Your search keyword '"Klockmann, Michael"' showing total 9 results

1. Variation in adult stress resistance does not explain vulnerability to climate change in copper butterflies.

Author

Klockmann, Michael, Wallmeyer, Leonard, and Fischer, Klaus

Subjects

*CLIMATE change, *MATERIAL plasticity, *BUTTERFLY behavior, *DEHYDRATION, *POPULATION dynamics

Abstract

Abstract: Ongoing climate change is a major threat to biodiversity. However, although many species clearly suffer from ongoing climate change, others benefit from it, for example, by showing range expansions. However, which specific features determine a species’ vulnerability to climate change? Phenotypic plasticity, which has been described as the first line of defence against environmental change, may be of utmost importance here. Against this background, we here compare plasticity in stress tolerance in 3 copper butterfly species, which differ arguably in their vulnerability to climate change. Specifically, we investigated heat, cold and desiccation resistance after acclimatization to different temperatures in the adult stage. We demonstrate that acclimation at a higher temperature increased heat but decreased cold tolerance and desiccation resistance. Contrary to our predictions, species did not show pronounced variation in stress resistance, though plastic capacities in temperature stress resistance did vary across species. Overall, our results seemed to reflect population—rather than species‐specific patterns. We conclude that the geographical origin of the populations used should be considered even in comparative studies. However, our results suggest that, in the 3 species studied here, vulnerability to climate change is not in the first place determined by stress resistance in the adult stage. As entomological studies focus all too often on adults only, we argue that more research effort should be dedicated to other developmental stages when trying to understand insect responses to environmental change. [ABSTRACT FROM AUTHOR]

Published

2018

2. Effects of temperature and drought on early life stages in three species of butterflies: Mortality of early life stages as a key determinant of vulnerability to climate change?

Author

Klockmann, Michael and Fischer, Klaus

Subjects

*BUTTERFLIES, *STRESS in children, *CLIMATE change, *DEHYDRATION, *CLASSIFICATION of insects, *PHYSIOLOGICAL effects of heat, *ENVIRONMENTAL engineering

Abstract

Anthropogenic climate change poses substantial challenges to biodiversity conservation. Well-documented responses include phenological and range shifts, and declines in cold but increases in warm-adapted species. Thus, some species will suffer while others will benefit from ongoing change, although the biological features determining the prospects of a given species under climate change are largely unknown. By comparing three related butterfly species of different vulnerability to climate change, we show that stress tolerance during early development may be of key importance. The arguably most vulnerable species showed the strongest decline in egg hatching success under heat and desiccation stress, and similar pattern also for hatchling mortality. Research, especially on insects, is often focussed on the adult stage only. Thus, collating more data on stress tolerance in different life stages will be of crucial importance for enhancing our abilities to predict the fate of particular species and populations under ongoing climate change. [ABSTRACT FROM AUTHOR]

Published

2017

3. Carried over: Heat stress in the egg stage reduces subsequent performance in a butterfly.

Author

Klockmann, Michael, Kleinschmidt, Friederike, and Fischer, Klaus

Subjects

*BICYCLUS, *PHYSIOLOGICAL effects of heat, *ANTHROPOGENIC effects on nature, *CLIMATE change, *CLASSICAL mechanics

Abstract

Increasing heat stress caused by anthropogenic climate change may pose a substantial challenge to biodiversity due to associated detrimental effects on survival and reproduction. Therefore, heat tolerance has recently received substantial attention, but its variation throughout ontogeny and effects carried over from one developmental stage to another remained largely neglected. To explore to what extent stress experienced early in life affects later life stages, we here investigate effects of heat stress experienced in the egg stage throughout ontogeny in the tropical butterfly Bicyclus anynana. We found that detrimental effects of heat stress in the egg stage were detectable in hatchlings, larvae and even resulting adults, as evidenced by decreased survival, growth, and body mass. This study shows that even in holometabalous insects with discrete life stages effects of stress experienced early in life are carried over to later stages, substantially reducing subsequent fitness. We argue that such effects need to be considered when trying to forecast species responses to climate change. [ABSTRACT FROM AUTHOR]

Published

2017

4. Heat resistance throughout ontogeny: body size constrains thermal tolerance.

Author

Klockmann, Michael, Günter, Franziska, and Fischer, Klaus

Subjects

*INSECTS & climate, *EFFECT of temperature on insects, *INSECT larvae, *INSECT eggs, *PUPAE

