon dioxide accumulation in the atmosphere. Studies testing this theory have focused on phenotypically plastic (short‐term, non‐evolutionary) thermal responses of mixotrophs. However, as small organisms with short generation times and large population sizes, mixotrophs may rapidly evolve in response to climate change. Here, we present data from a 3‐year experiment quantifying the evolutionary response of two mixotrophic nanoflagellates to temperature. We found evidence for adaptive evolution (increased growth rates in evolved relative to acclimated lineages) in the obligately phototrophic strain, but not in the facultative phototroph. All lineages showed trends of increased carbon use efficiency, flattening of thermal reaction norms, and a return to homeostatic gene expression. Generally, mixotrophs evolved reduced photosynthesis and higher grazing with increased temperatures, suggesting that evolution may act to exacerbate mixotrophs' effects on global carbon cycling. [ABSTRACT FROM AUTHOR]

Published

2022

4. Thermal adaptation affects the temperature-dependent toxicity of the insecticide imidacloprid to soil invertebrates.

Author

Kristiansen, Silje M., Leinaas, Hans P., van Gestel, Cornelis A.M., and Borgå, Katrine

Published

2024

5. Modelling temperature-dependent dynamics of single and mixed infections in a plant virus.

Author

Sardanyés, Josep, Alcaide, Cristina, Gómez, Pedro, and Elena, Santiago F.

Subjects

*MIXED infections, *PLANT viruses, *VIRUS diseases, *PHYTOPATHOGENIC microorganisms, *PLANT RNA

Abstract

• We propose mathematical models incorporating thermal reaction norms in species replication. • The dynamics of single and mixed infections is investigated with such models. • We estimate temperature-dependent replication and strength of competition parameters from experimental data for a plant virus. • Our work provides a general framework to incorporate abiotic responses in population dynamics. Multiple viral infection is an important issue in health and agriculture with strong impacts on society and the economy. Several investigations have dealt with the population dynamics of viruses with different dynamic properties, focusing on strain competition during multiple infections and the effects on viruses' hosts. Recent interest has been on how multiple infections respond to abiotic factors such as temperature (T). This is especially important in the case of plant pathogens, whose dynamics could be affected significantly by global warming. However, few mathematical models incorporate the effect of T on parasite fitness, especially in mixed infections. Here, we investigate simple mathematical models incorporating thermal reaction norms (TRNs), which allow for quantitative analysis. A logistic model is considered for single infections, which is extended to a Lotka-Volterra competition model for mixed infections. The dynamics of these two models are investigated, focusing on the roles of T -dependent replication and competitive interactions in both transient and asymptotic dynamics. We determine the scenarios of co-existence and competitive exclusion, which are separated by a transcritical bifurcation. To illustrate the applicability of these models, we ran single- and mixed-infection experiments in plants growing at 20 ∘ C and 30 ∘ C using two strains of the plant RNA virus Pepino mosaic virus. Using a macroevolutionary algorithm, we fitted the models to the data by estimating the TRNs for both strains in single infections. Then, we used these TRNs to feed the mixed-infection model estimating the strength of competition. We found an asymmetrical pattern in which each strain dominated at different T values due to differences in their TRNs. We also identified that T can modify competition interference greatly for both isolates. The models proposed here can be useful for investigating the outcomes of multiple-infection dynamics under abiotic changes and have implications for the understanding of viral responses to global warming. [ABSTRACT FROM AUTHOR]

Published

2022

6. Do Differences in Latitudinal Distributions of Species and Organelle Haplotypes Reflect Thermal Reaction Norms Within the Emiliania/Gephyrocapsa Complex?

Author

Peter von Dassow, Paula Valentina Muñoz Farías, Sarah Pinon, Esther Velasco-Senovilla, and Simon Anguita-Salinas

Subjects

Emiliania huxleyi, Gephyrocapsa, phytoplankton, thermal reaction norms, thermal performance curves, haplogroup, Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

The cosmopolitan phytoplankter Emiliania huxleyi contrasts with its closest relatives that are restricted to narrower latitudinal bands, making it interesting for exploring how alternative outcomes in phytoplankton range distributions arise. Mitochondrial and chloroplast haplogroups within E. huxleyi are shared with their closest relatives: Some E. huxleyi share organelle haplogroups with Gephyrocapsa parvula and G. ericsonii which inhabit lower latitudes, while other E. huxleyi share organelle haplogroups with G. muellerae, which inhabit high latitudes. We investigated whether the phylogeny of E. huxleyi organelles reflects environmental gradients, focusing on the Southeast Pacific where the different haplogroups and species co-occur. There was a high congruence between mitochondrial and chloroplast haplogroups within E. huxleyi. Haplogroup II of E. huxleyi is negatively associated with cooler less saline waters, compared to haplogroup I, both when analyzed globally and across temporal variability at the small special scale of a center of coastal upwelling at 30° S. A new mitochondrial haplogroup Ib detected in coastal Chile was associated with warmer waters. In an experiment focused on inter-species comparisons, laboratory-determined thermal reaction norms were consistent with latitudinal/thermal distributions of species, with G. oceanica exhibiting warm thermal optima and tolerance and G. muellerae exhibiting cooler thermal optima and tolerances. Emiliania huxleyi haplogroups I and II tended to exhibit a wider thermal niche compared to the other Gephyrocapsa, but no differences among haplogroups within E. huxleyi were found. A second experiment, controlling for local adaptation and time in culture, found a significant difference between E. huxleyi haplogroups. The difference between I and II was of the expected sign, but not the difference between I and Ib. The differences were small (≤1°C) compared to differences reported previously within E. huxleyi by local adaptation and even in-culture evolution. Haplogroup Ib showed a narrower thermal niche. The cosmopolitanism of E. huxleyi might result from both wide-spread generalist phenotypes and specialist phenotypes, as well as a capacity for local adaptation. Thermal reaction norm differences can well explain the species distributions but poorly explain distributions among mitochondrial haplogroups within E. huxleyi. Perhaps organelle haplogroup distributions reflect historical rather than selective processes.

Published

2021

7. Evidence for Evolutionary Adaptation of Mixotrophic Nanoflagellates to Warmer Temperatures

Author

Lepori-Bui, Michelle

Subjects

Ecology, carbon use efficiency, experimental evolutions, metabolism, Ochromonas, thermal reaction norms

Abstract

Mixotrophs, which combine photosynthesis and heterotrophy to gain energy, play an important role global biogeochemical cycles. Metabolic theory predicts that mixotrophs will become more heterotrophic with rising temperatures, potentially creating a positive feedback loop that accelerates carbon dioxide accumulation in the atmosphere. Studies testing this theory have focused on phenotypically plastic (short-term) thermal responses of mixotrophs. However, as small organisms with short generation times and large population sizes, mixotrophs may rapidly evolve in response to climate change. Here we present data from a 3-year experiment quantifying the evolutionary response of two mixotrophic nanoflagellates to temperature. We found evidence for adaptive evolution (increasing growth rates) in the obligately mixotrophic strain, but not in the facultative mixotroph, though all lineages evolved greater carbon use efficiency. Generally, mixotrophs evolved reduced photosynthesis and higher grazing with increased temperatures, suggesting that evolution may act to exacerbate mixotrophs’ effects on global carbon cycling.

Published

2022

8. Phenotypic plasticity and thermal efficiency of temperature responses in two conspecific springtail populations from contrasting climates.

Author

Sengupta, Sagnik and Leinaas, Hans Petter

Subjects

*LIFE history theory, *LIFE cycles (Biology), *CLIMATE change, *THERMAL efficiency, *CONIFEROUS forests

Abstract

Temperature drives adaptation in life-history traits through direct effects on physiological processes. However, multiple life-history traits co-evolve as a life-history strategy. Therefore, physiological limitations constraining the evolution of trait means and phenotypic plasticity can be larger for some traits than the others. Comparisons of thermal responses across life-history traits can improve our understanding of the mechanisms determining the life-history strategies. In the present study, we focused on a soil microarthropod species abundant across the Northern Hemisphere, Folsomia quadrioculata (Collembola), with previously known effects of macroclimate. We selected an arctic and a temperate population from areas with highly contrasting climates — the arctic tundra and a coniferous forest floor, respectively — and compared them for thermal plasticity and thermal efficiency in growth, development, fecundity, and survival across four temperatures for a major part of their life cycle. We intended to understand the mechanisms by which temperature drives the evolution of life-history strategies. We found that the temperate population maximized performance at 10–15 °C, whereas the arctic population maintained its thermal efficiency across a wider temperature range (10–20 °C). Thermal plasticity varied in a trait-specific manner, and when considered together with differences in thermal efficiency, indicated that stochasticity in temperature conditions may be important in shaping the life-history strategies. Our study suggests that adopting a whole-organism approach and including physiological time considerations while analysing thermal adaptation will markedly improve our understanding of plausible links between thermal adaptation and responses to global climate change. • The arctic population was efficient across a wider temperature range • Thermal plasticity differed in a trait-specific manner • Accounting for physiological time helps in understanding thermal adaptation • Whole-organism approaches can clarify the effect of climate on adaptation [ABSTRACT FROM AUTHOR]

Published

2024

9. Shrinking body sizes in response to warming: explanations for the temperature–size rule with special emphasis on the role of oxygen.

