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Post-embryonic Development of the Circadian Clock Seems to Correlate With Social Life Style in Bees
(2020)
Social life style can influence many aspects of an animal’s daily life, but it has not yet been clarified, whether development of the circadian clock in social and solitary living bees differs. In a comparative study, with the social honey bee, Apis mellifera, and the solitary mason bee, Osmia bicornis, we now found indications for a differentially timed clock development in social and solitary bees. Newly emerged solitary bees showed rhythmic locomotion right away and the number of neurons in the brain that produce the clock component pigment-dispersing factor (PDF) did not change during aging of the adult solitary bee. Honey bees on the other hand, showed no circadian locomotion directly after emergence and the neuronal clock network continued to grow after emergence. Social bees appear to emerge at an early developmental stage at which the circadian clock is still immature, but bees are already able to fulfill in-hive tasks.
Summary
Bees, like many other organisms, evolved an endogenous circadian clock, which enables them to foresee daily environmental changes and exactly time foraging flights to periods of floral resource availability. The social lifestyle of a honey bee colony has been shown to influence circadian behavior in nurse bees, which do not exhibit rhythmic behavior when they are nursing. On the other hand, forager bees display strong circadian rhythms. Solitary bees, like the mason bee, do not nurse their offspring and do not live in hive communities, but face the same daily environmental changes as honey bees. Besides their lifestyle mason and honey bees differ in their development and life history, because mason bees overwinter after eclosion as adults in their cocoons until they emerge in spring. Honey bees do not undergo diapause and have a relatively short development of a few weeks until they emerge. In my thesis, I present a comparison of the circadian clock of social honey bees (Apis mellifera) and solitary mason bees (Osmia bicornis and Osmia cornuta) on the neuroanatomical level and behavioral output level.
I firstly characterized in detail the localization of the circadian clock in the bee brain via the expression pattern of two clock components, namely the clock protein PERIOD (PER) and the neuropeptide Pigment Dispersing Factor (PDF), in the brain of honey bee and mason bee. PER is localized in lateral neuron clusters (which we called lateral neurons 1 and 2: LN1 and LN2) and dorsal neuron clusters (we called dorsal lateral neurons and dorsal neurons: DLN, DN), many glia cells and photoreceptor cells. This expression pattern is similar to the one in other insect species and indicates a common ground plan of clock cells among insects. In the LN2 neuron cluster with cell bodies located in the lateral brain, PER is co-expressed with PDF. These cells build a complex arborization network throughout the brain and provide the perfect structure to convey time information to brain centers, where complex behavior, e.g. sun-compass orientation and time memory, is controlled. The PDF arborizations centralize in a dense network (we named it anterio-lobular PDF hub: ALO) which is located in front of the lobula. In other insects, this fiber center is associated with the medulla (accessory medulla: AME). Few PDF cells build the ALO already in very early larval development and the cell number and complexity of the network grows throughout honey bee development. Thereby, dorsal regions are innervated first by PDF fibers and, in late larval development, the fibers grow laterally to the optic lobe and central brain. The overall expression pattern of PER and PDF are similar in adult social and solitary bees, but I found a few differences in the PDF network density in the posterior protocerebrum and the lamina, which may be associated with evolution of sociality in bees.
Secondly, I monitored activity rhythms, for which I developed and established a device to monitor locomotor activity rhythms of individual honey bees with contact to a mini colony in the laboratory. This revealed new aspects of social synchronization and survival of young bees with indirect social contact to the mini colony (no trophalaxis was possible). For mason bees, I established a method to monitor emergence and locomotor activity rhythms and I could show that circadian emergence rhythms are entrainable by daily temperature cycles. Furthermore, I present the first locomotor activity rhythms of solitary bees, which show strong circadian rhythms in their behavior right after emergence. Honey bees needed several days to develop circadian locomotor rhythms in my experiments. I hypothesized that honey bees do not emerge with a fully matured circadian system in the hive, while solitary bees, without the protection of a colony, would need a fully matured circadian clock right away after emergence. Several indices in published work and preliminary studies support my hypothesis and future studies on PDF expression in different developmental stages in solitary bees may provide hard evidence.
