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Das angeborene Immunsystem von Insekten besteht aus einer humoralen Komponente, einer zellulären Komponente und dem Prophenoloxidase-aktivierenden System. Fast alle Erkenntnisse über das angeborene Immunsystem stammen von Arbeiten mit Modellorganismen wie z.B. Drosophila oder Anopheles gambiae. Wie genau das Immunsystem der Honigbiene (Apis mellifera) funktioniert, ist jedoch noch relativ unbekannt. In der vorliegenden Arbeit wurden die unterschiedlichen Immunreaktionen aller drei Entwicklungsstadien der Honigbiene nach artifizieller Infektion mit Gram-negativen und Gram-positiven Bakterien (Escherichia coli und Micrococcus flavus) und dem Akuten Bienen Paralyse Virus (ABPV) untersucht und verglichen. Eine E. coli-Injektion zeigt bei Larven und adulten Arbeiterinnen nur wenig Auswirkung auf das äußere Erscheinungsbild und die Überlebensrate. In beiden Entwicklungsstadien wird die humorale Immunantwort stark induziert, erkennbar an der Expression der antimikrobiellen Peptide (AMPs) Hymenoptaecin, Defensin1 und Abaecin. Zusätzlich werden allein in Jungbienen nach bakterieller Infektion vier weitere immunspezifische Proteine exprimiert. Unter anderem eine Carboxylesterase (CE1) und das Immune-Responsive Protein 30 (IRp30). Die Expression von CE1 und IRp30 zeigt dabei den gleichen zeitlichen Verlauf wie die der AMPs. In Jungbienen kommt es zudem nach E. coli-Injektion zu einer raschen Abnahme an lebenden Bakterien in der Hämolymphe, was auf eine Aktivierung der zellulären Immunantwort schließen lässt. Ältere Bienen und Winterbienen zeigen eine stärkere Immunkompetenz als Jungbienen. Selbst nicht-infizierte Winterbienen exprimieren geringe Mengen der immunspezifischen Proteine IRp30 und CE1. Die Expression von IRp30 kann dabei durch Verwundung oder Injektion von E. coli noch gesteigert werden. Eine weitere Besonderheit ist die im Vergleich zu Jungbienen raschere Abnahme an lebenden Bakterien in der Hämolymphe bis hin zur vollständigen Eliminierung. Die Reaktion von Puppen auf eine bakterielle Infektion war völlig unerwartet. Nach Injektion von E. coli-Zellen kommt es innerhalb von 24 h p.i. zu einem tödlichen Kollaps, der sich in einer Graufärbung des gesamten Puppenkörpers äußert. Da keine Expression von AMPs nachzuweisen war, wird die humorale Immunantwort offensichtlich nicht induziert. Auch die zelluläre Immunantwort scheint nicht aktiviert zu werden, denn es konnte keine Abnahme an lebenden E. coli-Zellen beobachtet werden. Aufgrund dieser fehlenden Immunreaktionen vermehrt sich E. coli im Hämocoel infizierter Puppen und scheint damit deren Tod herbeizuführen. Nach viraler Infektion wurden in allen drei Entwicklungsstadien der Honigbiene gänzlich andere Reaktionen beobachtet als nach bakterieller Infektion. Bei dem verwendeten Akuten Bienen Paralyse Virus (ABPV) handelt es sich um ein Picorna-ähnliches Virus, dessen Vermehrung in der Hämolymphe über die massive Synthese der Capsidproteine verfolgt werden kann. Eine Injektion von sehr wenigen ABPV-Partikeln ins Hämocoel hat dramatische Auswirkungen auf Larven. Nach Virusinjektion kommt es innerhalb weniger Stunden zu einer raschen Virusvermehrung und schon 24 h p.i. zum Tod, häufig begleitet von einer Schwarzfärbung der gesamten Larve. Kurz vor dem Ableben kommt es neben dem Abbau hochmolekularer Speicherproteine zur Expression zahlreicher Proteine, die u.a. an der Translation oder dem Schutz vor oxidativem Stress beteiligt sind. Auf Jungbienen hat eine ABPV-Infektion keine so dramatischen Auswirkungen wie auf Larven. Sie zeigen lediglich Zeichen von Paralyse, zudem überleben sie länger bei höheren injizierten Partikelzahlen, die Virusvermehrung ist langsamer und es kommt zu keiner starken Veränderung des Hämolymph-Proteinmusters. Es konnte gezeigt werden, dass es in ABPV-infizierten Larven oder adulten Bienen zu keiner erkennbaren Aktivierung des humoralen Immunsystems in Form von exprimierten AMPs kommt. Zudem scheint die humorale Immunantwort auch nicht unterdrückt zu werden, denn nach gleichzeitiger Injektion von E. coli und ABPV kommt es neben der Expression viraler Capsidproteine auch zur Expression von AMPs. Zusätzlich konnte in Jungbienen nach Infektion mit ABPV eine zelluläre Immunantwort in Form von Nodulation ausgeschlossen werden. Ältere Bienen scheinen nicht nur mit bakteriellen Infektionen, sondern auch mit einer ABPV-Infektion besser zurechtzukommen. Bei einer Menge an ABPV-Partikeln, die in Jungbienen spätestens 72 h p.i. zum Tod führt, ist in Winterbienen eine Virusvermehrung erst ab 96 h p.i. erkennbar und diese beeinträchtigt die Überlebensrate kaum. Puppen sind einer Virusinfektion genauso schutzlos ausgeliefert wie einer Bakterieninfektion. Es kommt zwar zu keiner starken Änderung des äußeren Erscheinungsbildes, jedoch bleiben Puppen in ihrer Entwicklung komplett stehen. Das Virus muss sich daher stark vermehren, allerdings nicht überwiegend - wie bei Larven und adulten Bienen - in der Hämolymphe.