Author

Verberk, Wilco C.E.P., Atkinson, David, Hoefnagel, K. Natan, Hirst, Andrew G., Horne, Curtis R., and Siepel, Henk

Subjects

*BODY size, *GENOME size, *OXYGEN, *RESOURCE allocation, *RESPIRATION in plants, *SUPPLY & demand

Abstract

Body size is central to ecology at levels ranging from organismal fecundity to the functioning of communities and ecosystems. Understanding temperature‐induced variations in body size is therefore of fundamental and applied interest, yet thermal responses of body size remain poorly understood. Temperature–size (T–S) responses tend to be negative (e.g. smaller body size at maturity when reared under warmer conditions), which has been termed the temperature–size rule (TSR). Explanations emphasize either physiological mechanisms (e.g. limitation of oxygen or other resources and temperature‐dependent resource allocation) or the adaptive value of either a large body size (e.g. to increase fecundity) or a short development time (e.g. in response to increased mortality in warm conditions). Oxygen limitation could act as a proximate factor, but we suggest it more likely constitutes a selective pressure to reduce body size in the warm: risks of oxygen limitation will be reduced as a consequence of evolution eliminating genotypes more prone to oxygen limitation. Thus, T–S responses can be explained by the 'Ghost of Oxygen‐limitation Past', whereby the resulting (evolved) T–S responses safeguard sufficient oxygen provisioning under warmer conditions, reflecting the balance between oxygen supply and demands experienced by ancestors. T–S responses vary considerably across species, but some of this variation is predictable. Body‐size reductions with warming are stronger in aquatic taxa than in terrestrial taxa. We discuss whether larger aquatic taxa may especially face greater risks of oxygen limitation as they grow, which may be manifested at the cellular level, the level of the gills and the whole‐organism level. In contrast to aquatic species, terrestrial ectotherms may be less prone to oxygen limitation and prioritize early maturity over large size, likely because overwintering is more challenging, with concomitant stronger end‐of season time constraints. Mechanisms related to time constraints and oxygen limitation are not mutually exclusive explanations for the TSR. Rather, these and other mechanisms may operate in tandem. But their relative importance may vary depending on the ecology and physiology of the species in question, explaining not only the general tendency of negative T–S responses but also variation in T–S responses among animals differing in mode of respiration (e.g. water breathers versus air breathers), genome size, voltinism and thermally associated behaviour (e.g. heliotherms). [ABSTRACT FROM AUTHOR]

Published

2021

10. Genetic compensation rather than genetic assimilation drives the evolution of plasticity in response to mild warming across latitudes in a damselfly.

Author

Swaegers, Janne, Spanier, Katina I., and Stoks, Robby

Subjects

*GENE expression, *LATITUDE, *GLOBAL warming, *WATER temperature, *OZONE layer

Abstract

Global warming is causing plastic and evolutionary changes in the phenotypes of ectotherms. Yet, we have limited knowledge on how the interplay between plasticity and evolution shapes thermal responses and underlying gene expression patterns. We assessed thermal reaction norm patterns across the transcriptome and identified associated molecular pathways in northern and southern populations of the damselfly Ischnura elegans. Larvae were reared in a common garden experiment at the mean summer water temperatures experienced at the northern (20°C) and southern (24°C) latitudes. This allowed a space‐for‐time substitution where the current gene expression levels at 24°C in southern larvae are a proxy for the expected responses of northern larvae under gradual thermal evolution to the predicted 4°C warming. Most differentially expressed genes showed fixed differences across temperatures between latitudes, suggesting that thermal genetic adaptation will mainly evolve through changes in constitutive gene expression. Northern populations also frequently showed plastic responses in gene expression to mild warming, while southern populations were much less responsive to temperature. Thermal responsive genes in northern populations showed to a large extent a pattern of genetic compensation, namely gene expression that was induced at 24°C in northern populations remained at a lower constant level in southern populations, and were associated with metabolic and translation pathways. There was instead little evidence for genetic assimilation of an initial plastic response to mild warming. Our data therefore suggest that genetic compensation rather than genetic assimilation may drive the evolution of plasticity in response to mild warming in this damselfly species. [ABSTRACT FROM AUTHOR]

Published

2020

11. Phenotypic Plasticity of the Thermal Reaction Norms for Development in the Multicolored Asian Lady Beetle, Harmonia axyridis (Pallas) (Coleoptera, Coccinellidae).

Author

Lopatina, Е. B., Reznik, S. Ya., Ovchinnikov, A. N., Ovchinnikova, A. A., Bezman-Moseyko, О. S., and Gritsenko, Е. V.

Abstract

Phenotypic plasticity of insect thermal reaction norms (TRNs) (the lower thermal threshold, coefficient of thermal sensitivity, and sum of degree-days) ensures precise adjustment of the seasonal cycle to local environments by changing the pattern of temperature-dependence of developmental rate. In different geographic populations the plasticity of TRNs can be manifested in different ways. We investigated the photoperiodic and diet-induced plasticity of TRNs, body mass and structural size (hind femur length) of the multicolored Asian ladybird, Harmonia axyridis, from native (Irkutsk) and invasive (Sochi) laboratory populations. Each population was tested in 16 experimental treatments that represented combinations of 4 temperatures (17, 20, 24, and 28°C), 2 photoperiods (10 and 16 h of light per day), and 2 larval diets (frozen eggs of the grain moth Sitotroga cerealella and larvae and adults of the green peach aphid Myzus persicae). The lady beetle eggs developed at a temperature of 20°C; first instar larvae were distributed among experimental treatments. We have demonstrated that under both photoperiodic regimes larval feeding on a low-quality diet (grain moth eggs) resulted in a disproportional (more strongly manifested at a low temperature) retardation of preimaginal development of individuals from both populations. The lower temperature thresholds for preimaginal development were also greater on the inferior diet. When fed on grain moth eggs, larvae from the Irkutsk population showed weaker temperature-sensitivity of development, whereas in the Sochi population the slope of the TRN did not differ between the two diets. In contrast, H. axyridis from Irkutsk showed practically no photoperiodic plasticity of TRN, whereas those from Sochi were sensitive to photoperiod on both diets. Under short-day conditions, the lower temperature threshold in the latter population was smaller and temperature-sensitivity was weaker so that at the temperatures of 17 and 20°C, development under short-day conditions was faster than that under long-day conditions, whereas at 28°C, on the contrary, it was slightly slower. In both studied populations the thermal plasticity of adult body mass and hind femur length was manifested in different ways and to varying degrees, depending on the larval photoperiodic conditions and diet. Adult body mass could decrease or increase with larval developmental temperature or show no change. Despite being maintained in the laboratory for many generations, the H. axyridis populations from Sochi and Irkutsk have retained differences in physiological responses to photoperiodic conditions and larval diet. [ABSTRACT FROM AUTHOR]

Published

2020

12. Modelling temperature-dependent dynamics of single and mixed infections in a plant virus

Author

Cristina Alcaide, Josep Sardanyés, Pedro Gómez, Santiago F. Elena, Generalitat de Catalunya, Ministerio de Economía y Competitividad (España), Ministerio de Economía, Industria y Competitividad (España), Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), and European Commission

Subjects

Abiotic component, education.field_of_study, biology, Mathematical model, Co-infection dynamics, Applied Mathematics, media_common.quotation_subject, Population, Transcritical bifurcations, RNA virus, Abiotic stress, biology.organism_classification, Competition (biology), Bifurcations, Competition model, Transcritical bifurcation, Thermal reaction norms, Evolutionary biology, Nonlinear dynamics, Modeling and Simulation, Plant virus, Dynamical systems, education, media_common

