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How do physico-chemical stimulus features, perception, and physiology relate? Given the multi-layered and parallel architecture of brains, the question specifically is where physiological activity patterns correspond to stimulus features and/or perception. Perceived distances between six odour pairs are defined behaviourally from four independent odour recognition tasks. We find that, in register with the physico-chemical distances of these odours, perceived distances for 3octanol and n-amylacetate are consistently smallest in all four tasks, while the other five odour pairs are about equally distinct. Optical imaging in the antennal lobe, using a calcium sensor transgenically expressed in only first-order sensory or only second-order olfactory projection neurons, reveals that 3-octanol and n-amylacetate are distinctly represented in sensory neurons, but appear merged in projection neurons. These results may suggest that within-antennal lobe processing funnels sensory signals into behaviourally meaningful categories, in register with the physico-chemical relatedness of the odours.
Mushroom bodies (MBs) are multisensory integration centers in the insect brain involved in learning and memory formation. In the honeybee, the main sensory input region (calyx) of MBs is comparatively large and receives input from mainly olfactory and visual senses, but also from gustatory/tactile modalities. Behavioral plasticity following differential brood care, changes in sensory exposure or the formation of associative long-term memory (LTM) was shown to be associated with structural plasticity in synaptic microcircuits (microglomeruli) within olfactory and visual compartments of the MB calyx. In the same line, physiological studies have demonstrated that MB-calyx microcircuits change response properties after associative learning. The aim of this review is to provide an update and synthesis of recent research on the plasticity of microcircuits in the MB calyx of the honeybee, specifically looking at the synaptic connectivity between sensory projection neurons (PNs) and MB intrinsic neurons (Kenyon cells). We focus on the honeybee as a favorable experimental insect for studying neuronal mechanisms underlying complex social behavior, but also compare it with other insect species for certain aspects. This review concludes by highlighting open questions and promising routes for future research aimed at understanding the causal relationships between neuronal and behavioral plasticity in this charismatic social insect.
Die Pilzkörper von Drosophila melanogaster stellen eine für die Lebensfähigkeit dieses Organismus entbehrliche Gehirnstruktur dar. Die Entwicklungsprozesse, die der Bildung dieser zentralnervösen Struktur zugrunde liegen, sind gut erforscht. Die neuronalen Stammzellen, die für die Bildung dieser Gehirnstruktur verantwortlich sind, sind identifiziert und experimentell gut zugänglich. Daher bietet sich die Drosophila-Pilzkörperentwicklung als neurogenetisches Modellsystem an, grundlegende Mechanismen der Gehirnentwicklung durch die Untersuchung von Pilzkörperstrukturmutanten zu erforschen. In dieser Arbeit wurde mushroom bodies undersized P1 (mbuP1) als eine durch Transposon- Insertion in den Casein-Kinase-2ß-Genlokus verursachte, hypomorphe Mutation identifiziert, die zu einer starken Verringerung der Anzahl der die Pilzkörper bildenden intrinsischen Neurone führt. Eine Reversion des mbuP1-Pilzkörperphänotyps konnte unter anderem durch die Expression von Casein-Kinase-2ß-(CK2ß)-Transgenen im mbuP1-Hintergrund erzielt werden. Durch Rekombination wurde ein fertiler mbuP1-Stamm etabliert, der nun die Untersuchung der zellulären mbuP1-Defekte ermöglicht. Eine partielle, letale Deletion der CK2ß-Transkriptionseinheit wurde erzeugt. Die Letalität dieser Deletion konnte sowohl durch ein genomisches CK2ß-Transgen als auch durch die ubiquitäre Expression einer CK2ß-cDNA gerettet, und hierdurch die essentielle Funktion der CK2ß-Transkriptionseinheit in Drosophila belegt werden. Durch die ubiquitäre Expression von in vitro-mutagenisierten CK2ß-cDNAs im CK2ß-Letalhintergrund wurde gezeigt, daß die Phosphorylierung der regulatorischen CK2ß-Untereinheit durch die katalytisch aktive CK2α-Untereinheit kein lebensnotwendiger Prozess ist. Gleichartige Experimente wurden zur Untersuchung der funktionellen Bedeutung eines CK2ß-Zinkfingermotivs und eines CK2ß-Destruction-Box-Motivs durchgeführt. Diese legen nahe, daß das Zinkfingermotiv im Gegensatz zum Destruction-Box-Motiv für die in vivo-Funktion der CK2ß-Untereinheit essentiell ist. Expression der in vitro-mutagenisierten CK2ß-cDNAs im mbuP1-Hintergrund werden die funktionelle Bedeutung der ausgetauschten Aminosäuren für die Pilzkörperentwicklung zeigen. Eine letale genetische Interaktion von mbuP1 mit einer Mutation des Drosophila-MAP-Kinase-Gens rolled (rlSem) und eine lebensfähige Interaktion von mbuP1 mit einer Mutation des Drosophila-S6-Kinase-p90rsk-Gens ignorant (ignP1), bei der Flügel- und Augenent-wicklungsdefekte zu beobachten sind, wurden gefunden. Es wurde zudem gezeigt, daß rlSem als Suppressor des Pilzkörperphänotyps eines schwächeren mbu-Allels wirkt. Hierdurch konnte eine Beteiligung der Casein-Kinase-2 an MAP-Kinase-Signalübertragungswegen wahrscheinlich gemacht werden.