Like many other social insect societies, honeybees collectively share the resources they gather by feeding each other. These feeding contacts, known as trophallaxis, are regarded as the fundamental basis for social behavior in honeybees and other social insects for assuring the survival of the individual and the welfare of the group. In honeybees, where most of the trophallactic contacts are formed in the total darkness of the hive, the antennae play a decisive role in initiation and maintenance of the feeding contact, because they are sensitive to gustatory stimuli. The sequences of behaviors performed by the receiver bees at the beginning of a feeding contact includes the contact of one antenna with the mouthparts of a donor bee where the regurgitated food is located. The antennal motor action is characterized by behavioral asymmetry, which is novel among communicative motor actions in invertebrates. This preference of right over left antenna is without exception even after removal of the antennal flagellum. This case of laterality in basic social interaction might have its reason in the gustatory asymmetry in the antennae, because the right antenna turns out to be significantly more sensitive to stimulation with sugar water of various concentrations than the left one. Trophallactic contacts which guarantee a constant access to food for every individual in the hive are vitally important to the honeybee society, because honeybees are heterothermic insects which actively regulate their thoracic temperature. Even though the individual can regulate its body temperature, its heating performance is strictly limited by the amount of sugar ingested. The reason for this is that honeybees use mostly the glucose in their hemolymph as the energy substrate for muscular activity, and the heat producing flight muscles are among the metabolically most active tissues known. The fuel for their activity is honey; processed nectar with a sugar content of ~80% stored in the honeycomb. The results show that the sugar content of the ingested food correlates positively with the thoracic temperature of the honeybees even if they are caged and show no actual heating-related behavior as in brood warming or heating in the centre of the winter cluster. Honeybees actively regulate their brood temperature by heating to keep the temperature between 33 °C to 36 °C if ambient temperatures are lower. Heating rapidly depletes the worker’s internal energy; therefore the heating performance is limited by the honey that is ingested before the heating process. This study focused on the behavior and the thoracic temperature of the participants in trophallactic food exchanges on the brood comb. The brood area is the centre of heating activity in the hive, and therefore the region of highest energy demand. The results show that the recipients in a trophallactic food exchange have a higher thoracic temperature during feeding contacts than donors, and after the feeding contact the former engage in brood heating more often. The donor bees have lower thoracic temperature and shuttle constantly between honey stores and the brood comb, where they transfer the stored honey to heating bees. In addition, the results show a heat-triggered mechanism that enables donor and recipient to accomplish trophallactic contacts without delay in the total darkness of the hive in the brood area as the most energy consuming part of the hive. Providing heat-emitting workers with small doses of high performance fuel contributes to an economic distribution of resources consistent with the physiological conditions of the bees and the ecological requirements of the hive, resulting in a highly economical resource management system which might be one of the factors favouring the evolution of perennial bee colonies in temperate regions. The conclusion of these findings suggests a resource management strategy that has evolved from submissive placation behavior as it is seen in honeybees, bumblebees and other hymenopterans. The heat-triggered feedback mechanism behind the resource management of the honeybee´s thermoregulatory behavior reveals a new aspect of the division of labor and a new aspect of communication, and sheds new light on sociality in honeybees.