Age‐dependent transcriptional and epigenomic responses to light exposure in the honey bee brain
(2016)
Light is a powerful environmental stimulus of special importance in social honey bees that undergo a behavioral transition from in-hive to outdoor foraging duties. Our previous work has shown that light exposure induces structural neuronal plasticity in the mushroom bodies (MBs), a brain center implicated in processing inputs from sensory modalities. Here, we extended these analyses to the molecular level to unravel light-induced transcriptomic and epigenomic changes in the honey bee brain. We have compared gene expression in brain compartments of 1- and 7-day-old light-exposed honey bees with age-matched dark-kept individuals. We have found a number of differentially expressed genes (DEGs), both novel and conserved, including several genes with reported roles in neuronal plasticity. Most of the DEGs show age-related changes in the amplitude of light-induced expression and are likely to be both developmentally and environmentally regulated. Some of the DEGs are either known to be methylated or are implicated in epigenetic processes suggesting that responses to light exposure are at least partly regulated at the epigenome level. Consistent with this idea light alters the DNA methylation pattern of bgm, one of the DEGs affected by light exposure, and the expression of microRNA miR-932. This confirms the usefulness of our approach to identify candidate genes for neuronal plasticity and provides evidence for the role of epigenetic processes in driving the molecular responses to visual stimulation.
The honeybee is a well studied and important organism in neuroethology. The possibility to train them with a classical conditioning paradigm and their miniature brain provide a perfect requisite to investigate the neuronal principles of learning and memory. Honeybees use visual and olfactory cues to detect flowers during their foraging trips. Hence, the reward association of a nectar source is a multi-modal construct, which has at least two major components - olfactory and visual cues. It is still an open question, how both sensory components are converged in the mushroom body, which represent the multi-modal integration centre of the honeybee brain. The main goal of this study, is to investigate the processing of multiple modalities and how a reward association is formed. This includes, how and wether both sensory modalities interfere during learning. Thus, in this study stimulation with UV, blue and green light was used to evoke distinct photoreceptor activities in the compound eye. Furthermore, three different odours (Geraniol, Citronellol and Farnesol) were used. These stimuli were tested in three different experimental series. The first experiment involved classical differential conditioning of the single modalities - odour and colour. Honeybees showed high learning performances in differentiating olfactory stimuli and also reliable responses for visual conditioning. Furthermore, a temporal discrepancy in the stimulus length for best learning in the olfatcoty and visual cues was found. In the second series, it was tested how multi-modal compounds are perceived. This includes, unique cues (configural processing) or the sum of the single components of a compound (elemen- tal processing). This was tested by combining single odour components with monochromatic light in a positive (PP) and negative patterning (NP) experiment. During PP, the olfactory- visual compound was rewarded, whereas the single components were unrewarded. In contrast, during NP the single components were reinforced, but the compound was not. In addition, the ability to distinguish between two different light stimuli presented as a part of an olfactory-visual compound with the same odour component during acquisition was tested. In a memory test, the light stimuli were presented again as a compound and in addition as the single components. The results revealed that bees used elemental processing with compounds containing green and blue light. In contrast, when UV light was presented the bees used configural processing. Finally, a third experiment was conducted at the neuronal level. Multi-unit recordings were established to provide a suitable method to analyse extrinsic neurons at the mushroom body output region, the so called ventral lobe of the pedunculus. Here, three different odours (Geran- iol, Farnesol and Citronellol), two colours (green and blue) and two combined stimuli (colour + odour) were chosen as stimuli, to search for possible variations in processing stimuli with different modalities. Two units could be detected that responded mainly to visual stimuli.
