@phdthesis{Kleinhenz2008, author = {Kleinhenz, Marco}, title = {W{\"a}rme{\"u}bertragung im Brutbereich der Honigbiene (Apis mellifera)}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-26866}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {In dieser Arbeit untersuche ich das Verhalten von Arbeiterbienen beim Brutw{\"a}rmen, die W{\"a}rme{\"u}bertragung von den Bienen auf die gedeckelte Brut, die thermophysikalischen Eigenschaften des Brutnests und spezielle Aspekte des Brutnestaufbaus, die f{\"u}r dieses Thema relevant sind und bisher nicht untersucht wurden. Meine Arbeit umfasst Verhaltensbeobachtungen und thermografische Messungen an individuellen Bienen, die Simulation des Heizverhaltens von Arbeiterinnen und das Messen der Temperatur{\"a}nderungen in der Wabe, die Messung der thermophysikalischen Eigenschaften der Brutwabe und der Zellw{\"a}nde (W{\"a}rmeleitf{\"a}higkeit und Durchl{\"a}ssigkeit f{\"u}r W{\"a}rmestrahlung), die Auswertung von Brutzelltemperaturen als Ergebnis des Verhaltens von Arbeiterbienen, die Analyse der Anzahl und der r{\"a}umlichen Verteilung von Brutl{\"u}cken (Auswertung in 2-D und 3-D bez{\"u}glich beider Wabenseiten) und die Entwicklung spezifischer Computersoftware, die zur Erarbeitung dieser Ergebnisse unverzichtbar ist. Ein wichtiges Ergebnis dieser Arbeit ist die Entdeckung und Beschreibung eines bemerkenswerten, bislang unbekannten Verhaltens der Honigbiene: Die Aufrechterhaltung hoher Thoraxtemperaturen (TTh) bei Langzeitbesuchen in offenen Zellen („L{\"u}cken") die verstreut in der gedeckelten Brutfl{\"a}che vorkommen. Hier zeige ich, dass die Aufrechterhaltung der hohen TTh nicht auf den Zellinhalt (z. B. offene Brut) bezogen ist - in den meisten F{\"a}llen waren die besuchten Zellen ohnehin leer - sondern auf die direkt benachbarte gedeckelte Brut, mit der diese Zellen {\"u}ber gemeinsame Zellw{\"a}nde in Kontakt stehen. Dieses Verhalten liefert eine Erkl{\"a}rung f{\"u}r Langzeitzellbesuche von sehr langer Dauer ohne erkennbare Aktivit{\"a}t, die in fr{\"u}heren Arbeiten beschrieben aber nicht v{\"o}llig verstanden wurden, und es rehabilitiert die scheinbar „faulen" Bienen im Zellinnern. Diesem Verhalten kommt eine große Bedeutung f{\"u}r das Brutw{\"a}rmen zu, da sich der aufgeheizte Thorax tief in der Wabe (fast an der Mittelwand) befindet wo der W{\"a}rmeverlust an die Luft minimiert ist und von wo bis zu 6 umliegende Puppenzellen gleichzeitig gew{\"a}rmt werden k{\"o}nnen. Im Vergleich zum Brutw{\"a}rmeverhalten an der Wabenoberfl{\"a}che (Andr{\"u}cken des Thorax an die Brutdeckel), wo nur 1 oder Teile von 3 Brutdeckeln mit dem Thorax in Ber{\"u}hrung stehen, ist das W{\"a}rmen im Zellinnern mit derselben TTh bis zu 2,6-fach effizienter. Die Messung der thermophysikalischen Eigenschaften der Brutwabe und die Simulation des Brutw{\"a}rmeverhaltens unter kontrollierten Bedingungen zeigen, dass sich die Wabe langsam aufw{\"a}rmt und eher ein lokal begrenztes W{\"a}rmen als eine rasche W{\"a}rmeausbreitung {\"u}ber eine große Fl{\"a}che beg{\"u}nstigt. Der Einflussbereich eines einzelnen Zellbesuchers h{\"a}ngt von seiner TTh und der Dauer des Zellbesuchs ab. Anstiege der Bruttemperatur in bis zu 3 Zellen Abstand zum Zellbesucher sind nachweisbar. Das hier beschriebene Brutw{\"a}rmeverhalten im Innern von L{\"u}cken (offenen Zellen) bietet nicht nur neue Einsichten in das Bienenverhalten. Es erm{\"o}glicht auch eine Neubewertung der L{\"u}cken und ihrer N{\"u}tzlichkeit f{\"u}r die Bienen. Eine von mir entwickelte Computersoftware („CombUse 2.0") erm{\"o}glicht es, das Vorkommen und die r{\"a}umliche Verteilung von L{\"u}cken mit hoher Genauigkeit auf der Ebene einzelner Zellen zu erfassen und auszuwerten. Die r{\"a}umliche Verteilung der L{\"u}cken in der gedeckelten Brutfl{\"a}che zeigt, dass schon bei geringen L{\"u}ckenh{\"a}ufigkeiten von ca. 4 bis 10 \%, die in gesunden Kolonien normal sind, eine {\"u}berraschend große Zahl gedeckelter Brutzellen (88 \% bis 99 \%, wenn die dreidimensionale Verteilung ber{\"u}cksichtigt wird) im Einflussbereich von Brut w{\"a}rmenden Zellbesuchern sind. Obwohl das Brutw{\"a}rmeverhalten im Zellinnern schwer zu entdecken und zu beobachten ist, f{\"u}hren die in dieser Arbeit pr{\"a}sentierten Daten zu dem Schluss, dass es sich dabei um einen wichtigen Bestandteil der Nestklimatisierung bei Honigbienen handelt.