The proventriculus regulates the food passage from crop to midgut. As the haemolymph provides a constantly updated indication of an insect’s nutritional state, it is assumed that the factor controlling the proventri-culus activity is to be found in the haemolymph. The purpose of this doctoral thesis was to investigate how output (metabolic rate), input (food quality and food quantity) and internal state variables (haemolymph osmolarity and haemolymph sugar titer) affect each other and which of these factors controls the activity of the proventriculus in the honeybee. Therefore free-flying foragers were trained to collect con-trolled amounts of different sugar solutions. Immediately after feeding, metabolic rates were measured over different periods of time, then crop-emptying rates and haemolymph sugar titers were measured for the same individual bees. Under all investigated conditions, both the sugar transport rates through the proventriculus and the haemolyph sugar titers depended mainly on the metabolism. For bees collecting controlled amounts of 15 per cent, 30 per cent or 50 per cent sucrose solution haemolymph trehalose, glucose and fructose titers were constant for metabolic rates from 0 to 4.5 mlCO2/h. At higher metabolic rates, trehalose concentration decreased while that of glucose and fructose increased with the exception of bees fed 15 per cent sucrose solution. As the supply of sugar from the crop via the proventriculus was sufficient to support even the highest metabolic rates, the observed pattern must result from an upper limit in the capacity of the fat body to synthesise trehalose. The maximal rate of conversion of glucose to trehalose in the fat body was therefore calculated to average 92.4 µg glucose/min. However, for bees fed 15 per cent sucrose solution both the rate of conversion of glucose to trehalose and the rate of sugar transport from the crop to the midgut were limited, causing an overall decrease in total haemolymph sugar titers for metabolic rates higher than 5 mlCO2/h. Haemolymph sucrose titers were generally low but increased with increasing metabolic rates, even though sucrose was not always detected in bees with high metabolic rates. Though foragers were able to adjust their sugar transport rates precisely to their metabolic rates, a fixed surplus of sugars was transported through the proventriculus under specific feed-ing conditions. This fixed amount of sugars increased with increasing concentration and in-creasing quantity of fed sugar solution, but decreased with progressing time after feeding. This fixed amount of sugars was independent of the metabolic rates of the bees and of the molarity and viscosity of the fed sugar solution. As long as the bees did not exhaust their crop content, the haemolymph sugar titers were unaffected by the sugar surplus, by the time after feeding, by the concentration and by the viscosity of fed sugar solution. When bees were fed pure glucose (or fructose) solutions, un-usually little fructose (or glucose) was found in the haemolymph, leading to lower total haemolymph sugar titers, while the trehalose titer remained unaffected. In order to investigate the mechanisms underlying the regulation of the honeybee proven-triculus, foraging bees were injected either with metabolisable (glucose, fructose, trehalose), or non-metabolisable sugars (sorbose). Bees reacted to injections of metabolisable sugars with reduced crop-emptying rates, but injection of non-metabolisable sugars had no influence on crop emptying. Therefore it is concluded that the proventriculus regulation is controlled by the concentration of metabolisable compounds in the haemolymph, and not by the haemo-lymph osmolarity. A period of 10min was enough to observe reduced crop emptying rates after injections. It is suggested that glucose and fructose have an effect on the proventriculus activity only via their transformation to trehalose. However, when the bees were already in-jected 5min after feeding, no response was detectable. In addition it was investigated whether the overregulation is the result of feed-forward regulation for the imminent take-off and flight. In a first experiment, we investigated whether the bees release an extra amount of sugar solution very shortly before leaving for the hive. In a second experiment, it was tested whether the distance covered by the bees might have an influence on the surplus amount released prior to the take-off. In a third experiment, it was investigated if walking bees fail to release this extra amount of sugars, as they do not have to fly. Though we were not able to demonstrate that the overregulation is the result of feed-forward regulation for the imminent take-off and flight, it is conceivable that this phenome-non is a fixed reaction in foragers that can not be modulated. To investigate whether regulated haemolymph sugar titers are also observed in honeybee foragers returning from natural food sources, their crop contents and haemolymph sugar titers were investigated. While the quantity of the collected nectar was without influence on the haemolymph sugar titers, foragers showed increasing haemolymph sugar titers of glucose, fructose and sucrose with increasing sugar concentration of the carried nectar. In contrast no relationship between crop nectar concentrations and haemolymph trehalose titers was observed. We are sure that the regulation of food passage from crop to midgut is controlled by the trehalose titer. However, under some conditions the balance between consumption and income is not numerically exact. This imprecision depends on the factors which have an impact on the foraging energetics of the bees but are independent of those without influence on the foraging energetics. Therefore we would assume that the proventriculus activity is modulated by the motivational state of the bees.