Optogenetic manipulation of cells or living organisms became widely used in neuroscience following the introduction of the light-gated ion channel channelrhodopsin-2 (ChR2). ChR2 is a non-selective cation channel, ideally suited to depolarize and evoke action potentials in neurons. However, its calcium (Ca2\(^{2+}\)) permeability and single channel conductance are low and for some applications longer-lasting increases in intracellular Ca\(^{2+}\) might be desirable. Moreover, there is need for an efficient light-gated potassium (K\(^{+}\)) channel that can rapidly inhibit spiking in targeted neurons. Considering the importance of Ca\(^{2+}\) and K\(^{+}\) in cell physiology, light-activated Ca\(^{2+}\)-permeant and K\(^{+}\)-specific channels would be welcome additions to the optogenetic toolbox. Here we describe the engineering of novel light-gated Ca\(^{2+}\)-permeant and K\(^{+}\)-specific channels by fusing a bacterial photoactivated adenylyl cyclase to cyclic nucleotide-gated channels with high permeability for Ca\(^{2+}\) or for K\(^{+}\), respectively. Optimized fusion constructs showed strong light-gated conductance in Xenopus laevis oocytes and in rat hippocampal neurons. These constructs could also be used to control the motility of Drosophila melanogaster larvae, when expressed in motoneurons. Illumination led to body contraction when motoneurons expressed the light-sensitive Ca\(^{2+}\)-permeant channel, and to body extension when expressing the light-sensitive K\(^{+}\) channel, both effectively and reversibly paralyzing the larvae. Further optimization of these constructs will be required for application in adult flies since both constructs led to eclosion failure when expressed in motoneurons.
Endogenous molecular circadian clocks drive daily rhythmic changes at the cellular, physiological, and behavioral level for adaptation to and anticipation of environmental signals. The core molecular system consists of autoregulatory feedback loops, where clock proteins inhibit their own transcription. A complex and not fully understood interplay of regulatory proteins influences activity, localization and stability of clock proteins to set the pace of the clock. This study focuses on the molecular function of Ribosomal S6 Kinase (RSK) in the Drosophila melanogaster circadian clock. Mutations in the human rsk2 gene cause Coffin–Lowry syndrome, which is associated with severe mental disabilities. Knock-out studies with Drosophila ortholog rsk uncovered functions in synaptic processes, axonal transport and adult behavior including associative learning and circadian activity. However, the molecular targets of RSK remain elusive. Our experiments provide evidence that RSK acts in the key pace maker neurons as a negative regulator of Shaggy (SGG) kinase activity, which in turn determines timely nuclear entry of the clock proteins Period and Timeless to close the negative feedback loop. Phosphorylation of serine 9 in SGG is mediated by the C-terminal kinase domain of RSK, which is in agreement with previous genetic studies of RSK in the circadian clock but argues against the prevailing view that only the N-terminal kinase domain of RSK proteins carries the effector function. Our data provide a mechanistic explanation how RSK influences the molecular clock and imply SGG S9 phosphorylation by RSK and other kinases as a convergence point for diverse cellular and external stimuli.
In dieser Arbeit sollte die Funktion von RSK in Motoneuronen von Drosophila untersucht
werden. Mutationen im RSK2-Gen verursachen das Coffin-Lowry-Syndrom (CLS), das durch
mentale Retardierung charakterisiert ist. RSK2 ist hauptsächlich in Regionen des Gehirns
exprimiert, in denen Lernen und Gedächtnisbildung stattfinden. In Mäusen und Drosophila, die
als Modellorganismen für CLS dienen, konnten auf makroskopischer Ebene keine
Veränderungen in den Hirnstrukturen gefunden werden, dennoch wurden in verschiedenen
Verhaltensstudien Defekte im Lernen und der Gedächtnisbildung beobachtet.