Abstract

Heat tolerance is a trait of paramount ecological importance and may determine a species' ability to cope with ongoing climate change. Although critical thermal limits have consequently received substantial attention in recent years, their potential variation throughout ontogeny remained largely neglected. We investigate whether such neglect may bias conclusions regarding a species' sensitivity to climate change. Using a tropical butterfly, we found that developmental stages clearly differed in heat tolerance. It was highest in pupae followed by larvae, adults and finally eggs and hatchlings. Strikingly, most of the variation found in thermal tolerance was explained by differences in body mass, which may thus impose a severe constraint on adaptive variation in stress tolerance. Furthermore, temperature acclimation was beneficial by increasing heat knock-down time and therefore immediate survival under heat stress, but it affected reproduction negatively. Extreme temperatures strongly reduced survival and subsequent reproductive success even in our highly plastic model organism, exemplifying the potentially dramatic impact of extreme weather events on biodiversity. We argue that predictions regarding a species' fate under changing environmental conditions should consider variation in thermal tolerance throughout ontogeny, variation in body mass and acclimation responses as important predictors of stress tolerance. [ABSTRACT FROM AUTHOR]

Published

2017

5. Fitness implications of simulated climate change in three species of copper butterflies (Lepidoptera: Lycaenidae).

Author

KLOCKMANN, MICHAEL, KARAJOLI, FAJES, KUCZYK, JOSEPHINE, REIMER, STEPHANIE, and FISCHER, KLAUS

Subjects

*CLIMATE change, *BUTTERFLIES, *BIODIVERSITY, *HEAT waves (Meteorology), *COLD-blooded animals

Abstract

Ongoing climate change and especially the associated heat waves may pose a major challenge to biodiversity conservation. Although many ectotherms in temperate zones may benefit from current climate change, others will suffer. However, the specific biological features determining the response of a given species to climate change have remained largely unknown. In the present study, conducted in three copper butterfly species that likely differ in their vulnerability to climate change, we tested the responses to simulated heat waves using ecologically realistic diurnal temperature cycles. Surprisingly, we found little support for our hypothesis that the most vulnerable species will suffer most from simulated climate change. Although species differed significantly in their responses to treatments, such variation appears to be largely ruled by selection pressures associated with the specific developmental pathway. In general, simulated heat waves had little effect on fitness components including fat content and immune function. Consequently, all three species appear to be capable of dealing with projected changes during their larval and pupal development. Whether this also applies to other developmental stages, more extreme stress or indirect effects climate change remains to be seen. Identifying the critical factors determining the vulnerability of a species to climate change will remain an important task for future research. [ABSTRACT FROM AUTHOR]

Published

2017

6. Does narrow niche space in a 'cold-stenothermic' spring snail indicate high vulnerability to environmental change?

Author

Klockmann, Michael, Scharre, Mareike, Haase, Martin, and Fischer, Klaus

Subjects

*STENOTHOIDAE, *ECOLOGICAL niche, *SNAILS, *WATER pollution potential, *GLOBAL environmental change, *HABITATS

Abstract

Niche breadth has fundamental ecological implications. Specialists with a narrow niche space are able to survive under specific conditions only, making them potentially sensitive to effects of environmental change. We here investigate (1) the factors restricting the specialized spring snail Bythinella dunkeri to its specific habitat, and (2) its capacity for plasticity to respond to changing environmental conditions, based on a combination of field work and laboratory experiments. By comparing occupied and unoccupied sites, we revealed that snail presence was most strongly affected by distance to the crop-out, water depth, pH value, and redox potential. In contrast, spring temperatures did not affect the occurrence of this 'stenothermic' snail, and laboratory experiments documented a high tolerance toward both high and fluctuating temperatures. However, B. dunkeri was found to be very sensitive to desiccation, such that changes in precipitation regimes may easily harm populations. The species investigated here may therefore indeed be sensitive to environmental change, but not because of limited thermal tolerance which initially seemed to be the most obvious reason. [ABSTRACT FROM AUTHOR]

Published

2016

7. Simulating effects of climate change under direct and diapause development in a butterfly.

Author

Klockmann, Michael, Schröder, Uta, Karajoli, Fajes, and Fischer, Klaus

Subjects

*BUTTERFLY behavior, *INSECT development, *EFFECT of temperature on insects, *DIAPAUSE, *INSECT growth