3. Zusammenfassung Ein noch immer unvollständig verstandenes Problem sind die exakten Mechanismen der Arbeitsteilung und Koordination innerhalb von Bienenvölkern Apis mellifera. Auf der einen Seite muss die sensorische und neuronale Ausstattung jedes Individuums das Potential zur Kommunikation und Aufgabenbewältigung enthalten, zum anderen müssen jedem Bienenvolk Mechanismen zur Steuerung zur Verfügung stehen, die auch so weit in die Zukunft reichenden Notwendigkeiten wie Wintervorbereitungen zuverlässig durchführen. Die vorliegende Arbeit beleuchtet daraus ausgewählte Aspekte. Zum einen werden Aspekte der kognitiven Fähigkeiten der Einzelbienen untersucht, die im Hinblick auf ihre Rolle als sammelnde Arbeiterinnen eine wichtige Rolle spielen. Das Erkennen und Verarbeiten von Mustern spielt eine wichtige Rolle beim Auffinden von potentiellen Nahrungsquellen. Hier konnte mittels des DMTS – Paradigma ein hoher Abstraktionsgrad der Musterverarbeitung sowie eine Speicherung auch komplexer Muster gezeigt werden. Zum anderen wird die Bruttemperatur als ein Einfluss auf die Puppenentwicklung und dessen mögliche Folgen auf kognitive Fähigkeiten und Lebenshistorie untersucht. Variation der Bruttemperatur wurde in verschiedenen Zusammenhängen als starker Einfluss auf unterschiedliche Aspekte der Entwicklung gezeigt. In der vorliegenden Arbeit kann diese Bruttemperatur als möglicher Faktor der nachfolgend unterschiedlichen Ausprägung von Verhaltensmustern gezeigt werden. Dabei wird ebenso auf die Unterschiede im Verhaltensmuster von täglichen Stocktätigkeiten wie auf die resultierenden Unterschiede in der Lebensgeschichte und –spanne eingegangen, die aus unterschiedlichen Brutaufzuchtstemperaturen resultieren können. Als Aufzuchtstemperaturen werden dabei 32°C, 35°C sowie 36°C verwendet, um eine Vari ation zwischen der an anderer Stelle berichteten mittleren, der niedrigsten und der höchsten Temperatur für morphologisch vollständig entwickelte Bienen zu erreichen und die daraus resultierenden Arbeiterinnen zu untersuchen. Sowohl die Ergebnisse der Verhaltensuntersuchungen von Stockbienen wie auch der Vergleich von Lebensaktivität und –spanne zeigen dabei signifikante Unterschiede zwischen den bei unterschiedlichen Temperaturen aufgezogenen Arbeiterinnen in deren analysiertem Verhalten.
In their natural environment animals face complex and highly dynamic olfactory input. This requires fast and reliable processing of olfactory information, in vertebrates as well as invertebrates. Parallel processing has been shown to improve processing speed and power in other sensory systems like auditory or visual. In the olfactory system less is known about olfactory coding in general and parallel processing in particular. With its elaborated olfactory system and due to their specialized neuroanatomy, honeybees are well-suited model organism to study parallel olfactory processing. The honeybee possesses a unique neuronal architecture - a dual olfactory pathway. Two mirror-imaged output projection neuron (PN) pathways connect the first olfactory processing stage, the antennal lobe (analog to the vertebrates olfactory bulb, OB), with the second, the mushroom body (MB) known to be involved in orientation and learning and memory, and the lateral horn (LH). The medial antennal lobe-protocerebral tract (m-APT) first innervates the MB and thereafter the LH, while the other, the lateral-APT (l-APT) projects in opposite direction. The neuroanatomy and evolution of these pathways has been analyzed, yet little is known about its physiology. To analyze the function of the dual olfactory pathway a new established recording method was designed and is described in the first chapter of this thesis (multi-unit-recordings). This is now the first time where odor response from several PNs of both tracts is recorded simultaneously and with high temporal precision. In the second chapter the PN odor responses are analyzed. The major findings are: both tracts responded to all tested odors but with differing characteristics. Since recent studies describe the input to the two tracts being rather similar, the results now indicate differential odor processing along the tracts, therefore this is a good indicator for parallel processing. PNs of the m-APT process odors in a sparse manner with delayed response latencies, but with high odor-specificity. PNs of the l-APT in contrast respond to several odor stimuli and respond in general faster. In some PN originating from both tracts, characteristics of odor-identity coding via response latencies were found. Analyzing the over-all dynamic range of the PNs both l- and m-APT PNs were tested over a large odor concentration range (10-6 to 10-2) (3. chapter). The PNs responded with linear and non-linear correlation of the response strength to the odor concentration. In most cases the l-APT is comparatively more sensitive to low odor concentrations. Response latency decreases with increasing odor concentration in both tracts. Alternative coding principles and elaboration on the hypothesis whether the dual olfactory pathway may contribute coincidental innervation to the next higher-order neurons, the Kenyon cells (KC), is subject of the 4. chapter. Cross-correlations and synchronous responses of both tracts show that in principle odors may be coded via temporal coding. Results suggest that odor processing is enhanced if both tracts contribute to olfactory coding together. In another project the distribution of the inhibitory neurotransmitter GABA (gamma-aminobutyric acid) was measured in the bee’s MB during adult maturation (5. chapter). GABAergic inhibition is of high importance in odor coding. An almost threefold decrease in the total amount of GABAergic innervation was found during adult maturation in the l- and m-APT target region, in particular at the change in division of labor during the transition from a young nurse bee to an older forager bee. The results fit well into the current understanding of brain development in the honeybee and other social insects during adult maturation, which was described as presynaptic pruning and KC dendritic outgrowth. Combining anatomical and functional properties of the bee’s dual olfactory pathway suggests that both rate and temporal coding are implemented along two parallel streams. Comparison with recent work on analog output pathways of the vertebrate’s OB indicates that parallel processing of olfactory information may be a common principle across distant taxa.