Social insects control brood development by using different thermoregulatory strategies. Camponotus mus ants expose their brood to daily temperature fluctuations by translocating them inside the nest following a circadian rhythm of thermal preferences. At the middle of the photophase brood is moved to locations at 30.8°C; 8 h later, during the night, the brood is transferred back to locations at 27.5°C. We investigated whether daily thermal fluctuations experienced by developing pupae affect the neuroarchitecture in the adult brain, in particular in sensory input regions of the mushroom bodies (MB calyces). The complexity of synaptic microcircuits was estimated by quantifying MB-calyx volumes together with densities of presynaptic boutons of microglomeruli (MG) in the olfactory lip and visual collar regions. We compared young adult workers that were reared either under controlled daily thermal fluctuations of different amplitudes, or at different constant temperatures. Thermal regimes significantly affected the large (non-dense) olfactory lip region of the adult MB calyx, while changes in the dense lip and the visual collar were less evident. Thermal fluctuations mimicking the amplitudes of natural temperature fluctuations via circadian rhythmic translocation of pupae by nurses (amplitude 3.3°C) lead to higher numbers of MG in the MB calyces compared to those in pupae reared at smaller or larger thermal amplitudes (0.0, 1.5, 9.6°C), or at constant temperatures (25.4, 35.0°C). We conclude that rhythmic control of brood temperature by nursing ants optimizes brain development by increasing MG densities and numbers in specific brain areas. Resulting differences in synaptic microcircuits are expected to affect sensory processing and learning abilities in adult ants, and may also promote interindividual behavioral variability within colonies.
This thesis consists of three major chapters, each of which has been separately published or under the process for publication. The first chapter is about anatomical characterization of the mushroom body of adult Drosophila melanogaster. The mushroom body is the center for olfactory learning and many other functions in the insect brains. The functions of the mushroom body have been studied by utilizing the GAL4/UAS gene expression system. The present study characterized the expression patterns of the commonly used GAL4 drivers for the mushroom body intrinsic neurons, Kenyon cells. Thereby, we revealed the numerical composition of the different types of Kenyon cells and found one subtype of the Kenyon cells that have not been described. The second and third chapters together demonstrate that the multiple types of dopaminergic neurons mediate the aversive reinforcement signals to the mushroom body. They induce the parallel memory traces that constitute the different temporal domains of the aversive odor memory. In prior to these chapters, “General introduction and discussion” section reviews and discuss about the current understanding of neuronal circuit for olfactory learning in Drosophila.
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.