}, subject = {Biene }, language = {de} } @phdthesis{Kehrberger2021, author = {Kehrberger, Sandra}, title = {Effects of climate warming on the timing of flowering and emergence in a tritrophic relationship: plants - bees - parasitoids}, doi = {10.25972/OPUS-21393}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-213932}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {The right timing of phenological events is crucial for species fitness. Species should be highly synchronized with mutualists, but desynchronized with antagonists. With climate warming phenological events advance in many species. However, often species do not respond uniformly to warming temperatures. Species-specific responses to climate warming can lead to asynchrony or even temporal mismatch of interacting species. A temporal mismatch between mutualists, which benefit from each other, can have negative consequences for both interaction partners. For host-parasitoid interactions temporal asynchrony can benefit the host species, if it can temporally escape its parasitoid, with negative consequences for the parasitoid species, but benefit the parasitoid species if it increases synchrony with its host, which can negatively affect the host species. Knowledge about the drivers of phenology and the species-specific responses to these drivers are important to predict future effects of climate change on trophic interactions. In this dissertation I investigated how different drivers act on early flowering phenology and how climate warming affects the tritrophic relationship of two spring bees (Osmia cornuta \& Osmia bicornis), an early spring plant (Pulsatilla vulgaris), which is one of the major food plants of the spring bees, and three main parasitoids of the spring bees (Cacoxenus indagator, Anthrax anthrax, Monodontomerus). In Chapter II I present a study in which I investigated how different drivers and their change over the season affect the reproductive success of an early spring plant. For that I recorded on eight calcareous grasslands around W{\"u}rzburg, Germany the intra-seasonal changes in pollinator availability, number of co-flowering plants and weather conditions and studied how they affect flower visitation rates, floral longevity and seed set of the early spring plant P. vulgaris. I show that bee abundances and the number of hours, which allowed pollinator foraging, were low at the beginning of the season, but increased over time. However, flower visitation rates and estimated total number of bee visits were higher on early flowers of P. vulgaris than later flowers. Flower visitation rates were also positively related to seed set. Over time and with increasing competition for pollinators by increasing numbers of co-flowering plants flower visitation rates decreased. My data shows that a major driver for early flowering dates seems to be low interspecific competition for pollinators, but not low pollinator abundances and unfavourable weather conditions. Chapter III presents a study in which I investigated the effects of temperature on solitary bee emergence and on the flowering of their food plant and of co-flowering plants in the field. Therefore I placed bee cocoons of two spring bees (O. cornuta \& O. bicornis) on eleven calcareous grasslands which differed in mean site temperature. On seven of these grasslands the early spring plant P. vulgaris occurred. I show that warmer temperatures advanced mean emergence in O. cornuta males. However, O. bicornis males and females of both species did not shift their emergence. Compared to the bees P. vulgaris advanced its flowering phenology more strongly with warmer temperatures. Co-flowering plants did not shift flowering onset. I suggest that with climate warming the first flowers of P. vulgaris face an increased risk of pollinator limitation whereas for bees a shift in floral resources may occur. In Chapter IV I present a study in which I investigated the effects of climate warming on host-parasitoid relationships. I studied how temperature and photoperiod affect emergence phenology in two spring bees (O. cornuta \& O. bicornis) and three of their main parasitoids (C. indagator, A. anthrax, Monodontomerus). In a climate chamber experiment with a crossed design I exposed cocoons within nest cavities and cocoons outside of nest cavities to two different temperature