Honigbienen (Apis mellifera carnica) regulieren die Temperatur ihrer Brut in einem sehr engen Temperaturfenster, da vor allem die gedeckelte Brut sehr temperaturempfindlich reagiert (Groh et al. 2004). Die Thermoregulation ist nicht – wie lange angenommen – Beiprodukt von alltäglichen Arbeiten der Bienen im Brutbereich, sondern eine aktive und Energie- und Zeitaufwändige eigene Tätigkeit. Arbeiterinnen ziehen sich mit ihren Beinen an die Brutoberfläche, drücken ihren warmen Thorax auf die Brutdeckel und verharren so für einige Minuten um mit der eigenen Körperwärme die Brut zu temperieren (Bujok et al. 2002). Wie erwartet korrelierte die Thoraxtemperatur einer Arbeiterin mit der Frequenz der abdominalen Atembewegungen, bei sehr hohen Thoraxtemperaturen (über 40°C) erreichten die Bienen Atemfrequenzen von über 8Hz. Eine weitere Methode die Brut effektiv zu wärmen übten Bienen aus, die leere Zellen im gedeckelten Brutbereich besuchen (Kleinhenz et al. 2003). Arbeiterinnen gingen dabei bevorzugt in Zellen, die von möglichst vielen gedeckelten Zellen umgeben waren. Sowohl die Dauer der Zellbesuche, als auch die mittlere Thoraxtemperatur bei Ein- und Austritt der Zelle korrelierten mit der Anzahl der benachbarten Brutzellen – je mehr Brutzellen eine leere Zelle in ihrer direkten Nachbarschaft hatte umso länger dauerte der Besuch einer Biene und umso höher ist die Ein- bzw. Austrittstemperatur der Biene. Mindestes 48 Stunden alte Bienen unterschieden sich signifikant in ihrem Wärmeverhalten von jüngeren Bienen. Tote gedeckelte Brut wurde in manchen Fällen über viele Tage (durchgehend bis 10 Tage) gewärmt, sie unterschied sich in ihrer Temperatur nicht von unbehandelter gedeckelter Brut. In weiteren Versuchen lag die Bruttemperatur von toter Brut zwar unter der eines Kontrollbereiches, die Temperatur lag aber weiterhin im optimalen Bereich von 33,5 bis 35°C (Groh et al. 2004). In diesen Versuchen wurde die tote Brut vor dem Einsetzen in den Beobachtungsstock wieder auf 35°C erwärmt. Wachskegel in gedeckelten Zellen wurden erkannt und ausgeräumt. Aktive Signale, die von der Brut ausgehen scheinen also nicht notwendig für die effektive Bruttemperaturregulierung zu sein. Untersuchungen mittels Laser-Doppler-Vibrometrie zeigten auch keine Hinweise auf eine mechanische Kommunikation zwischen den Puppen und den Arbeiterinnen. Das Brutwärmen scheint eine Aktion zu sein, die von den Bienen nur in Gemeinschaft sinnvoll durchgeführt werden kann. In einigen Fällen kam es während der Puppenphase zu unerklärlichen Abfällen in der Bruttemperatur, die nur durch einen positiven Rückkopplungseffekt seitens der Arbeiterinnen erklärt werden kann. Beim Brutwärmen spielen die Antennen der Arbeiterinnen wahrscheinlich eine wichtige Rolle. Während sich die Bienen beim aktiven Brutwärmen den Brutdeckel annähern sind die Antennenspitzen immer auf die Brutdeckel gerichtet. Fehlen den Arbeiterinnen die Antennen, dann ist die Thermoregulation eingeschränkt oder unzureichend. Die Bruttemperatur korreliert mit der Anzahl der abgetrennten Antennensegmente, je mehr Antennensegmente fehlen, desto weniger gut wird die Temperatur im Brutbereich hoch und konstant gehalten. Zusätzlich scheint es eine Lateralität in der Antennenfunktion zu geben, wurde die rechte Antenne gekürzt wärmten die Bienen die Brut signifikant schlechter, als beim Kürzen der linken Antenne. Durch das Kürzen der Antennen änderte sich auch das Verhalten der Tiere: Kontrollbienen verharrten ruhig im Brutbereich, während Bienen mit gekürzten Antennen teilweise ähnlich warm waren, aber nicht mehr das oben beschriebene aktive Brutwärmeverhalten zeigten.