Die synaptische Plastizität und die einhergehenden Veränderungen in den Eigenschaften der
Synapse sind fundamental für adaptives Verhalten. Zur Analyse der synaptischen Plastizität
eignet sich das neuromuskuläre System von Drosophila als Modell wegen des stereotypen
Innervierungsmusters und der Verwendung ionotroper Glutamatrezeptoren, deren
Untereinheiten homolog sind zu den Untereinheiten der Glutamatrezeptoren des AMPA-Typs
aus Säugern, die wesentlich für die Bildung von LTP im Hippocampus sind.
Zunächst konnte gezeigt werden, dass RSK in den Motoneuronen von Drosophila an der
präsynaptischen Seite lokalisiert ist, wodurch RSK eine Synapsen-spezifische Funktion
ausüben könnte. Morphologische Untersuchungen der Struktur der neuromuskulären Synapsen
konnten aufzeigen, dass durch den Verlust von RSK die Größe der neuromuskulären Synapse,
der Boutons sowie der Aktiven Zonen und Glutamatrezeptorfelder reduziert ist. Obwohl mehr
Boutons gebildet werden, sind weniger Aktive Zonen und Glutamatrezeptorfelder in der
neuromuskulären Synapse enthalten. RSK reguliert die synaptische Transmission, indem es die
postsynaptische Sensitivität, nicht aber die Freisetzung der Neurotransmitter an der
präsynaptischen Seite beeinflusst, obwohl in immunhistochemischen Analysen eine
postsynaptische Lokalisierung von RSK nicht nachgewiesen werden konnte. RSK ist demnach
an der Regulation der synaptischen Plastizität glutamaterger Synapsen beteiligt.
Durch immunhistochemische Untersuchungen konnte erstmals gezeigt werden, dass aktiviertes
ERK an der präsynaptischen Seite lokalisiert ist und diese synaptische Lokalisierung von RSK
reguliert wird. Darüber hinaus konnte in dieser Arbeit nachgewiesen werden, dass durch den
Verlust von RSK hyperaktiviertes ERK in den Zellkörpern der Motoneurone vorliegt. RSK
wird durch den ERK/MAPK-Signalweg aktiviert und übernimmt eine Funktion sowohl als
Effektorkinase als auch in der Negativregulation des Signalwegs. Demnach dient RSK in den
Zellkörpern der Motoneurone als Negativregulator des ERK/MAPK-Signalwegs. Darüber
hinaus könnte RSK die Verteilung von aktivem ERK in den Subkompartimenten der
Motoneurone regulieren.
Da in vorangegangenen Studien gezeigt werden konnte, dass ERK an der Regulation der
synaptischen Plastizität beteiligt ist, indem es die Insertion der AMPA-Rezeptoren zur Bildung
der LTP reguliert, sollte in dieser Arbeit aufgeklärt werden, ob der Einfluss von RSK auf die
synaptische Plastizität durch seine Funktion als Negativregulator von ERK zustande kommt.
Untersuchungen der genetischen Interaktion von rsk und rolled, dem Homolog von ERK in
Drosophila, zeigten, dass die durch den Verlust von RSK beobachtete reduzierte Gesamtzahl
der Aktiven Zonen und Glutamatrezeptorfelder der neuromuskulären Synapse auf die Funktion
von RSK als Negativregulator von ERK zurückzuführen ist. Die Größe der neuromuskulären
Synapse sowie die Größe der Aktiven Zonen und Glutamatrezeptorfelder beeinflusst RSK
allerdings durch seine Funktion als Effektorkinase des ERK/MAPK-Signalwegs.
Studien des axonalen Transports von Mitochondrien zeigten, dass dieser in vielen
neuropathologischen Erkrankungen beeinträchtigt ist. Die durchgeführten Untersuchungen des
axonalen Transports in Motoneuronen konnten eine neue Funktion von RSK in der Regulation
des axonalen Transports aufdecken. In den Axonen der Motoneurone von RSK-Nullmutanten
wurden BRP- und CSP-Agglomerate nachgewiesen. RSK könnte an der Regulation des
axonalen Transports von präsynaptischem Material beteiligt sein. Durch den Verlust von RSK
wurden weniger Mitochondrien in anterograder Richtung entlang dem Axon transportiert, dafür verweilten mehr Mitochondrien in stationären Phasen. Diese Ergebnisse zeigen, dass
auch der anterograde Transport von Mitochondrien durch den Verlust von RSK beeinträchtigt
ist.
