Your search keyword '"Helmut, Käfer"' showing total 9 results

1. The respiratory metabolism of overwintering paper wasp gynes ( Polistes dominula and Polistes gallicus )

Author

Helmut Käfer, Anton Stabentheiner, Helmut Kovac, and Iacopo Petrocelli

Subjects

Paper wasp, Physiology, Insect Science, Respiratory metabolism, Zoology, Biology, Polistes gallicus, biology.organism_classification, Polistes dominula, Ecology, Evolution, Behavior and Systematics, Overwintering

Published

2021

2. Energetics of Paper Wasps (

Author

Helmut, Kovac, Helmut, Käfer, Iacopo, Petrocelli, Astrid B, Amstrup, and Anton, Stabentheiner

Abstract

Paper wasps are widely distributed in Europe. They live in the warm Mediterranean, and in the harsh Alpine climate. Some species are very careful in their choice of nesting sites to ensure a proper development of the brood. We investigated microclimate conditions at the nests of three species (

Published

2022

3. Effect of climate on strategies of nest and body temperature regulation in paper wasps, Polistes biglumis and Polistes gallicus

Author

Anton Stabentheiner, Julia Magdalena Nagy, Helmut Kovac, Helmut Käfer, Iacopo Petrocelli, and Stefano Turillazzi

Subjects

Multidisciplinary, Wasps, Temperature, Animals, Water, Body Temperature Regulation, Nesting Behavior

Abstract

Polistes paper wasps are a widespread taxon inhabiting various climates. They build nests in the open without a protective outer layer, which makes them vulnerable to changing temperatures. To better understand the options they have to react to environmental variation and climate change, we here compare the thermoregulatory behavior of Polistes biglumis from cool Alpine climate with Polistes gallicus from warm Mediterranean climate. Behavioral plasticity helps both of them to withstand environmental variation. P. biglumis builds the nests oriented toward east-south-east to gain solar heat of the morning sun. This increases the brood temperature considerably above the ambience, which speeds up brood development. P. gallicus, by contrast, mostly avoids nesting sites with direct insolation, which protects their brood from heat stress on hot days. To keep the brood temperature below 40–42 °C on warm days, the adults of the two species show differential use of their common cooling behaviors. While P. biglumis prefers fanning of cool ambient air onto the nest heated by the sun and additionally cools with water drops, P. gallicus prefers cooling with water drops because fanning of warm ambient air onto a warm nest would not cool it, and restricts fanning to nests heated by the sun.

Published

2021

4. Relation between activity, endothermic performance and respiratory metabolism in two paper wasps: Polistes dominula and Polistes gallicus

Author

Bettina Kundegraber, Helmut Käfer, Anton Stabentheiner, Helmut Kovac, and Iacopo Petrocelli

Subjects

0106 biological sciences, 0301 basic medicine, Mediterranean climate, Physiology, Range (biology), Wasps, Metabolic adaptation, Zoology, Climate change, Polistes dominula, 010603 evolutionary biology, 01 natural sciences, Biochemistry, Body Temperature, 03 medical and health sciences, Species Specificity, Animals, Molecular Biology, Energy demand, biology, Respiration, Carbon Dioxide, biology.organism_classification, 030104 developmental biology, Respiratory metabolism, Polistes gallicus

Abstract

Climate change is expected to produce shifts in species distributions as well as behavioural and physiological adaptations to find suitable conditions or to cope with the altered environment. The paper wasps Polistes dominula and Polistes gallicus are closely related species, native in the European Mediterranean region and North Africa. P. dominula has expanded its range to the relatively cooler climates of Northern and Eastern Europe, but P. gallicus remained in its original distribution area. In order to reveal their metabolic adaptation to the current climate conditions, and the impact on energy demand at future climate conditions, we investigated the respiratory metabolic rate (CO2 production) of P. dominula from Austria and P. gallicus from Italy. In contrast to the metabolic cold adaptation hypothesis their standard metabolic rate was nearly the same and increased in a typical exponential course with increasing ambient temperature. The metabolic rate of active wasps was higher than the standard metabolic rate and increased with the wasps' activity. There was no obvious difference in the active metabolism between the two species, with the exception that some P. gallicus individuals showed some extraordinary high values. A simultaneous measurement of metabolic rate and body temperature revealed that increased CO2 production was accompanied by endothermic activity. The two investigated populations of paper wasps are quite similar in their metabolic response to temperature, although they live in different climate regions. The spread of P. dominula into cooler regions did not have significant influence on their active and standard metabolic rate.