In the eusocial insect honeybee (Apis mellifera), many sterile worker bees live together with a reproductive queen in a colony. All tasks of the colony are performed by the workers, undergoing age-dependent division of labor. Beginning as hive bees, they take on tasks inside the hive such as cleaning or the producing of larval food, later developing into foragers. With that, the perception of sweetness plays a crucial role for all honeybees whether they are sitting on the honey stores in the hive or foraging for food. Their ability to sense sweetness is undoubtedly necessary to develop and evaluate food sources. Many of the behavioral decisions in honeybees are based on sugar perception, either on an individual level for ingestion, or for social behavior such as the impulse to collect or process nectar. In this context, honeybees show a complex spectrum of abilities to perceive sweetness on many levels. They are able to perceive at least seven types of sugars and decide to collect them for the colony. Further, they seem to distinguish between these sugars or at least show clear preferences when collecting them. Additionally, the perception of sugar is not rigid in honeybees. For instance, their responsiveness towards sugar changes during the transition from in-hive bees (e.g. nurses) to foraging and is linked to the division of labor. Other direct or immediate factors changing responsiveness to sugars are stress, starvation or underlying factors, such as genotype.
Interestingly, the complexity in their sugar perception is in stark contrast to the fact that honeybees seem to have only three predicted sugar receptors.
In this work, we were able to characterize the three known sugar receptors (AmGr1, AmGr2 and AmGr3) of the honeybee fully and comprehensively in oocytes (Manuscript II, Chapter 3 and Manuscript III, Chapter 4). We could show that AmGr1 is a broad sugar receptor reacting to sucrose, glucose, maltose, melezitose and trehalose (which is the honeybees’ main blood sugar), but not fructose. AmGr2 acts as its co-receptor altering AmGr1’s specificity, AmGr3 is a specific fructose receptor and we proved the heterodimerization of all receptors. With my studies, I was able to reproduce and compare the ligand specificity of the sugar receptors in vivo by generating receptor mutants with CRISPR/Cas9. With this thesis, I was able to define AmGr1 and AmGr3 as the honeybees’ basis receptors already capable to detect all sugars of its known taste spectrum.
In the expression analysis of my doctoral thesis (Manuscript I, Chapter 2) I demonstrated that both basis receptors are expressed in the antennae and the brain of nurse bees and foragers. This thesis assumes that AmGr3 (like the Drosophila homologue) functions as a sensor for fructose, which might be the satiety signal, while AmGr1 can sense trehalose as the main blood sugar in the brain. Both receptors show a reduced expression in the brain of foragers when compared with nurse bees. These results may reflect the higher concentrated diet of nurse bees in the hive. The higher number of receptors in the brain may allow nurse bees to perceive hunger earlier and to consume the food their sitting on. Forager bees have to be more persistent to hunger, when they are foraging, and food is not so accessible. The findings of reduced expression of the fructose receptor AmGr3 in the antennae of nurse bees are congruent with my other result that nurse bees are also less responsive to fructose at the antennae when compared to foragers (Manuscript I, Chapter 2). This is possible, since nurse bees sit more likely on ripe honey which contains not only higher levels of sugars but also monosaccharides (such as fructose), while foragers have to evaluate less-concentrated nectar.
My investigations of the expression of AmGr1 in the antennae of honeybees found no differences between nurse bees and foragers, although foragers are more responsive to the respective sugar sucrose (Manuscript I, Chapter 2). Considering my finding that AmGr2 is the co-receptor of AmGr1, it can be assumed that AmGr1 and the mediated sucrose taste might not be directly controlled by its expression, but indirectly by its co-receptor. My thesis therefore clearly shows that sugar perception is associated with division of labor in honeybees and appears to be directly or indirectly regulated via expression.