Die NO-sensitive Guanylyl-Cyclase (NO-GC) ist ein zentrales Enzym der NO/cGMP-Signalkaskade, das über die Aktivierung von NO zur Bildung des second messangers cGMP führt. Die NO-GC setzt sich aus zwei Untereinheiten zusammen, sodass zwei Isoformen des Enzyms gebildet werden können (α1β1 und α2β1). Da die genaue Verteilung der beiden Isoformen im Colon nicht bekannt ist, wurde diese im ersten Teil dieser Arbeit charakterisiert. Immunhistochemie und In-situ-Hybridisierung zeigten die Expression beider Isoformen sowohl in der glatten Muskelschicht als auch in der Submukosa und Lamina propria. Dabei war die α1β1-Isoform ubiquitär, die α2β1-Isoform dagegen hauptsächlich im Bereich des myenterischen Plexus vorzufinden.
In der glatten Muskelschicht des Colons ist die NO-GC in glatten Muskelzellen (SMC), interstitiellen Zellen von Cajal (ICC) sowie Fibroblasten-ähnliche Zellen (FLC) exprimiert und hauptsächlich in die Modulation der gastrointestinalen Motilität involviert. Zur spezifischen Charakterisierung der Funktion der NO-GC in den einzelnen Zelltypen wurden Knockout-Mäuse generiert, denen die NO-GC global (GCKO) oder spezifisch in SMC (SMC-GCKO), ICC (ICC-GCKO) oder beiden Zelltypen (SMC/ICC-GCKO) fehlt. Anhand dieser Mausmodelle sollten im zweiten Teil dieser Arbeit die modulatorischen Effekte der NO-GC auf die spontanen Kontraktionen des Colons bestimmt werden. Zur Charakterisierung der spontanen Kontraktionen der zirkulären Muskelschicht wurden Myographiestudien mit 2,5 mm langen Colonringen durchgeführt. Hierbei konnten drei verschiedene Kontraktionen gemessen werden: Kleine, hochfrequente Ripples, mittlere Kontraktionen und große Kontraktionen. Die detaillierte Analyse der einzelnen Kontraktionen zeigte einerseits eine NO-unabhängige Regulation der Ripples, andererseits eine NO-abhängige Modulation der mittleren und großen Kontraktionen über die NO-GC in SMC und ICC. Die NO-GC in SMC beeinflusst die Kontraktionen vermutlich vor allem über die Regulation des Muskeltonus der zirkulären Muskelschicht. Die NO-GC in ICC dagegen modifiziert die spontanen Kontraktionen möglicherweise über eine Veränderung der Schrittmacheraktivität. Allerdings führt erst ein Funktionsverlust des NO/cGMP-Signalweges in beiden Zelltypen zu einem sichtbar veränderten Kontraktionsmuster, das dem von globalen Knockout-Tieren glich. Dies weist auf eine kompensatorische Wirkung der NO-GC im jeweils anderen Zelltyp hin.
Zur Analyse der propulsiven Kontraktionen entlang des gesamten Colons wurden Videoaufnahmen der Darmbewegungen in Kontraktionsmusterkarten transformiert. Zudem wurde der Darm durchspült und die Ausflusstropfen aufgezeichnet, um die Effektivität der Kontraktionen beurteilen zu können. Hierbei zeigte sich, dass eine Beeinträchtigung des NO/cGMP-Signalweges eine verminderte Effektivität der Kontraktionen zur Folge hat und vermutlich durch eine beeinträchtige Synchronisation der Kontraktionen erklärt werden kann. In diesem Regulationsmechanismus konnte vor allem der NO-GC in SMC eine übergeordnete Rolle zugewiesen werden.