Abstract

Multiple viral infection is an important issue in health and agriculture with strong impacts on society and the economy. Several investigations have dealt with the population dynamics of viruses with different dynamic properties, focusing on strain competition during multiple infections and the effects on viruses’ hosts. Recent interest has been on how multiple infections respond to abiotic factors such as temperature (T). This is especially important in the case of plant pathogens, whose dynamics could be affected significantly by global warming. However, few mathematical models incorporate the effect of T on parasite fitness, especially in mixed infections. Here, we investigate simple mathematical models incorporating thermal reaction norms (TRNs), which allow for quantitative analysis. A logistic model is considered for single infections, which is extended to a Lotka-Volterra competition model for mixed infections. The dynamics of these two models are investigated, focusing on the roles of T-dependent replication and competitive interactions in both transient and asymptotic dynamics. We determine the scenarios of co-existence and competitive exclusion, which are separated by a transcritical bifurcation. To illustrate the applicability of these models, we ran single- and mixed-infection experiments in plants growing at 20º C and 30º C using two strains of the plant RNA virus Pepino mosaic virus. Using a macroevolutionary algorithm, we fitted the models to the data by estimating the TRNs for both strains in single infections. Then, we used these TRNs to feed the mixed-infection model estimating the strength of competition. We found an asymmetrical pattern in which each strain dominated at different T values due to differences in their TRNs. We also identified that T can modify competition interference greatly for both isolates. The models proposed here can be useful for investigating the outcomes of multiple-infection dynamics under abiotic changes and have implications for the understanding of viral responses to global warming., J.S. has been partially funded by the CERCA Program of the Generalitat de Catalunya, by the Ministry of Economy, Industry and Competitiveness (MINECO) grant MTM2015-71509-C2-1-R, by Agencia Estatal de Investigación (AEI) grant RTI2018-098322-B-I00, and by a Ramón y Cajal contract (RYC-2017-22243). C.A. was funded by the MINECO within a PhD program grant (FPU16/02569). This work was also supported by the AEI-FEDER grants AGL2014-59556-R and AGL2017-89550-R to P.G. and PID2019-103998GB-I00 to S.F.E.

Published

2022

13. Modelling temperature-dependent dynamics of single and mixed infections in a plant virus

Author

Generalitat de Catalunya, Ministerio de Economía y Competitividad (España), Ministerio de Economía, Industria y Competitividad (España), Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), European Commission, Sardanyés, Josep, Alcaide, Cristina, Gómez, Pedro, Elena, Santiago F., Generalitat de Catalunya, Ministerio de Economía y Competitividad (España), Ministerio de Economía, Industria y Competitividad (España), Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), European Commission, Sardanyés, Josep, Alcaide, Cristina, Gómez, Pedro, and Elena, Santiago F.

Abstract

Multiple viral infection is an important issue in health and agriculture with strong impacts on society and the economy. Several investigations have dealt with the population dynamics of viruses with different dynamic properties, focusing on strain competition during multiple infections and the effects on viruses’ hosts. Recent interest has been on how multiple infections respond to abiotic factors such as temperature (T). This is especially important in the case of plant pathogens, whose dynamics could be affected significantly by global warming. However, few mathematical models incorporate the effect of T on parasite fitness, especially in mixed infections. Here, we investigate simple mathematical models incorporating thermal reaction norms (TRNs), which allow for quantitative analysis. A logistic model is considered for single infections, which is extended to a Lotka-Volterra competition model for mixed infections. The dynamics of these two models are investigated, focusing on the roles of T-dependent replication and competitive interactions in both transient and asymptotic dynamics. We determine the scenarios of co-existence and competitive exclusion, which are separated by a transcritical bifurcation. To illustrate the applicability of these models, we ran single- and mixed-infection experiments in plants growing at 20º C and 30º C using two strains of the plant RNA virus Pepino mosaic virus. Using a macroevolutionary algorithm, we fitted the models to the data by estimating the TRNs for both strains in single infections. Then, we used these TRNs to feed the mixed-infection model estimating the strength of competition. We found an asymmetrical pattern in which each strain dominated at different T values due to differences in their TRNs. We also identified that T can modify competition interference greatly for both isolates. The models proposed here can be useful for investigating the outcomes of multiple-infection dynamics under abiotic changes and have implica

Published

2022

14. Shrinking body sizes in response to warming

Author

Curtis R. Horne, Wilco C. E. P. Verberk, Henk Siepel, David Atkinson, K. Natan Hoefnagel, and Andrew G. Hirst

Subjects

0106 biological sciences, Animal Ecology and Physiology, Phenotypic plasticity, 01 natural sciences, phenotypic plasticity, climate warming, life-history trade-off, Thermal reaction norms, life‐history trade‐off, growth trajectory, SDG 13 - Climate Action, Body Size, Hypoxia, SDG 15 - Life on Land, 0303 health sciences, Ecology, Temperature, Hypoxia (environmental), Fecundity, temperature–size rule, Bergmann's rule, cell size, Ectotherm, Original Article, General Agricultural and Biological Sciences, Adaptive value, thermal reaction norms, Biology, 010603 evolutionary biology, Gigantism, General Biochemistry, Genetics and Molecular Biology, Climate warming, 03 medical and health sciences, Respiration, Life-history trade-off, Animals, Ecosystem, gigantism, 030304 developmental biology, hypoxia, Original Articles, Cell size, Oxygen, Growth trajectory, Temperature-size rule

Abstract

Body size is central to ecology at levels ranging from organismal fecundity to the functioning of communities and ecosystems. Understanding temperature‐induced variations in body size is therefore of fundamental and applied interest, yet thermal responses of body size remain poorly understood. Temperature–size (T–S) responses tend to be negative (e.g. smaller body size at maturity when reared under warmer conditions), which has been termed the temperature–size rule (TSR). Explanations emphasize either physiological mechanisms (e.g. limitation of oxygen or other resources and temperature‐dependent resource allocation) or the adaptive value of either a large body size (e.g. to increase fecundity) or a short development time (e.g. in response to increased mortality in warm conditions). Oxygen limitation could act as a proximate factor, but we suggest it more likely constitutes a selective pressure to reduce body size in the warm: risks of oxygen limitation will be reduced as a consequence of evolution eliminating genotypes more prone to oxygen limitation. Thus, T–S responses can be explained by the ‘Ghost of Oxygen‐limitation Past’, whereby the resulting (evolved) T–S responses safeguard sufficient oxygen provisioning under warmer conditions, reflecting the balance between oxygen supply and demands experienced by ancestors. T–S responses vary considerably across species, but some of this variation is predictable. Body‐size reductions with warming are stronger in aquatic taxa than in terrestrial taxa. We discuss whether larger aquatic taxa may especially face greater risks of oxygen limitation as they grow, which may be manifested at the cellular level, the level of the gills and the whole‐organism level. In contrast to aquatic species, terrestrial ectotherms may be less prone to oxygen limitation and prioritize early maturity over large size, likely because overwintering is more challenging, with concomitant stronger end‐of season time constraints. Mechanisms related to time constraints and oxygen limitation are not mutually exclusive explanations for the TSR. Rather, these and other mechanisms may operate in tandem. But their relative importance may vary depending on the ecology and physiology of the species in question, explaining not only the general tendency of negative T–S responses but also variation in T–S responses among animals differing in mode of respiration (e.g. water breathers versus air breathers), genome size, voltinism and thermally associated behaviour (e.g. heliotherms).

Published

2021

15. The role of temperature in egg development of three aquatic insects Lestagella penicillata (Ephemeroptera), Aphanicercella scutata (Plecoptera), Chimarra ambulans (Trichoptera) from South Africa.

Author

Ross-Gillespie, Vere, Picker, Mike D., Dallas, Helen F., and Day, Jenny A.