regimes (long-term mean of W{\"u}rzburg, Germany and long-term mean of W{\"u}rzburg + 4 °C) and three photoperiods (W{\"u}rzburg vs. Sn{\aa}sa, Norway vs. constant darkness) and recorded the time of bee and parasitoid emergence. I show that warmer temperatures advanced emergence in all studied species, but bees advanced less strongly than parasitoids. Consequently, the time period between female bee emergence and parasitoid emergence decreased in the warm temperature treatment compared to the cold one. Photoperiod influenced the time of emergence only in cocoons outside of nest cavities (except O. bicornis male emergence). The data also shows that the effect of photoperiod compared to the effect of temperature on emergence phenology was much weaker. I suggest that with climate warming the synchrony of emergence phenologies of bees and their parasitoids will amplify. Therefore, parasitism rates in solitary bees might increase which can negatively affect reproductive success and population size. In this dissertation I show that for early flowering spring plants low interspecific competition for pollinators with co-flowering plants is a major driver of flowering phenology, whereas other drivers, like low pollinator abundances and unfavourable weather conditions are only of minor importance. With climate warming the strength of different drivers, which act on the timing of phenological events, can change, like temperature. I show that warmer temperatures advance early spring plant flowering more strongly than bee emergence and flowering phenology of later co-flowering plants. Furthermore, I show that warmer temperatures advance parasitoid emergence more strongly than bee emergence. Whereas temperature changes can lead to non-uniform temporal shifts, I demonstrate that geographic range shifts and with that altered photoperiods will not change emergence phenology in bees and their parasitoids. In the tritrophic system I investigated in this dissertation climate warming may negatively affect the reproductive success of the early spring plant and the spring bees but not of the parasitoids, which may even benefit from warming temperatures.}, subject = {Biene }, language = {en} } @phdthesis{Kohl2023, author = {Kohl, Patrick Laurenz}, title = {The buzz beyond the beehive: population demography, parasite burden and limiting factors of wild-living honeybee colonies in Germany}, doi = {10.25972/OPUS-33032}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-330327}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {The western honeybee (Apis mellifera) is widely known as the honey producer and pollinator managed by beekeepers but neglected as a wild bee species. Central European honeybee populations have been anthropogenically disturbed since about 1850 through introgression and moderate artificial selection but have never been truly domesticated due to a lack of mating control. While their decline in the wild was historically attributed to the scarcity of nesting cavities, a contemporary view considers the invasion of the parasitic mite Varroa destructor in the 1970s as the major driver. However, there are no longitudinal population data available that could substantiate either claim. Based on the insight that introduced European honeybees form viable wild populations in eastern North America and reports on the occurrence of wild-living colonies from various European countries, we systematically studied the ecology of wild-living honeybees in Germany. First, we investigated whether wild-living honeybees colonising German forests form a self-sustaining population. Second, we asked how the parasite burden of wild-living colonies relates to that of managed colonies. And third, we explored whether the winter mortality of wild-living colonies is associated with parasite burden, nest depredation, or the lack of resources on the landscape scale. Between 2017 and 2021, we monitored listed trees with black woodpecker cavities for honeybees in the managed forests of three study regions (Swabian Alb, counties Coburg and Lichtenfels, county Weilheim-Schongau). Continuity of occupation was determined using microsatellite genetic markers. Wild-living colonies predictably colonised forests in summer, when about 10\% of all cavities were occupied. The annual colony survival rate and colony lifespan (based on N=112 