Abstract

Temperature is one of the most important ecological factors affecting species survival and distributions. Therefore, global climate change, involving increases in mean surface temperature and the occurrence of extreme weather events, may pose a substantial challenge to biodiversity. Whereas tropical ectotherms are believed to be very sensitive to climate change, temperate-zone species may actually benefit from higher temperatures. However, as in temperate zones large parts of the year are unsuitable for growth and reproduction, seasonal time constraints may complicate matters. Against this background we here investigate the impact of simulated climate change, involving increased mean temperatures and heat waves, across developmental pathways of the butterfly Lycaena tityrus (Poda) (Lepidoptera: Lycaenidae). Increased temperatures speeded up development but decreased pupal mass as expected. However, we found no evidence for detrimental effects of increased temperatures or even simulated heat waves. Furthermore, patterns did not differ between indirectly and directly developing individuals, which are assumed to be more time constrained. Our findings support the notion that not all species will be detrimentally affected by climate change, and suggest that species attributes maybe more important than potential time constraints imposed by different developmental pathways. [ABSTRACT FROM AUTHOR]

Published

2016

8. Strong negative effects of simulated heat waves in a tropical butterfly.

Author

Fischer, Klaus, Klockmann, Michael, and Reim, Elisabeth

Subjects

*HEAT waves (Meteorology), *BUTTERFLIES, *CLIMATE change, *IMMUNE response, *COLD-blooded animals, *HUMIDITY

Abstract

Climate change poses a significant challenge to all natural systems on Earth. Especially increases in extreme weather events such as heat waves have the potential to strongly affect biodiversity, though their effects are poorly understood because of a lack of empirical data. Therefore, we here explore the sensitivity of a tropical ectotherm, which are in general believed to have a low warming tolerance, to experimentally simulated climate change using ecologically realistic diurnal temperature cycles. Increasing the mean temperature permanently by 3°C had mostly minor effects on developmental traits in the butterfly Bicyclus anynana. Simulated heat waves (strongly elevated temperatures for some time though retaining the same overall temperature mean), in contrast, caused strong negative effects by prolonging development time (by up to 10%) and reducing body mass (-21%), especially when combined with reduced relative humidity. Detrimental effects were carried over into the adult stage, diminishing subsequent performance. Most strikingly, higher temperatures suppressed adult immune function (haemocytes: -54%, lysozyme activity: -32%), which may potentially change the way species interact with antagonists. Heat waves thus reduced fitness parameters by 10-25% for development time and body mass and by up to 54% for immune parameters even in this plastic and widespread butterfly, exemplifying the potentially dramatic impact of extreme weather events on biodiversity. [ABSTRACT FROM AUTHOR]

Published

2014

9. Determinants of tree frog calling ponds in a human-transformed landscape.

Author

Fischer, Klaus, Becker, Marlen, Becker, Bianca, Bensch, Julia, Böckers, Andre, Burmeister, Martin, Dombrowski, Janine, Donke, Elisabeth, Ermisch, Rebecca, Fritze, Marcus, Fritzsch, Anna, Hübler, Nora, Ide, Marina, Klockmann, Michael, Mielke, Melanie, Pfender, David, Schiffler, Maria, Schrödter, Marlen, Sund, Lars, and Viertel, Caroline

Subjects

*HYLIDAE, *LANDSCAPES, *HABITATS, *CONSERVATION biology, *CROP circles, *VERTEBRATE populations

Abstract

Facing increasing human demands on Earth, understanding how endangered species may survive in isolated remnants of natural habitat within heavily transformed landscapes is key to contemporary conservation biology. Against this background we here investigate the factors affecting pond occupancy in the endangered European tree frog ( Hyla arborea L.) within an urban landscape, being located in north-eastern Germany where the species is still fairly common. Our survey revealed that 58 out of 122 ponds were occupied by H. arborea. Ponds with a higher percentage of floating vegetation, being deeper and surrounded by higher percentages of crop fields and forests were more likely to be occupied, while factors associated with urbanization such as the percentage of built-up area were strongly detrimental. Habitat requirements of H. arborea were complex as occurrence was simultaneously affected by different spatial scales, including the landscape scale, the immediate surroundings of ponds and the ponds themselves. H. arborea avoided highly urbanized areas, but occurred frequently in agricultural areas surrounding the city. The latter suggests that this species is fairly tolerant towards human-induced transformations, and that vast arable fields yielded positive rather than negative effects on H. arborea occurrence. We conclude that the most important conservation issues for supporting H. arborea populations at the periphery of urbanized areas are (1) maintaining an open (agricultural) landscape structure, (2) providing undisturbed overwintering habitats, and (3) maintaining pond quality by halting shrub and tree encroachment. [ABSTRACT FROM AUTHOR]

Published

2015