Subjects

*MAYFLIES, *STONEFLIES, *EMBRYOLOGY, *AQUATIC insects

Abstract

1. The sub-lethal effects of water temperature on egg development was investigated in three syntopic mountain stream insects, viz. Lestagella penicillata (Ephemeroptera: Teloganodidae), Aphanicercella scutata (Plecoptera: Notonemouridae) and Chimarra ambulans (Trichoptera: Philopotamidae) from the winter rainfall Western Cape Province, South Africa. 2. Eggs of each species were incubated after fertilisation at six temperature treatments across the range of 5–30 °C. Total development time required for 50% hatch, total hatch success, duration of the hatching period, upper and lower thermal limits for development, as well as thermal reaction norms were calculated for each species. 3. Successful egg development and hatching occurred between 10 and 20 °C for L . penicillata , with highest percentage hatch (90%) at 10, 15 and 20 °C treatments. For A. scutata successful hatching also occurred between 10 and 20 °C but hatching success was reduced (~ 30%) at 20 °C compared to ~ 80% hatching success at 10 and 15 °C treatments. For C. ambulans , successful development and hatching occurred over a wider range of temperatures (10–25 °C) but with lower (5–20%) and more variable hatching success at all temperatures. 4. Thermal reaction norms in conjunction with egg hatch parameters showed that L . penicillata and particularly C. ambulans were warm adapted, while the A. scutata was cold adapted. These observed differences in egg development characteristics similarly relate to the different life-histories and their relation to developmental season. 5. Lethal thermal limits for egg development along with the sub-lethal effects of temperature on hatch success provide valuable information for setting environmental water temperature guidelines for species conservation as well as environmental flow studies. [ABSTRACT FROM AUTHOR]

Published

2018

16. Microgeographic differentiation in thermal performance curves between rural and urban populations of an aquatic insect.

Author

Tüzün, Nedim, Op de Beeck, Lin, Brans, Kristien I., Janssens, Lizanne, and Stoks, Robby

Subjects

*AQUATIC insects, *INSECT population genetics, *INSECT ecology, *RURAL population, *INSECT mortality

Abstract

The rapidly increasing rate of urbanization has a major impact on the ecology and evolution of species. While increased temperatures are a key aspect of urbanization ('urban heat islands'), we have very limited knowledge whether this generates differentiation in thermal responses between rural and urban populations. In a common garden experiment, we compared the thermal performance curves (TPCs) for growth rate and mortality in larvae of the damselfly Coenagrion puella from three urban and three rural populations. TPCs for growth rate shifted vertically, consistent with the faster-slower theoretical model whereby the cold-adapted rural larvae grew faster than the warm-adapted urban larvae across temperatures. In line with costs of rapid growth, rural larvae showed lower survival than urban larvae across temperatures. The relatively lower temperatures hence expected shorter growing seasons in rural populations compared to the populations in the urban heat islands likely impose stronger time constraints to reach a certain developmental stage before winter, thereby selecting for faster growth rates. In addition, higher predation rates at higher temperature may have contributed to the growth rate differences between urban and rural ponds. A faster-slower differentiation in TPCs may be a widespread pattern along the urbanization gradient. The observed microgeographic differentiation in TPCs supports the view that urbanization may drive life-history evolution. Moreover, because of the urban heat island effect, urban environments have the potential to aid in developing predictions on the impact of climate change on rural populations. [ABSTRACT FROM AUTHOR]

Published

2017

17. How does the dengue vector mosquito Aedes albopictus respond to global warming?

Author

Pengfei Jia, Xiang Chen, Jin Chen, Liang Lu, Qiyong Liu, and Xiaoyue Tan

Abstract

Background: Global warming has a marked influence on the life cycle of epidemic vectors as well as their interactions with human beings. The Aedes albopictus mosquito as the vector of dengue fever surged exponentially in the last decade, raising ecological and epistemological concerns of how climate change altered its growth rate and population dynamics. As the global warming pattern is considerably uneven across four seasons, with a confirmed stronger effect in winter, an emerging need arises as to exploring how the seasonal warming effects influence the annual development of Ae. albopictus. Methods: The model consolidates a 35-year climate dataset and designs fifteen warming patterns that increase the temperature of selected seasons. Based on a recently developed mechanistic population model of Ae. albopictus, the model simulates the thermal reaction of blood-fed adults by systematically increasing the temperature from 0.5 to 5 °C at an interval of 0.5 °C in each warming pattern. Results: The results show the warming effects are different across seasons. The warming effects in spring and winter facilitate the development of the species by shortening the diapause period. The warming effect in summer is primarily negative by inhibiting mosquito development. The warming effect in autumn is considerably mixed. However, these warming effects cannot carry over to the following year, possibly due to the fact that under the extreme weather in winter the mosquito fully ceases from development and survives in terms of diapause eggs. Conclusions: As the historical pattern of global warming manifests seasonal fluctuations, this study provides corroborating and previously ignored evidence of how such seasonality affects the mosquito development. Understanding this short-term temperature-driven mechanism as one chain of the transmission events is critical to refining the thermal reaction norms of the epidemic vector under global warming as well as developing effective mosquito prevention and control strategies. [ABSTRACT FROM AUTHOR]

Published

2017

18. Genetic compensation rather than genetic assimilation drives the evolution of plasticity in response to mild warming across latitudes in a damselfly

Author

Janne Swaegers, Katina I. Spanier, and Robby Stoks

Subjects

0106 biological sciences, 0301 basic medicine, Odonata, evolution of plasticity, REACTION NORMS, RNA-Seq, Global Warming, ANNOTATION, 01 natural sciences, ZOSTERA-MARINA, Transcriptome, transcriptomics, Damselfly, RNA&#8208, THERMAL-STRESS, RNA-SEQ, ADAPTATION, TRANSCRIPTOMIC RESPONSES, CLIMATE-CHANGE, Ecology, Temperature, climate change, Larva, Ectotherm, Seasons, Life Sciences & Biomedicine, time substitution, EXPRESSION, Biochemistry & Molecular Biology, Climate change, Environmental Sciences & Ecology, thermal reaction norms, Biology, 010603 evolutionary biology, 03 medical and health sciences, seq, PHENOTYPIC PLASTICITY, space&#8208, Genetics, Animals, Gene, Ecology, Evolution, Behavior and Systematics, for&#8208, Evolutionary Biology, Science & Technology, Global warming, biology.organism_classification, 030104 developmental biology, Genetic assimilation

Abstract

Global warming is causing plastic and evolutionary changes in the phenotypes of ectotherms. Yet, we have limited knowledge on how the interplay between plasticity and evolution shapes thermal responses and underlying gene expression patterns. We assessed thermal reaction norm patterns across the transcriptome and identified associated molecular pathways in northern and southern populations of the damselfly Ischnura elegans. Larvae were reared in a common garden experiment at the mean summer water temperatures experienced at the northern (20°C) and southern (24°C) latitudes. This allowed a space-for-time substitution where the current gene expression levels at 24°C in southern larvae are a proxy for the expected responses of northern larvae under gradual thermal evolution to the predicted 4°C warming. Most differentially expressed genes showed fixed differences across temperatures between latitudes, suggesting that thermal genetic adaptation will mainly evolve through changes in constitutive gene expression. Northern populations also frequently showed plastic responses in gene expression to mild warming, while southern populations were much less responsive to temperature. Thermal responsive genes in northern populations showed to a large extent a pattern of genetic compensation, namely gene expression that was induced at 24°C in northern populations remained at a lower constant level in southern populations, and were associated with metabolic and translation pathways. There was instead little evidence for genetic assimilation of an initial plastic response to mild warming. Our data therefore suggest that genetic compensation rather than genetic assimilation may drive the evolution of plasticity in response to mild warming in this damselfly species. ispartof: MOLECULAR ECOLOGY vol:29 issue:24 pages:4823-4834 ispartof: location:England status: published

Published

2020

19. Past history shapes evolution of reproductive success in a global warming scenario.

Author

Santos, Marta A., Antunes, Marta A., Grandela, Afonso, Carromeu-Santos, Ana, Quina, Ana S., Santos, Mauro, Matos, Margarida, and Simões, Pedro

Subjects

*BIOLOGICAL fitness, *GLOBAL warming, *LIFE history theory, *ANIMAL populations, *LONG-Term Evolution (Telecommunications), *PHYSIOLOGICAL adaptation