To rapidly process biologically relevant stimuli, sensory systems have developed a broad variety of coding mechanisms like parallel processing and coincidence detection. Parallel processing (e.g., in the visual system), increases both computational capacity and processing speed by simultaneously coding different aspects of the same stimulus. Coincidence detection is an efficient way to integrate information from different sources. Coincidence has been shown to promote associative learning and memory or stimulus feature detection (e.g., in auditory delay lines). Within the dual olfactory pathway of the honeybee both of these mechanisms might be implemented by uniglomerular projection neurons (PNs) that transfer information from the primary olfactory centers, the antennal lobe (AL), to a multimodal integration center, the mushroom body (MB). PNs from anatomically distinct tracts respond to the same stimulus space, but have different physiological properties, characteristics that are prerequisites for parallel processing of different stimulus aspects. However, the PN pathways also display mirror-imaged like anatomical trajectories that resemble neuronal coincidence detectors as known from auditory delay lines. To investigate temporal processing of olfactory information, we recorded PN odor responses simultaneously from both tracts and measured coincident activity of PNs within and between tracts. Our results show that coincidence levels are different within each of the two tracts. Coincidence also occurs between tracts, but to a minor extent compared to coincidence within tracts. Taken together our findings support the relevance of spike timing in coding of olfactory information (temporal code).
Long-term behavioral changes related to learning and experience have been shown to be associated with structural remodeling in the brain. Leaf-cutting ants learn to avoid previously preferred plants after they have proved harmful for their symbiotic fungus, a process that involves long-term olfactory memory. We studied the dynamics of brain microarchitectural changes after long-term olfactory memory formation following avoidance learning in Acromyrmex ambiguus. After performing experiments to control for possible neuronal changes related to age and body size, we quantified synaptic complexes (microglomeruli, MG) in olfactory regions of the mushroom bodies (MB) at different times after learning. Long-term avoidance memory formation was associated with a transient change in MG densities. Two days after learning, MG density was higher than before learning. At days 4 and 15 after learning when ants still showed plant avoidance MG densities had decreased to the initial state. The structural reorganization of MG triggered by long-term avoidance memory formation clearly differed from changes promoted by pure exposure to and collection of novel plants with distinct odors. Sensory exposure by the simultaneous collection of several, instead of one, non-harmful plant species resulted in a decrease in MG densities in the olfactory lip. We hypothesize that while sensory exposure leads to MG pruning in the MB olfactory lip, the formation of long-term avoidance memory involves an initial growth of new MG followed by subsequent pruning.
Long-term behavioral changes related to learning and experience have been shown to be associated with structural remodeling in the brain. Leaf-cutting ants learn to avoid previously preferred plants after they have proved harmful for their symbiotic fungus, a process that involves long-term olfactory memory. We studied the dynamics of brain microarchitectural changes after long-term olfactory memory formation following avoidance learning in Acromyrmex ambiguus. After performing experiments to control for possible neuronal changes related to age and body size, we quantified synaptic complexes (microglomeruli, MG) in olfactory regions of the mushroom bodies (MBs) at different times after learning. Long-term avoidance memory formation was associated with a transient change in MG densities. Two days after learning, MG density was higher than before learning. At days 4 and 15 after learning—when ants still showed plant avoidance—MG densities had decreased to the initial state. The structural reorganization of MG triggered by long-term avoidance memory formation clearly differed from changes promoted by pure exposure to and collection of novel plants with distinct odors. Sensory exposure by the simultaneous collection of several, instead of one, non-harmful plant species resulted in a decrease in MG densities in the olfactory lip. We hypothesize that while sensory exposure leads to MG pruning in the MB olfactory lip, the formation of long-term avoidance memory involves an initial growth of new MG followed by subsequent pruning.
Olfactory circuits change structurally and physiologically during development and adult life. This allows insects to respond to olfactory cues in an appropriate and adaptive way according to their physiological and behavioral state, and to adapt to their specific abiotic and biotic natural environment. We highlight here findings on olfactory plasticity and modulation in various model and non-model insects with an emphasis on moths and social Hymenoptera. Different categories of plasticity occur in the olfactory systems of insects. One type relates to the reproductive or feeding state, as well as to adult age. Another type of plasticity is context-dependent and includes influences of the immediate sensory and abiotic environment, but also environmental conditions during postembryonic development, periods of adult behavioral maturation, and short- and long-term sensory experience. Finally, plasticity in olfactory circuits is linked to associative learning and memory formation. The vast majority of the available literature summarized here deals with plasticity in primary and secondary olfactory brain centers, but also peripheral modulation is treated. The described molecular, physiological, and structural neuronal changes occur under the influence of neuromodulators such as biogenic amines, neuropeptides, and hormones, but the mechanisms through which they act are only beginning to be analyzed.