TY - JOUR A1 - Reim, Tina A1 - Thamm, Markus A1 - Rolke, Daniel A1 - Blenau, Wolfgang A1 - Scheiner, Ricarda T1 - Suitability of three common reference genes for quantitative real-time PCR in honey bees JF - Apidologie : a quality journal in bee science N2 - Honey bees are important model organisms for neurobiology, because they display a large array of behaviors. To link behavior with individual gene function, quantitative polymerase chain reaction is frequently used. Comparing gene expression of different individuals requires data normalization using adequate reference genes. These should ideally be expressed stably throughout lifetime. Unfortunately, this is frequently not the case. We studied how well three commonly used reference genes are suited for this purpose and measured gene expression in the brains of honey bees differing in age and social role. Although rpl32 is used most frequently, it only remains stable in expression between newly emerged bees, nurse-aged bees, and pollen foragers but shows a peak at the age of 12 days. The genes gapdh and ef1 alpha-f1, in contrast, are expressed stably in the brain throughout all age groups except newly emerged bees. According to stability software, gapdh was expressed most stably, followed by rpl32 and ef1 alpha-f1. KW - gene expression KW - quantitative PCR KW - reference gene KW - stability program KW - Apis mellifera Y1 - 2013 U6 - https://doi.org/10.1007/s13592-012-0184-3 SN - 0044-8435 VL - 44 IS - 3 SP - 342 EP - 350 PB - Springer CY - Paris ER - TY - JOUR A1 - Thamm, Markus A1 - Scholl, Christina A1 - Reim, Tina A1 - Gruebel, Kornelia A1 - Moeller, Karin A1 - Rossler, Wolfgang A1 - Scheiner, Ricarda T1 - Neuronal distribution of tyramine and the tyramine receptor AmTAR1 in the honeybee brain JF - The journal of comparative neurology N2 - Tyramine is an important neurotransmitter, neuromodulator, and neurohormone in insects. In honeybees, it is assumed to have functions in modulating sensory responsiveness and controlling motor behavior. Tyramine can bind to two characterized receptors in honeybees, both of which are coupled to intracellular cAMP pathways. How tyramine acts on neuronal, cellular and circuit levels is unclear. We investigated the spatial brain expression of the tyramine receptor AmTAR1 using a specific antibody. This antibody detects a membrane protein of the expected molecular weight in western blot analysis. In honeybee brains, it labels different structures which process sensory information. Labeling along the antennal nerve, in projections of the dorsal lobe and in the gnathal ganglion suggest that tyramine receptors are involved in modulating gustatory and tactile perception. Furthermore, the ellipsoid body of the central complex and giant synapses in the lateral complex show AmTAR1-like immunoreactivity (AmTAR1-IR), suggesting a role of this receptor in modulating sky-compass information and/or higher sensor-motor control. Additionally, intense signals derive from the mushroom bodies, higher-order integration centers for olfactory, visual, gustatory and tactile information. To investigate whether AmTAR1-expressing brain structures are in vicinity to tyramine releasing sites, a specific tyramine antibody was applied. Tyramine-like labeling was observed in AmTAR1-IR positive structures, although it was sometimes weak and we did not always find a direct match of ligand and receptor. Moreover, tyramine-like immunoreactivity was also found in brain regions without AmTAR1-IR (optic lobes, antennal lobes), indicating that other tyramine-specific receptors may be expressed there. KW - antibody KW - biogenic amines KW - G-protein coupled receptor KW - honeybee KW - tyramine Y1 - 2017 U6 - https://doi.org/10.1002/cne.24228 SN - 0021-9967 SN - 1096-9861 VL - 525 SP - 2615 EP - 2631 PB - Wiley CY - Hoboken ER - TY - JOUR A1 - Scheiner, Ricarda A1 - Reim, Tina A1 - Sovik, Eirik A1 - Entler, Brian V. A1 - Barron, Andrew B. A1 - Thamm, Markus T1 - Learning, gustatory responsiveness and tyramine differences across nurse and forager honeybees JF - The journal of experimental biology N2 - Honeybees are well known for their complex division of labor. Each bee sequentially performs a series of social tasks during its life. The changes in social task performance are linked to gross differences in behavior and physiology. We tested whether honeybees performing different social tasks (nursing versus foraging) would differ in their gustatory responsiveness and associative learning behavior in addition to their daily tasks in the colony. Further, we investigated the role of the biogenic amine tyramine and its receptors in the behavior of nurse bees and foragers. Tyramine is an important insect