Abstract

Adaptive evolution is critical for animal populations to thrive in the fast-changing natural environments. Ectotherms are particularly vulnerable to global warming and, although their limited coping ability has been suggested, few real-time evolution experiments have directly accessed their evolutionary potential. Here, we report a long-term experimental evolution study addressing the evolution of Drosophila thermal reaction norms, after ∼30 generations under different dynamic thermal regimes: fluctuating (daily variation between 15 and 21 °C) or warming (daily fluctuation with increases in both thermal mean and variance across generations). We analyzed the evolutionary dynamics of Drosophila subobscura populations as a function of the thermally variable environments in which they evolved and their distinct background. Our results showed clear differences between the historically differentiated populations: high latitude D. subobscura populations responded to selection, improving their reproductive success at higher temperatures whereas their low latitude counterparts did not. This suggests population variation in the amount of genetic variation available for thermal adaptation, an aspect that needs to be considered to allow for better predictions of future climate change responses. Our results highlight the complex nature of thermal responses in face of environmental heterogeneity and emphasize the importance of considering inter-population variation in thermal evolution studies. • Evolution of thermal reaction norms was studied in two Drosophila subobscura populations. • Northern European populations under warming selection improved reproductive success at high temperatures. • Southern European population did not show evolution of thermal reaction norms under warming selection. • Other life-history traits such as fecundity and juvenile viability did not show relevant changes. • This study indicates population variation in the evolutionary potential for long-term thermal adaptation. [ABSTRACT FROM AUTHOR]

Published

2023

20. First demonstration of the influence of photoperiod on the thermal requirements for development in insects and in particular the linden-bug, Pyrrhocoris apterus (Heteroptera: Pyrrhocoridae)

Author

Elena B. LOPATINA, Sergei V. BALASHOV, and Vladilen E. KIPYATKOV

Subjects

heteroptera, pyrrhocoridae, pyrrhocoris apterus, photoperiod, temperature, thermal reaction norms, thermal requirements for development, development time, development rate, thermal threshold, thermal lability, seasonal variation, Zoology, QL1-991

Abstract

The influence of photoperiod on the thermal requirements for development was discovered for the first time in insects during experiments on the linden-bug, Pyrrhocoris apterus. The effect of photoperiod on the duration of linden-bug development at five constant temperatures (20, 22, 24, 26 and 28°C) was measured and the thermal requirements for development at three photoperiods (14, 17 and 20 h light per day) were calculated. Bugs from four geographic populations were used in these experiments: Pyatigorsk (44°02´N, 43°04´E), Borisovka (50°36´N, 36°01´E), Mikhailov (54°15´N, 39°0´E) and Ryazan (54°36´N, 39°42´E). From the values of individual development times at different temperatures the coefficient of linear regression of development rate (the inverse of the duration) on temperature and the thermal threshold for development were calculated. Both these parameters were found to decrease significantly with decrease in day-length for all four populations studied. It means that at shorter day-lengths nymphal development is less dependent on temperature compared to the development at longer day-lengths. These effects seem to be adaptive. The development times of nymphs at relatively high temperatures (above 24-25°C) are shorter under long-days than under short days which should be advantageous at the height of summer when the days are long and the weather is warm. In the contrast, at relatively low temperatures (below 24-25°C) the nymphs develop significantly faster under short-days than under long days, which is advantageous at the end of summer as it allows the nymphs to reach the adult stage, the only stage capable of overwintering. The influence of photoperiod on the thermal reaction norm appeared to be more or less gradual, i.e. the shorter the day-length the shallower the slope of the regression line of development rate on temperature and the lower the thermal threshold for development. An analysis of the literature shows that this effect of photoperiod on the thermal requirements for development is widespread among insects but has been overlooked by previous authors. The authors conclude that the variation in the development time observed in insects at different seasons, photoperiods or food regimes, or from different populations, etc., are generally due to some modification of the thermal reaction norms and more specifically to differences in the thermal requirements for development.

Published

2007

21. Local adaptation drives thermal tolerance among parasite populations: a common garden experiment.

Author

Mazé-Guilmo, Elise, Blanchet, Simon, Rey, Olivier, Canto, Nicolas, and Loot, Géraldine

Subjects

*PARASITES, *ECTOPARASITES, *THERMAL tolerance (Physiology), *CLIMATE change, *HEAT

Abstract

Understanding the evolutionary responses of organisms to thermal regimes is of prime importance to better predict their ability to cope with ongoing climate change. Although this question has attracted interest in free-living organisms, whether or not infectious diseases have evolved heterogeneous responses to climate is still an open question. Here, we ran a common garden experiment using the fish ectoparasite Tracheliastes polycolpus, (i) to test whether parasites living in thermally heterogeneous rivers respond differently to an experimental thermal gradient and (ii) to determine the evolutionary processes (natural selection or genetic drift) underlying these responses. We demonstrated that the reaction norms involving the survival rate of the parasite larvae (i.e. the infective stage) across a temperature gradient significantly varied among six parasite populations. Using a Qst/Fst approach and phenotype-environment associations, we further showed that the evolution of survival rate partly depended upon temperature regimes experienced in situ, and was mostly underlined by diversifying selection, but also-to some extent-by stabilizing selection and genetic drift. This evolutionary response led to population divergences in thermal tolerance across the landscape, which has implications for predicting the effects of future climate change. [ABSTRACT FROM AUTHOR]

Published

2016

22. Developmental Plasticity in Butterfly Eyespot Mutants: Variation in Thermal Reaction Norms across Genotypes and Pigmentation Traits

Author

Mateus, Ana Rita Amaro, P, Beldade, and Repositório da Universidade de Lisboa

Subjects

Insect Science, developmental plasticity, seasonal polyphenism, pigmentation mutants, Bicyclus anynana, butterfly eyespots, gene-by-environment interactions, thermal reaction norms, trait integration, trait-specific effects

Abstract

Developmental plasticity refers to the property by which a genotype corresponds to distinct phenotypes depending on the environmental conditions experienced during development. This dependence of phenotype expression on environment is graphically represented by reaction norms, which can differ between traits and between genotypes. Even though genetic variation for reaction norms provides the basis for the evolution of plasticity, we know little about the genes that contribute to that variation. This includes understanding to what extent those are the same genes that contribute to inter-individual variation in a fixed environment. Here, we quantified thermal plasticity in butterfly lines that differ in pigmentation phenotype to test the hypothesis that alleles affecting pigmentation also affect plasticity therein. We characterized thermal reaction norms for eyespot color rings of distinct Bicyclus anynana genetic backgrounds, corresponding to allelic variants affecting eyespot size and color composition. Our results reveal genetic variation for the slope and curvature of reaction norms, with differences between eyespots and between eyespot color rings, as well as between sexes. Our report of prevalent temperature-dependent and compartment-specific allelic effects underscores the complexity of genotype-by-environment interactions and their consequence for the evolution of developmental plasticity.

Published

2022

23. Plasticity of the thermal developmental reaction norms in the european peacock butterfly Inachis io (Lepidoptera, Nymphalidae).

Author

Ryzhkova, M. and Lopatina, E.

Subjects

*NYMPHALIDAE, *BUTTERFLIES, *INSECT development, *LEPIDOPTERA, *ONTOGENY, *PHYSIOLOGY

Abstract

The goal of the study was to analyze the plasticity of the developmental thermal reaction norms in the peacock butterfly Inachis io as affected by different photoperiodic conditions and group versus individual keeping. Overwintered imagoes were collected in Stariy Peterhof (Saint-Petersburg, Russia) in May 2010 and 2012-2013. Twelve experimental regimes were used: 4 thermal (16, 18, 20 and 22°C) and 3 photoperiodic (12, 18 and 22 h of light per day). Under short-daylight conditions (12 h), the larvae were shown to develop a little faster than under long-day conditions (22 h), although the thermal developmental thresholds were invariable in both cases. The linear regression coefficient characterizing developmental thermolability was significantly higher only in males more affected during their development by the short-day photoperiod than females. Under the 18-h daylight regime, larval development was less thermolabile and characterized by a lower thermal threshold than under the shorter or longer photoperiod. The influence of the short-day photoperiod on the larval development manifested itself most distinctly in the body mass changes in emerging pupae: under all thermal regimes, the pupae were lighter under the short-than long-day photoperiod. The pupal body mass grew with the rise in temperature, contrary to the temperature-size rule. Individual keeping led to the longer duration and lower thermolability of larval and pupal development, as well as to a reduced pupal body mass. Individual keeping exerted a stronger influence on females than on males. [ABSTRACT FROM AUTHOR]

Published

2015

24. Temperature-mediated biotic interactions influence enemy release of nonnative species in warming environments.

Author

Fey, Samuel B. and Herren, Cristina M.