The comparison with a characterization study using other bee breeds and thus an alternative protein sequence of AmGr1 shows that co-expression of different AmGr1 versions with AmGr2 alters the sugar response differently. Therefore, this thesis provides first important indications that alternative splicing could also represent an important regulatory mechanism for sugar perception in honeybees.
Further, I found out that the bitter compound quinine lowers the reward quality in learning experiments for honeybees (Manuscript IV, Chapter 5). So far, no bitter receptor has been found in the genome of honeybees and this thesis strongly assumes that bitter substances such as quinine inhibit sugar receptors in honeybees. With this finding, my work includes other molecules as possible regulatory mechanism in the honeybee sugar perception as well. We showed that the inhibitory effect is lower for fructose compared to sucrose. Considering that sugar signals might be processed as differently attractive in honeybees, this thesis concludes that the sugar receptor inhibition via quinine in honeybees might depend on the receptor (or its co-receptor), is concentration-dependent and based on the salience or attractiveness and concentration of the sugar present.
With my thesis, I was able to expand the knowledge on honeybee’s sugar perception and formulate a complex, comprehensive overview. Thereby, I demonstrated the multidimensional mechanism that regulates the sugar receptors and thus the sugar perception of honeybees. With this work, I defined AmGr1 and AmGr3 as the basis of sugar perception and enlarged these components to the co-receptor AmGr2 and the possible splice variants of AmGr1. I further demonstrated how those sugar receptor components function, interact and that they are clearly involved in the division of labor in honeybees. In summary, my thesis describes the mechanisms that enable honeybees to perceive sugar in a complex way, even though they inhere a limited number of sugar receptors. My data strongly suggest that honeybees overall might not only differentiate sugars and their diet by their general sweetness (as expected with only one main sugar receptor). The found sugar receptor mechanisms and their interplay further suggest that honeybees might be able to discriminate directly between monosaccharides and disaccharides or sugar molecules and with that their diet (honey and nectar).
Um einen Beitrag zum besseren Verständnis der Rolle der Bienenwachse in der Kommunikation der Honigbienen leisten zu können, wurden Wabenwachse unterschiedlichen Alters und Kutikulawachse unterschiedlicher Kasten,Geschlechter und Berufsgruppen mit Hilfe von Gaschromatographie, Massenspektroskopie und FTIR-Spektroskopie untersucht. Die chemischen Analysen zeigten mittels Diskriminantenfunktionsanalysen hochsignifikante Unterschiede in den aliphatischen Kohlenwasserstoffen zwischen Wabenwachsen unterschiedlichen Alters und Kutikulawachsen unterschiedlicher Kasten und Geschlechter. Erstmals konnte für ein komplexes Substanzgemisch (Bienenwachs) eine lineare Abhängigkeit zwischen dem Schmelzverhalten und der chemischen Zusammensetzung der Wachse nachgewiesen werden.Mit Hilfe von Verhaltensversuchen wurde der Frage nachgegangen, ob die chemischen Unterschiede für die Bienen überhaupt relevant sind. Mit Hilfe der differentielle Konditionierung des Rüsselreflexes wurde getestet, inwieweit Bienen die verschiedenen Wachse unterscheiden können. Eine Diskriminierung der Wachse aufgrund der aliphatischen Kohlenwasserstoffe war den Honigbienen nicht möglich. Dies ergab einen neuen und interessanten Einblick in die Kommunikation der Honigbienen
The Western Honeybee (Apis mellifera) is among the most versatile species in the world. Its adaptability is rooted in thousands of the differently specialized individuals acting jointly together. Thus, bees that are able to handle a certain task or condition well can back up other individuals less capable to do so on the colony level. Vice versa, the latter individuals might perform better in other situations. This evolutionary recipe for success ensures the survival of colonies despite challenging habitat conditions. In this context, the ectoparasitic mite Varroa destructor reflects the most pronounced biotic challenge to honeybees worldwide. Without proper treatment, infested colonies rapidly dwindle and ultimately die. Nevertheless, resistance behaviours against this parasite have evolved in some populations through natural selection, enabling colonies to survive untreated. In this, different behaviours appear to be adapted to the respective habitat conditions and may complement each other. Yet, the why and how of this behavioural response to the mite remains largely unknown. My thesis focuses on the biological background of Varroa-resistance traits in honeybees and presents important findings for the comprehension of this complex host-parasite interaction. Based on this, I draw implications for both, applied bee breeding and scientific investigations in the field of Varroa-resistance. Specifically, I focus on two traits commonly found in resistant and, to a lower degree, also mite-susceptible colonies: decreased mite reproduction and the uncapping and subsequent recapping of sealed brood cells. Examining failures in the reproductive success of mites as a primary mechanism of Varroa-resistance, I was able to link them to specific bee behaviours and external factors. Since mite reproduction and the brood rearing of bees are inevitably connected, I first investigated the effects of brood interruption on the reproductive success of mites. Brood interruption decreased the reproductive success of mites both immediately and in the long term. By examining the causes of reproductive failure, I could show that this was mainly due to an increased share of infertile mites. Furthermore, I proved that interruption in brood rearing significantly increased the expression of recapping behaviour. These findings consequently showed a dynamic modulation of mite reproduction and recapping, as well as a direct effect of brood interruption on both traits. To further elucidate the plasticity in the expression of both traits, I studied mite reproduction, recapping behaviour and infestation levels over the course of three years. The resulting extensive dataset unveiled a significant seasonal variation in mite reproduction and recapping. In addition, I show that recapping decreases the reproductive success of mites by increasing delayed developing female offspring and cells lacking male offspring. By establishing a novel picture-based brood investigation method, I could furthermore show that both the removal of brood cells and recapping activity specifically target brood ages in which mite offspring would be expected. Recapping, however, did not cause infertility of mites. Considering the findings of my first study, this points towards complementary mechanisms.