Der dritte Teil der Arbeit thematisierte den Befund, dass SMC-GCKO-Tiere ca. 5 Monate nach Tamoxifen-Behandlung Entartungen der Mukosa entwickelten. Diese Entartung war lediglich in Tamoxifen-induzierten Knockout-Tieren vorzufinden. Histologische Analysen identifizierten die Entartungen als tubulovillöses Adenom. Die Genexpressionsanalyse von Mukosafalten von SMC-GCKO- und heterozygoten Kontrolltieren zeigte eine Vielzahl von Genen, welche spezifisch bei colorectalem Karzinom differenziell exprimiert sind. Einer dieser Faktoren war der BMP-Antagonist Gremlin1. Dieser Faktor erschien von besonderem Interesse, da er in Zellen der Lamina muscularis mucosae und kryptennahen Myofibroblasten exprimiert wird. Immunhistochemische Analysen ließen vermuten, dass diese Zellen sowohl die NO-GC als auch die Cre-Rekombinase unter dem SMMHC-Promotor exprimieren. Diese Arbeit liefert demnach Hinweise darauf, dass die NO-GC einen wichtigen Regulator innerhalb der Stammzellnische bildet. Die Deletion der NO-GC führt vermutlich zu einer verstärkten Bildung bzw. Sekretion von Gremlin1, was die Homöostase der mukosalen Erneuerung stört und somit zur Entwicklung von Adenomen führt.
This study investigates the abundance and geographic distribution of the hawkmoth species (Lepidoptera: Sphingidae) of Southeast-Asia and analyses the resulting patterns of biodiversity, biogeography and macroecology. Data on the distribution of species were retrieved from published and unpublished faunal lists and museum collections (in close cooperation with the Natural History Museum, London). Over 34,500 records of the global distribution of the 380 species that occur in Southeast-Asia (including New Guinea and the Solomon Islands) were used for a GIS-supported estimate of distributional ranges, which can be accessed at http://www.sphingidae-sea.biozentrum.uni-wuerzburg.de, an Internet site that also provides pictures of the species and checklists for 114 islands of the Malesian region. The abundance of species in local assemblages was assessed from nightly collections at artificial light sources. Using a compilation of own samples as well as published and unpublished data from other sources, local abundance data on 93 sites were used for analysis, covering 159 species or 17,676 specimens.
Certain fatty acids and sphingoid bases found at mucosal surfaces are known to have antibacterial activity and are thought to play a more direct role in innate immunity against bacterial infections. Herein, we analysed the antibacterial activity of sphingolipids, including the sphingoid base sphingosine as well as short-chain C\(_{6}\) and long-chain C\(_{16}\)-ceramides and azido-functionalized ceramide analogs against pathogenic Neisseriae. Determination of the minimal inhibitory concentration (MIC) and minimal bactericidal concentration (MBC) demonstrated that short-chain ceramides and a ω-azido-functionalized C\(_{6}\)-ceramide were active against Neisseria meningitidis and N. gonorrhoeae, whereas they were inactive against Escherichia coli and Staphylococcus aureus. Kinetic assays showed that killing of N. meningitidis occurred within 2 h with ω–azido-C\(_{6}\)-ceramide at 1 X the MIC. Of note, at a bactericidal concentration, ω–azido-C\(_{6}\)-ceramide had no significant toxic effect on host cells. Moreover, lipid uptake and localization was studied by flow cytometry and confocal laser scanning microscopy (CLSM) and revealed a rapid uptake by bacteria within 5 min. CLSM and super-resolution fluorescence imaging by direct stochastic optical reconstruction microscopy demonstrated homogeneous distribution of ceramide analogs in the bacterial membrane. Taken together, these data demonstrate the potent bactericidal activity of sphingosine and synthetic short-chain ceramide analogs against pathogenic Neisseriae.