Subjects

*INTRODUCED organisms & the environment, *BIOLOGICAL invasions, *COMPETITION (Biology), *RANGE ecology, *PUMPKINSEED (Fish), *FISHES

Abstract

"Enemy release" occurs when invading species suffer from interactions with pathogens, parasites, herbivores, or predators to a lesser degree than native species due to a lack of shared evolutionary history. Here we provide strong support for the hypothesis that variable thermal sensitivities between a consumer and its resources can generate temperaturedependent enemy release using both a mathematical model and a field experiment. We identify three common scenarios where changes in temperature should alter enemy release based on asymmetric responses among enemies and their resources to changes in temperature: (1) the vital rates of a shared enemy are more sensitive to changes in temperature than its resources, (2) the enemy's thermal maximum for consumption is higher than the resources' maxima for growth, and (3) the invading resource has a higher thermal maximum for growth than its native competitor. Mathematical representations indicated that warming is capable of altering enemy release in each of these three scenarios. We also tested our hypothesis using a mesocosm warming experiment in a system that exhibits variable thermal sensitivities between a predator and its native and nonnative prey. We conducted a six-week experiment manipulating the presence of Lepomis sunfish (present, absent) and water temperature (ambient, heated) using the nonnative crustacean zooplankter, Daphnia lumholtzi, whose morphological defenses reduce prédation from juvenile sunfish relative to native Daphnia pulex. Our results indicate that D. lumholtzi benefited to a greater extent from the presence of Lepomis predators as temperatures increase. Taken together, our model and experiment indicate that changes in environmental temperature may directly influence the success of nonnative species and may assist with forecasting the community consequences of biological invasions in a warming world. [ABSTRACT FROM AUTHOR]

Published

2014

25. Temperature- and density-dependence of diapause induction and its life history correlates in the geometrid moth Chiasmia clathrata (Lepidoptera: Geometridae)

Author

Välimäki, Panu, Kivelä, Sami M., and Mäenpää, Maarit I.

Subjects

DIAPAUSE, LEPIDOPTERA, INSECT reproduction, INSECT development, INSECT populations, INSECT physiology, INSECT larvae

Abstract

The relative roles of genetics and developmental plasticity in creating phenotypes adapted to prevailing conditions are insufficiently understood. In potentially multivoltine temperate insects, individuals that do not enter diapause but develop directly into reproductive adults within the same season are severely time-constrained. Direct development is, however, under selection only if expressed in the wild. Thus, adaptive correlates of the direct development are expected to evolve and persist only in multivoltine populations. We studied the genetic and phenotypic components of variation in juvenile development in the geometrid moth Chiasmia clathrata from univoltine and bivoltine regions. Larvae were reared at two temperatures (14/20 °C) and densities (low/high) in a factorial split-brood experiment. High temperature and low density promoted direct development, the former condition being associated with a short development time, high growth rate and large body size. Genotypes of bivoltine origin had a higher propensity for direct development and seemingly expressed an exaggerated plastic response to increasing temperature compared to the ones from univoltine populations. Alternative life history phenotypes associated with the induced developmental pathway emerged only in the bivoltine region, direct development resulting in a short larval period, high growth rate and small size at 20 °C there. The degree of differentiation between the developmental pathways was insensitive to larval density; high density only decreased both development time and body size to a certain degree. We conclude that the differences between the pathways are not due to the induction of a particular pathway itself, but geographically varying selection pressures shape the correlation structure among life history traits and their pathway-specific expression. [ABSTRACT FROM AUTHOR]

Published

2013

26. Ecological emergence of thermal clines in body size.

Author

Edeline, Eric, Lacroix, Gérard, Delire, Christine, Poulet, Nicolas, and Legendre, Stéphane

Subjects

*GLOBAL warming, *CLINES, *FOOD chains, *ECOLOGICAL niche, *PREDATION, *BERGMANN'S rule

Abstract

The unprecedented rate of global warming requires a better understanding of how ecosystems will respond. Organisms often have smaller body sizes under warmer climates (Bergmann's rule and the temperature-size rule), and body size is a major determinant of life histories, demography, population size, nutrient turnover rate, and food-web structure. Therefore, by altering body sizes in whole communities, current warming can potentially disrupt ecosystem function and services. However, the underlying drivers of warming-induced body downsizing remain far from clear. Here, we show that thermal clines in body size are predicted from universal laws of ecology and metabolism, so that size-dependent selection from competition (both intra and interspecific) and predation favors smaller individuals under warmer conditions. We validate this prediction using 4.1 × 106 individual body size measurements from French river fish spanning 29 years and 52 species. Our results suggest that warming-induced body downsizing is an emergent property of size-structured food webs, and highlight the need to consider trophic interactions when predicting biosphere reorganizations under global warming. [ABSTRACT FROM AUTHOR]

Published

2013

27. GENOTYPE-BY-TEMPERATURE INTERACTIONS MAY HELP TO MAINTAIN CLONAL DIVERSITY IN ASTERIONELLA FORMOSA (BACILLARIOPHYCEAE).

Author

Gsell, Alena S., Senerpont Domis, Lisette N., Przytulska-Bartosiewicz, Anna, Mooij, Wolf M., Donk, Ellen, and Ibelings, Bas W.

Subjects

*DIATOMS, *GENOTYPE-environment interaction, *COEXISTENCE of species, *FRESHWATER algae, *MARINE algae, *MARINE phytoplankton, *PHYSIOLOGICAL effects of temperature

Abstract

Marine and freshwater phytoplankton populations often show large clonal diversity, which is in disagreement with clonal selection of the most vigorous genotype(s). Temporal fluctuation in selection pressures in variable environments is a leading explanation for maintenance of such genetic diversity. To test the influence of temperature as a selection force in continually (seasonally) changing aquatic systems we carried out reaction norms experiments on co-occurring clonal genotypes of a ubiquitous diatom species, Asterionella formosa Hassall, across an environmentally relevant range of temperatures. We report within population genetic diversity and extensive diversity in genotype-specific reaction norms in growth rates and cell size traits. Our results showed genotype by environment interactions, indicating that no genotype could outgrow all others across all temperature environments. Subsequently, we constructed a model to simulate the relative proportion of each genotype in a hypothetical population based on genotype and temperature-specific population growth rates. This model was run with different seasonal temperature patterns. Our modeling exercise showed a succession of two to several genotypes becoming numerically dominant depending on the underlying temperature pattern. The results suggest that (temperature) context dependent fitness may contribute to the maintenance of genetic diversity in isolated populations of clonally reproducing microorganisms in temporally variable environments. [ABSTRACT FROM AUTHOR]

Published

2012

28. Photoperiod modifies thermal reaction norms for growth and development in the red poplar leaf beetle Chrysomela populi (Coleoptera: Chrysomelidae)

Author

Kutcherov, Dmitry A., Lopatina, Elena B., and Kipyatkov, Vladilen E.

Subjects

*PHOTOPERIODISM, *CHRYSOMELIDAE, *GROWTH, *TEMPERATURE effect, *INSECT development, *INSECT larvae

Abstract

Abstract: Regression lines of development rate on temperature appeared significantly different between long (22h) and short (12h) day conditions and intersected each other at 23.8°С. Thus, the rate of growth and development was higher at temperatures below the intersection point under short-day but above the intersection point it was higher under long day. Ecological relevance of this effect seems as follows: in autumn, as nights become longer and average daily temperature decreases, larvae have to speed up their development because it is only imago that overwinters. Conversely, midsummer offers long days and usually higher temperature, so again it is advantageous to develop as fast as possible in order to have at least one more generation per year. These results are compared with other studies showing interactions between photoperiod and temperature, and some possible general patterns are outlined. The lower thermal threshold for larval development depended on photoperiodic conditions; therefore rate isomorphy must be violated in this species. Development at higher temperatures generally resulted in smaller adults, as is usual with ectotherms according to the “temperature-size rule”, but body weight depended significantly on temperature only under short day. Our estimates of the lower temperature thresholds for growth and development in both cases did conform to the generalization made previously by in spite of another formula used by us. We briefly discuss this phenomenon and argue that relative position of these thresholds can be explained mathematically and per se may lack any biological sense. [Copyright &y& Elsevier]

Published

2011

29. Thermal acclimation of swimming performance in newt larvae: the influence of diel temperature fluctuations during embryogenesis.