colonies) were 10.6\% and 0.6 years, with 90\% of colonies surviving summer (July-September), 16\% surviving winter (September-April), and 72\% surviving spring (April-July). The average maximum and minimum colony densities were 0.23 (July) and 0.02 (April) colonies per km^2. During the (re-)colonisation of forests in spring, swarms preferred cavities that had already been occupied by other honeybee colonies. We estimate the net reproductive rate of the population to be R0= 0.318, meaning that it is currently not self-sustaining but maintained by the annual immigration of swarms from managed hives. The wild-living colonies are feral in a behavioural sense. We compared the occurrence of 18 microparasites among feral colonies (N=64) and managed colonies (N=74) using qPCR. Samples were collected in four regions (the three regions mentioned above and the city of Munich) in July 2020; they consisted of 20 workers per colony captured at flight entrances. We distinguished five colony types representing differences in colony age and management histories. Besides strong regional variation, feral colonies consistently hosted fewer microparasite taxa (median: 5, range 1-8) than managed colonies (median: 6, range 4-9) and had different parasite communities. Microparasites that were notably less prevalent among feral colonies were Trypanosomatidae, Chronic bee paralysis virus, and Deformed wing viruses A and B. In the comparison of five colony types, parasite burden was lowest in newly founded feral colonies, intermediate in overwintered feral colonies and managed nucleus colonies, and highest in overwintered managed colonies and hived swarms. This suggests that the natural mode of colony reproduction by swarming, which creates pauses in brood production, and well-dispersed nests, which reduce horizontal transmission, explain the reduced parasite burden in feral compared to managed colonies. To explore the roles of three potential drivers of feral colony winter mortality, we combined colony observations gathered during the monitoring study with data on colony-level parasite burden, observations and experiments on nest depredation, and landscape analyses. There was no evidence for an effect of summertime parasite burden on subsequent winter mortality: colonies that died (N=57) did not have a higher parasite burden than colonies that survived (N=10). Camera traps (N=15) installed on cavity trees revealed that honeybee nests are visited by a range of vertebrate species throughout the winter at rates of up to 10 visits per week. Four woodpecker species, great tits, and pine martens acted as true nest depredators. The winter survival rate of colonies whose nest entrances were protected by screens of wire mesh (N=32) was 50\% higher than that of colonies with unmanipulated entrances (N=40). Analyses of land cover maps revealed that the landscapes surrounding surviving colonies (N=19) contained on average 6.4 percentage points more resource-rich cropland than landscapes surrounding dying colonies (N=94). We estimate that tens of thousands of swarms escape from apiaries each year to occupy black woodpecker cavities and other hollow spaces in Germany and that feral colonies make up about 5\% of the regional honeybee populations. They are unlikely to contribute disproportionately to the spread of bee diseases. Instead, by spatially complementing managed colonies, they contribute to the pollination of wild plants in forests. Honeybees occupying tree cavities likely have various effects on forest communities by acting as nest site competitors or prey, and by accumulating biomass in tree holes. Nest depredation (a consequence of a lack of well-protected nest sites) and food resource limitation seem to be more important than parasites in hampering feral colony survival. The outstanding question is how environmental and intrinsic factors interact in preventing population establishment. Nest boxes with movable frames could be used to better study the environmental drivers of feral colonies' mortality. Pairs of wild (self-sustaining) and managed populations known to exist outside Europe could provide answers to whether modern apiculture creates honeybee populations maladapted to life in the wild. In Europe, large continuous forests might represent evolutionary refuges for wild honeybees.}, subject = {Biene }, language = {en} }