Published

2020

5. Wasps - The Astonishing Diversity of a Misunderstood Insect by Eric R. Eaton

Author

Helmut Käfer

Subjects

Sting, History, Insect Science, media_common.quotation_subject, Ethnology, Belligerent, Insect, Diversity (politics), media_common

Abstract

Most people associate wasps with their sting. These belligerent nuisances use it liberally when they invade serene picnics or cheerful barbecues or while defending their colonies, which they constr...

Published

2021

6. The energetics and thermoregulation of water collecting honeybees

Author

Anton Stabentheiner, Helmut Kovac, and Helmut Käfer

Subjects

030110 physiology, 0106 biological sciences, 0301 basic medicine, Physiology, Foraging, Honeybee, 010603 evolutionary biology, 01 natural sciences, Thermoregulation, 03 medical and health sciences, Behavioral Neuroscience, Animal science, Osmoregulation, Energetics, Animals, Ecology, Evolution, Behavior and Systematics, Ecosystem, Motivation, Original Paper, Energy demand, Collecting, Behavior, Animal, Liquid food, Temperature, Water, Honey, Bees, Brood, Environmental science, Animal Science and Zoology, Seasons, Energy Metabolism, Body Temperature Regulation

Abstract

Honeybees need water for different purposes, to maintain the osmotic homeostasis in adults as well as to dilute stored honey and prepare liquid food for the brood. Water is also used for cooling of the hive. Foraging in endothermic insects is energy-intensive and the question arises how much energy bees invest in a resource without any metabolically usable energy. We investigated the energy demand of water collecting bees under natural conditions. The thermoregulation and energetic effort was measured simultaneously in a broad range of experimental ambient temperatures (Ta = 12–40 °C). The thorax temperature as well as the energetic turnover showed a great variability. The mean Tthorax was ranging from ~ 35.7 °C at 12 °C to nearly 42.5 °C at 40 °C. The energy turnover calculated from CO2-release was highest at a Ta of 20 °C with about 60 mW and lowest at 40 °C with about 22 mW per bee. The total costs during collection decreased from 10.4 J at 12 °C to 0.5 J at 40 °C. The energetic effort of the water collectors was comparable with that of 0.5 M sucrose foraging bees. Our investigation strongly supports the hypothesis that the bees’ motivational status determines the energetic performance during foraging. Electronic supplementary material The online version of this article (10.1007/s00359-018-1278-9) contains supplementary material, which is available to authorized users.

Published

2018

7. Comparison of thermal traits of Polistes dominula and Polistes gallicus, two European paper wasps with strongly differing distribution ranges

Author

Anton Stabentheiner, Iacopo Petrocelli, Helmut Kovac, and Helmut Käfer

Subjects

030110 physiology, 0106 biological sciences, 0301 basic medicine, Physiology, Range (biology), Climate, Wasps, Microclimate, Biology, Metabolic rate, Environment, Polistes dominula, 010603 evolutionary biology, 01 natural sciences, Biochemistry, Body Temperature, Polistes gallicus, 03 medical and health sciences, Endocrinology, Nest, Seasonal breeder, Animals, Critical thermal maximum, Ecology, Evolution, Behavior and Systematics, Overwintering, Original Paper, Ecology, Temperature, Thermal limits, Carbon Dioxide, biology.organism_classification, Adaptation, Physiological, Italy, 13. Climate action, Animal Science and Zoology, Female, Basal Metabolism

Abstract

The two paper wasps, Polistes dominula and Polistes gallicus, are related species with strongly differing distribution ranges. We investigated thermal tolerance traits (critical thermal limits and metabolic response to temperature) to gain knowledge about physiological adaptations to their local climate conditions and to get evidence for the reasons of P. dominula’s successful dispersion. Body and ambient temperature measurements at the nests revealed behavioural adaptations to microclimate. The species differed clearly in critical thermal minimum (P. dominula −1.4 °C, P. gallicus −0.4 °C), but not significantly in critical thermal maximum of activity (P. dominula 47.1 °C, P. gallicus 47.6 °C). The metabolic response did not reveal clear adaptations to climate conditions. At low and high temperatures, the metabolic rate of P. dominula was higher, and at intermediate temperatures, we determined higher values in P. gallicus. However, the species exhibited remarkably differing thermoregulatory behaviour at the nest. On average, P. gallicus tolerated a thoracic temperature up to ~41 °C, whereas P. dominula already tried at ~37 °C to keep the thorax below ambient temperature. We suggest this to be an adaptation to the higher mean ambient temperature we measured at the nest during a breeding season. Although we determined for P. dominula a 0.5 °C larger thermal tolerance range, we do not presume this parameter to be solely responsible for the successful distribution of P. dominula. Additional factors, such as the thermal tolerance of the queens could limit the overwintering success of P. gallicus in a harsher climate.