Author

Měrákov, Eva and Gvoždík, Lumír

Subjects

*LARVAE, *EMBRYOLOGY, *ACCLIMATIZATION, *NATURAL selection, *HABITATS

Abstract

1. Thermal acclimation is one of the basic strategies by which organisms cope with thermal heterogeneity of the environment. Under predictable variation in environmental temperatures, theory predicts that selection favours acclimation of thermal performance curves over fixed phenotypes. 2. We examined the influence of diel fluctuations in developmental temperatures on the thermal sensitivity of the maximal swimming capacity in larvae of the alpine newt, Triturus alpestris. 3. We incubated newt eggs under three thermal regimes with varying daily amplitudes (1, 5 and 9 °C) and similar means (17·6–17·9 °C), and accordingly we measured the swimming speed of hatched larvae at three experimental temperatures (12, 17 and 22 °C), which they would normally experience in their natural habitat. 4. Embryonic development under low and middle temperature fluctuations produced larvae with similar swimming speeds across experimental temperatures. In contrast, the most fluctuating regime induced development of phenotypes, which at 12 °C swam faster than larvae developed under moderate diel fluctuations. 5. Our results provide evidence that diel temperature fluctuations induce acclimation of thermal dependence of locomotor performance. In ectotherms experiencing diel cycles in environmental temperatures, this plastic response may act as an important pacemaker in the evolution of thermal sensitivity. [ABSTRACT FROM AUTHOR]

Published

2009

30. EVOLUTION IN A CONSTANT ENVIRONMENT: THERMAL FLUCTUATIONS AND THERMAL SENSITIVITY OF LABORATORY AND FIELD POPULATIONS OF MANDUCA SEXTA.

Author

Kingsolver, Joel G., Ragland, Gregory J., and Diamond, Sarah E.

Subjects

*BIOLOGICAL evolution, *MANDUCA, *SPHINGIDAE, *PHYSIOLOGICAL effects of temperature, *BIOLOGY, *ANIMAL populations

Abstract

Adaptation to temporal variation in environmental conditions is widespread. Whether evolution in a constant environment alters adaptation to temporal variation is relatively unexplored. We examine how constant and diurnally fluctuating temperature conditions affect life-history traits in two populations of the tobacco hornworm, Manduca sexta: a field population that routinely experiences fluctuating temperatures; and a laboratory population (derived from this field population in the 1960s) maintained at a constant temperature for more than 250 generations. Our experiments demonstrate that diurnal fluctuations significantly alter body size and development time in both populations, and confirm that these populations differ in their responses to a mean temperature. However, we found no evidence for population divergence in responses to diurnal temperature fluctuations. We suggest that mean and extreme temperatures may act as more potent selective forces on thermal reaction norms than temperature variation per se. [ABSTRACT FROM AUTHOR]

Published

2009

31. Why does a grasshopper have fewer, larger offspring at its range limits?

Author

HASSALL, M., WALTERS, R. J., TELFER, M., and HASSALL, M. R. J.

Subjects

*GRASSHOPPERS, *GENETIC polymorphisms, *GENETIC research, *INSECT societies, *BIOLOGY

Abstract

Analysis of size of offspring reared through three laboratory generations from populations of the field grasshopper Chorthippus brunneus from 27 sites around the British Isles showed that offspring were larger towards the cooler-wetter conditions in the western and northern limits of the range. This variation had a significant genetic component. There was a trade-off between clutch size and offspring size between and within populations. Under favourable thermal and feeding conditions maternal fitness was optimal when individuals produced the largest clutches of the smallest eggs, but under poor conditions maternal fitness was optimal when individuals produced small clutches of very large offspring. Calculation of geometric mean fitness over time indicated that having larger offspring near to the edge of the range could be advantageous as a conservative risk-spreading strategy. As well as geographic variation in egg size, significant environment–genotype interactions in egg size in relation to temperature were observed. [ABSTRACT FROM AUTHOR]

Published

2006

32. How does the dengue vector mosquito Aedes albopictus respond to global warming?

Author

Jin Chen, Liang Lu, Xiang Chen, Liu Qiyong, Xiaoyue Tan, and Pengfei Jia

Subjects

Aedes albopictus, 010504 meteorology & atmospheric sciences, 030231 tropical medicine, Population, Climate change, Biology, Diapause, Models, Biological, 01 natural sciences, Dengue, 03 medical and health sciences, Extreme weather, 0302 clinical medicine, Mosquito, Thermal reaction norms, Aedes, medicine, Animals, education, Ecosystem, 0105 earth and related environmental sciences, education.field_of_study, Ecology, Research, Global warming, Temperature, Seasonality, medicine.disease, biology.organism_classification, Mechanistic population modeling, Insect Vectors, Infectious Diseases, Population model, Parasitology, Seasons

Abstract

Background Global warming has a marked influence on the life cycle of epidemic vectors as well as their interactions with human beings. The Aedes albopictus mosquito as the vector of dengue fever surged exponentially in the last decade, raising ecological and epistemological concerns of how climate change altered its growth rate and population dynamics. As the global warming pattern is considerably uneven across four seasons, with a confirmed stronger effect in winter, an emerging need arises as to exploring how the seasonal warming effects influence the annual development of Ae. albopictus. Methods The model consolidates a 35-year climate dataset and designs fifteen warming patterns that increase the temperature of selected seasons. Based on a recently developed mechanistic population model of Ae. albopictus, the model simulates the thermal reaction of blood-fed adults by systematically increasing the temperature from 0.5 to 5 °C at an interval of 0.5 °C in each warming pattern. Results The results show the warming effects are different across seasons. The warming effects in spring and winter facilitate the development of the species by shortening the diapause period. The warming effect in summer is primarily negative by inhibiting mosquito development. The warming effect in autumn is considerably mixed. However, these warming effects cannot carry over to the following year, possibly due to the fact that under the extreme weather in winter the mosquito fully ceases from development and survives in terms of diapause eggs. Conclusions As the historical pattern of global warming manifests seasonal fluctuations, this study provides corroborating and previously ignored evidence of how such seasonality affects the mosquito development. Understanding this short-term temperature-driven mechanism as one chain of the transmission events is critical to refining the thermal reaction norms of the epidemic vector under global warming as well as developing effective mosquito prevention and control strategies. Electronic supplementary material The online version of this article (doi:10.1186/s13071-017-2071-2) contains supplementary material, which is available to authorized users.

Published

2017

33. Temperature- and density-dependence of diapause induction and its life history correlates in the geometrid moth Chiasmia clathrata (Lepidoptera: Geometridae)

Author

Välimäki, Panu, Kivelä, Sami M., and Mäenpää, Maarit I.

Published

2013

34. First demonstration of the influence of photoperiod on the thermal requirements for development in insects and in particular the linden-bug, Pyrrhocoris apterus (Heteroptera: Pyrrhocoridae)

Author

V. E. Kipyatkov, E. B. Lopatina, and S. V. Balashov

Subjects

thermal lability, development time, thermal reaction norms, thermal requirements for development, Biology, photoperiod, Animal science, Thermal, medicine, thermal threshold, Nymph, Overwintering, heteroptera, photoperiodism, seasonal variation, pyrrhocoridae, Ecology, Pyrrhocoridae, Heteroptera, temperature, Seasonality, Pyrrhocoris, medicine.disease, biology.organism_classification, development rate, QL1-991, Insect Science, pyrrhocoris apterus, Zoology

Abstract

The influence of photoperiod on the thermal requirements for development was discovered for the first time in insects during experiments on the linden-bug, Pyrrhocoris apterus. The effect of photoperiod on the duration of linden-bug development at five constant temperatures (20, 22, 24, 26 and 28°C) was measured and the thermal requirements for development at three photope- riods (14, 17 and 20 h light per day) were calculated. Bugs from four geographic populations were used in these experiments: Pyatigorsk (44°02´N, 43°04´E), Borisovka (50°36´N, 36°01´E), Mikhailov (54°15´N, 39°0´E) and Ryazan (54°36´N, 39°42´E). From the values of individual development times at different temperatures the coefficient of linear regression of development rate (the inverse of the duration) on temperature and the thermal threshold for development were calculated. Both these parameters were found to decrease significantly with decrease in day-length for all four populations studied. It means that at shorter day-lengths nym- phal development is less dependent on temperature compared to the development at longer day-lengths. These effects seem to be adaptive. The development times of nymphs at relatively high temperatures (above 24-25°C) are shorter under long-days than under short days which should be advantageous at the height of summer when the days are long and the weather is warm. In the contrast, at relatively low temperatures (below 24-25°C) the nymphs develop significantly faster under short-days than under long days, which is advantageous at the end of summer as it allows the nymphs to reach the adult stage, the only stage capable of overwintering. The influence of photoperiod on the thermal reaction norm appeared to be more or less gradual, i.e. the shorter the day-length the shal- lower the slope of the regression line of development rate on temperature and the lower the thermal threshold for development. An analysis of the literature shows that this effect of photoperiod on the thermal requirements for development is widespread among insects but has been overlooked by previous authors. The authors conclude that the variation in the development time observed in insects at different seasons, photoperiods or food regimes, or from different populations, etc., are generally due to some modification of the thermal reaction norms and more specifically to differences in the thermal requirements for development.