This underlines the importance of increased recapping behaviour and decreased mite reproduction as resistance traits, while at the same time emphasising the challenges of reliable data acquisition. To pave the way for a practical application of these findings in breeding, we then investigated the heritability (i.e., the share of genotypic variation on the observed phenotypic variation) of the accounted traits. By elaborating comparable test protocols and compiling data from over 4,000 colonies, we could, for the first time, demonstrate that recapping of infested cells and decreased reproductive success of mites are heritable (and thus selectable) traits in managed honeybee populations.
My thesis proves the importance of recapping and decreased mite reproduction as resistance traits and therefore valuable goals for breeding efforts. In this regard, I shed light on the underlying mechanisms of both traits, and present clear evidence for their interaction and heritability.
Olfaction plays an important role in a variety of behaviors throughout the life of the European honeybee. Caste specific, environmentally induced and aging/experiencedependent differences in olfactory behavior represent a promising model to investigate mechanisms and consequences of phenotypic neuronal plasticity within the olfactory pathway of bees. This study focuses on the two different female phenotypes within the honeybee society, queens and workers. In this study, for the first time, structural plasticity in the honeybee brain was investigated at the synaptic level. Queens develop from fertilized eggs that are genetically not different from those that develop into workers. Adult queens are larger than workers, live much longer, and display different behaviors. Developmental trajectory is mainly determined by nutritional factors during the larval period. Within the subsequent post-capping period, brood incubation is precisely controlled, and pupae are incubated close to 35°C via thermoregulatory activity of adult workers. Behavioral studies suggest that lower rearing temperatures cause deficits in olfactory learning in adult bees. To unravel possible neuronal correlates for thermoregulatory and caste dependent influences on olfactory behavior, I examined structural plasticity of developing as well as mature olfactory synaptic neuropils. Brood cells were reared in incubators and pupal as well as adult brains were dissected for immunofluorescent staining. To label synaptic neuropils, I used an antibody to synapsin and fluophore-conjugated phalloidin which binds to filamentous (F-) actin. During development, neuronal F-actin is expressed in growing neurons, and in the mature nervous system, F-actin is most abundant in presynaptic terminals and dendritic spines. In the adult brains, this double labeling technique enables the quantification of distinct synaptic complexes microglomeruli [MG]) within olfactory and visual input regions of the mushroom bodies (MBs) prominent higher sensory integration centers. Analyses during larval-adult metamorphosis revealed that the ontogenetic plasticity in the female castes is reflected in the development of the brain. Distinct differences among the timing of the formation of primary and secondary olfactory neuropils were also revealed. These differences at different levels of the olfactory pathway in queens and workers correlate with differences in tasks performed by both female castes. In addition to caste specific differences, thermoregulation of sealed brood cells has important consequences on the synaptic organization within the MB calyces of adult workers and queens. Even small differences in rearing temperatures affected the number of MG in the olfactory calyx lip regions. In queens, the highest number of MG in the olfactory lip developed at 1°C below the temperature where the maximum of MG is found in workers (33.5 vs. 34.5°C). Apart from this developmental neuronal plasticity, this study exhibits a striking age-related plasticity of MG throughout the extended life span of queens. Interestingly, MG numbers in the olfactory lip increased with age, but decreased within the adjacent visual collar of the MB calyx. To conclude, developmental and adult plasticity of the synaptic circuitry in the sensory input regions of the MB calyx may underlie caste- and age-specific adaptations and long-term plasticity in behavior.