Published

2016

8. Assessing honeybee and wasp thermoregulation and energetics—New insights by combination of flow-through respirometry with infrared thermography

Author

Helmut Kovac, Anton Stabentheiner, Stefan K. Hetz, Helmut Käfer, and Gabriel Stabentheiner

Subjects

0106 biological sciences, 030310 physiology, media_common.quotation_subject, Flow (psychology), Foraging, Honeybee, Zoology, Insect, 010603 evolutionary biology, 01 natural sciences, Article, 03 medical and health sciences, Respirometry, Thermography / Respirometry / Energetics / Temperature / Honeybee / Wasp, Energetics, Critical thermal maximum, Physical and Theoretical Chemistry, Instrumentation, media_common, 0303 health sciences, Temperature, Thermoregulation, Wasp, Condensed Matter Physics, Thermography, Environmental science

Abstract

Graphical abstract . Highlights ► We demonstrate the benefits of a combined use of infrared thermography with respiratory measurements in insect ecophysiological research. ► Infrared thermography enables repeated investigation of behaviour and thermoregulation without behavioural impairment. ► Comparison with respirometry brings new insights into the mechanisms of energetic optimisation of bee and wasp foraging. ► Combination of methods improves interpretation of respiratory traces in determinations of insect critical thermal limits., Endothermic insects like honeybees and some wasps have to cope with an enormous heat loss during foraging because of their small body size in comparison to endotherms like mammals and birds. The enormous costs of thermoregulation call for optimisation. Honeybees and wasps differ in their critical thermal maximum, which enables the bees to kill the wasps by heat. We here demonstrate the benefits of a combined use of body temperature measurement with infrared thermography, and respiratory measurements of energy turnover (O2 consumption or CO2 production via flow-through respirometry) to answer questions of insect ecophysiological research, and we describe calibrations to receive accurate results. To assess the question of what foraging honeybees optimise, their body temperature was compared with their energy turnover. Honeybees foraging from an artificial flower with unlimited sucrose flow increased body surface temperature and energy turnover with profitability of foraging (sucrose content of the food; 0.5 or 1.5 mol/L). Costs of thermoregulation, however, were rather independent of ambient temperature (13–30 °C). External heat gain by solar radiation was used to increase body temperature. This optimised foraging energetics by increasing suction speed. In determinations of insect respiratory critical thermal limits, the combined use of respiratory measurements and thermography made possible a more conclusive interpretation of respiratory traces.

Published

2012

9. Respiration and metabolism of the resting European paper wasp (Polistes dominulus)

Author

Helmut, Käfer, Helmut, Kovac, Barbara, Oswald, and Anton, Stabentheiner

Subjects

Original Paper, Pulmonary Gas Exchange, Respiration, Wasps, Carbon Dioxide, Environment, Adaptation, Physiological, Survival Analysis, Body Temperature, Europe, Resting metabolism, Insects, Animals, Female, Basal Metabolism, Seasons, Adaptation, Polistes

Abstract

The European paper wasp, Polistes dominulus Christ, is an abundant wasp species in South and Central Europe which dispersed to the north in recent times. Polistes dominulus exhibits an energy-extensive mode of life, spending much time resting at the nest, which should be reflected in adaptations regarding gas exchange and standard metabolism. We analysed the resting metabolism (CO2 emission) of Polistes dominulus workers in the ambient temperature range an individual may be exposed to during a breeding season (Ta = 2.4–40.6 °C) via flow through respirometry. Behaviour and endothermic activity were assessed by infrared thermography. With rising Ta, CO2 release followed an exponential increase from 27 to 149 and 802 nl g−1 min−1 at Ta = 3, 20 and 35 °C, respectively. Measurements of the thermal regime at the nest showed that resting P. dominulus are most of the time in the lower range of their standard metabolic curve. A comparison with a “highly energetic” wasp like Vespula sp. revealed that Polistes dominulus not only optimises behaviour but also reduces metabolism to save energy. The CO2 emission patterns changed with ambient temperature, from discontinuous (≤25 °C) to cyclic (25–36 °C) and continuous gas exchange at higher temperatures. A pronounced break appeared in the data progression regarding cycle frequency and CO2 emission per gas exchange cycle between 15 and 10 °C. This striking change in gas exchange features indicates a physiological adaptation to special respiratory requirements at low temperatures. Electronic supplementary material The online version of this article (doi:10.1007/s00360-015-0915-7) contains supplementary material, which is available to authorised users.

Published

2015