Published

2007

35. Ecological emergence of thermal clines in body size

Author

Stéphane Legendre, Eric Edeline, Nicolas Poulet, Gérard Lacroix, Christine Delire, Biogéochimie et écologie des milieux continentaux (Bioemco), Centre National de la Recherche Scientifique (CNRS)-AgroParisTech-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut National de la Recherche Agronomique (INRA)-École normale supérieure - Paris (ENS Paris), Centre national de recherches météorologiques (CNRM), Météo France-Centre National de la Recherche Scientifique (CNRS), Écologie des organismes aquatiques, Office national de l'eau et des milieux aquatiques (ONEMA), Ministère de l'écologie, du développement durable et de l'énergie-Ministère de l'écologie, du développement durable et de l'énergie, Institut de biologie de l'ENS Paris (UMR 8197/1024) (IBENS), Département de Biologie - ENS Paris, École normale supérieure - Paris (ENS Paris)-École normale supérieure - Paris (ENS Paris)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Recherche Agronomique (INRA)-Université Pierre et Marie Curie - Paris 6 (UPMC)-AgroParisTech-Centre National de la Recherche Scientifique (CNRS), Institut national des sciences de l'Univers (INSU - CNRS)-Météo France-Centre National de la Recherche Scientifique (CNRS), Institut de biologie de l'ENS Paris (IBENS), Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Département de Biologie - ENS Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS Paris), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), ANR, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), École normale supérieure - Paris (ENS-PSL), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut de Recherche pour le Développement (IRD)-Institut National de la Recherche Agronomique (INRA)-Université Pierre et Marie Curie - Paris 6 (UPMC)-AgroParisTech-Centre National de la Recherche Scientifique (CNRS), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS), and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Paris (ENS-PSL)

Subjects

0106 biological sciences, life history, Competitive Behavior, Food Chain, Metabolic theory of ecology, thermal reaction norms, Biology, niche theory, Models, Biological, 010603 evolutionary biology, 01 natural sciences, metabolic theory of ecology, Animals, Body Size, Environmental Chemistry, Ecosystem, ComputingMilieux_MISCELLANEOUS, General Environmental Science, Trophic level, community interactions, Global and Planetary Change, Ecology, Community, food‐web structure, 010604 marine biology & hydrobiology, Population size, Global warming, Fishes, Temperature, size distributions, temperature‐size rule, Bergmann's rules, Biodiversity, Interspecific competition, 15. Life on land, predator–prey size ratio, Bergmann's rule, 13. Climate action, Predatory Behavior, [SDE.BE]Environmental Sciences/Biodiversity and Ecology

Abstract

International audience; The unprecedented rate of global warming requires a better understanding of how ecosystems will respond. Organisms often have smaller body sizes under warmer climates (Bergmann's rule and the temperature‐size rule), and body size is a major determinant of life histories, demography, population size, nutrient turnover rate, and food‐web structure. Therefore, by altering body sizes in whole communities, current warming can potentially disrupt ecosystem function and services. However, the underlying drivers of warming‐induced body downsizing remain far from clear. Here, we show that thermal clines in body size are predicted from universal laws of ecology and metabolism, so that size‐dependent selection from competition (both intra and interspecific) and predation favors smaller individuals under warmer conditions. We validate this prediction using 4.1 × 106 individual body size measurements from French river fish spanning 29 years and 52 species. Our results suggest that warming‐induced body downsizing is an emergent property of size‐structured food webs, and highlight the need to consider trophic interactions when predicting biosphere reorganizations under global warming.

Published

2013

36. How does the dengue vector mosquito Aedes albopictus respond to global warming?

Author

Jia P, Chen X, Chen J, Lu L, Liu Q, and Tan X

Subjects

Aedes growth & development, Animals, Dengue transmission, Ecosystem, Global Warming, Insect Vectors growth & development, Models, Biological, Seasons, Temperature, Aedes physiology, Insect Vectors physiology

Abstract

Background: Global warming has a marked influence on the life cycle of epidemic vectors as well as their interactions with human beings. The Aedes albopictus mosquito as the vector of dengue fever surged exponentially in the last decade, raising ecological and epistemological concerns of how climate change altered its growth rate and population dynamics. As the global warming pattern is considerably uneven across four seasons, with a confirmed stronger effect in winter, an emerging need arises as to exploring how the seasonal warming effects influence the annual development of Ae. albopictus., Methods: The model consolidates a 35-year climate dataset and designs fifteen warming patterns that increase the temperature of selected seasons. Based on a recently developed mechanistic population model of Ae. albopictus, the model simulates the thermal reaction of blood-fed adults by systematically increasing the temperature from 0.5 to 5 °C at an interval of 0.5 °C in each warming pattern., Results: The results show the warming effects are different across seasons. The warming effects in spring and winter facilitate the development of the species by shortening the diapause period. The warming effect in summer is primarily negative by inhibiting mosquito development. The warming effect in autumn is considerably mixed. However, these warming effects cannot carry over to the following year, possibly due to the fact that under the extreme weather in winter the mosquito fully ceases from development and survives in terms of diapause eggs., Conclusions: As the historical pattern of global warming manifests seasonal fluctuations, this study provides corroborating and previously ignored evidence of how such seasonality affects the mosquito development. Understanding this short-term temperature-driven mechanism as one chain of the transmission events is critical to refining the thermal reaction norms of the epidemic vector under global warming as well as developing effective mosquito prevention and control strategies.

Published

2017

37. Microgeographic differentiation in thermal performance curves between rural and urban populations of an aquatic insect

Author

Lin Op de Beeck, Nedim Tüzün, Kristien I. Brans, Lizanne Janssens, Robby Stoks, and Biology

Subjects

0106 biological sciences, 0301 basic medicine, growth‐survival trade‐off, urban heat islands, Growing season, thermal reaction norms, 010603 evolutionary biology, 01 natural sciences, Predation, 03 medical and health sciences, Damselfly, faster–slower model, Urbanization, Aquatic insect, Genetics, Urban heat island, thermal evolution, Ecology, Evolution, Behavior and Systematics, biology, Ecology, Original Articles, biology.organism_classification, 030104 developmental biology, Urban ecology, urban ecology, time stress, countergradient variation, Evolutionary ecology, Original Article, General Agricultural and Biological Sciences

Abstract

The rapidly increasing rate of urbanization has a major impact on the ecology and evolution of species. While increased temperatures are a key aspect of urbanization ("urban heat islands"), we have very limited knowledge whether this generates differentiation in thermal responses between rural and urban populations. In a common garden experiment, we compared the thermal performance curves (TPCs) for growth rate and mortality in larvae of the damselfly Coenagrion puella from three urban and three rural populations. TPCs for growth rate shifted vertically, consistent with the faster-slower theoretical model whereby the cold-adapted rural larvae grew faster than the warm-adapted urban larvae across temperatures. In line with costs of rapid growth, rural larvae showed lower survival than urban larvae across temperatures. The relatively lower temperatures hence expected shorter growing seasons in rural populations compared to the populations in the urban heat islands likely impose stronger time constraints to reach a certain developmental stage before winter, thereby selecting for faster growth rates. In addition, higher predation rates at higher temperature may have contributed to the growth rate differences between urban and rural ponds. A faster-slower differentiation in TPCs may be a widespread pattern along the urbanization gradient. The observed microgeographic differentiation in TPCs supports the view that urbanization may drive life-history evolution. Moreover, because of the urban heat island effect, urban environments have the potential to aid in developing predictions on the impact of climate change on rural populations. ispartof: Evolutionary Applications vol:10 issue:10 pages:1067-1075 ispartof: location:England status: published

38. Sperm plasticity to seawater temperatures in Atlantic cod Gadus morhua is affected more by population origin than individual environmental exposure

Author

Beirão, J., Purchase, C. F., Wringe, B. F., and Fleming, I. A.

Published

2014

39. Thermal Acclimation of Swimming Performance in Newt Larvae: The Influence of Diel Temperature Fluctuations during Embryogenesis

Author

Měráková, Eva and Gvoždík, Lumír

Published

2009