neurotransmitter, which has long been neglected in behavioral studies as it was believed to only act as the metabolic precursor of the better-known amine octopamine. With the increasing number of characterized tyramine receptors in diverse insects, we need to understand the functions of tyramine on its own account. Our findings suggest an important role for tyramine and its two receptors in regulating honeybee gustatory responsiveness, social organization and learning behavior. Foragers, which were more responsive to gustatory stimuli than nurse bees and performed better in appetitive learning, also differed from nurse bees in their tyramine brain titers and in the mRNA expression of a tyramine receptor in the brain. Pharmacological activation of tyramine receptors increased gustatory responsiveness of nurse bees and foragers and improved appetitive learning in nurse bees. These data suggest that a large part of the behavioral differences between honeybees may be directly linked to tyramine signaling in the brain. KW - Biogenic amines KW - Nurse bee KW - Apis mellifera KW - PER KW - Proboscis extension response Y1 - 2017 U6 - https://doi.org/10.1242/jeb.152496 SN - 0022-0949 SN - 1477-9145 VL - 220 SP - 1443 EP - 1450 PB - Company of Biologists Limited CY - Cambridge ER - TY - JOUR A1 - Reim, Tina A1 - Scheiner, Ricarda T1 - Division of labour in honey bees: age- and task-related changes in the expression of octopamine receptor genes JF - Insect molecular biology N2 - The honey bee (Apis melliferaL.) has developed into an important ethological model organism for social behaviour and behavioural plasticity. Bees perform a complex age-dependent division of labour with the most pronounced behavioural differences occurring between in-hive bees and foragers. Whereas nurse bees, for example, stay inside the hive and provide the larvae with food, foragers leave the hive to collect pollen and nectar for the entire colony. The biogenic amine octopamine appears to play a major role in division of labour but the molecular mechanisms involved are unknown. We here investigated the role of two characterized octopamine receptors in honey bee division of labour. AmOctR1 codes for a Ca2+-linked octopamine receptor. AmOctR3/4 codes for a cyclic adenosine monophosphate-coupled octopamine receptor. Messenger RNA expression of AmOctR1 in different brain neuropils correlates with social task, whereas expression of AmOctR3/4 changes with age rather than with social role per se. Our results for the first time link the regulatory role of octopamine in division of labour to specific receptors and brain regions. They are an important step forward in our understanding of complex behavioural organization in social groups. KW - Apis mellifera KW - behavioural plasticity KW - G-protein coupled receptor KW - AmOctR1 KW - AmOctR3 KW - 4 Y1 - 2014 U6 - https://doi.org/10.1111/imb.12130 SN - 0962-1075 SN - 1365-2583 VL - 23 IS - 6 SP - 833 EP - 841 PB - Wiley-Blackwell CY - Hoboken ER - TY - JOUR A1 - Scheiner, Ricarda A1 - Toteva, Anna A1 - Reim, Tina A1 - Sovik, Eirik A1 - Barron, Andrew B. T1 - Differences in the phototaxis of pollen and nectar foraging honey bees are related to their octopamine brain titers JF - Frontiers in physiology N2 - The biogenic amine octopamine is an important neuromodulator, neurohormone and neurotransmitter in insects. We here investigate the role of octopamine signaling in honey bee phototaxis. Our results show that groups of bees differ naturally in their phototaxis. Pollen forgers display a lower light responsiveness than nectar foragers. The lower phototaxis of pollen foragers coincides with higher octopamine titers in the optic lobes but is independent of octopamine receptor gene expression. Increasing octopamine brain titers reduces responsiveness to light, while tyramine application enhances phototaxis. These findings suggest an involvement of octopamine signaling in honey bee phototaxis and possibly division of labor, which is hypothesized to be based on individual differences in sensory responsiveness. KW - biogenic amines KW - tyramine KW - division of labor KW - honey bee KW - light responsiveness KW - insect KW - behavior Y1 - 2014 U6 - https://doi.org/10.3389/fphys.2014.00116 SN - 1664-042X VL - 5 PB - Frontiers Research Foundation CY - Lausanne ER - TY - THES A1 - Reim, Tina T1 - Biogene Aminrezeptoren bei der Honigbiene Apis mellifera T1 - Biogenic amine receptors in the honey bee Apis mellifera BT - Charakterisierung des Tyramin 2-Rezeptors und die Beteiligung der Octopamin- und Tyraminrezeptoren an der Steuerung der altersabhängigen Arbeitsteilung N2 - Die Honigbiene Apis mellifera zeigt innerhalb einer Kolonie eine an das Alter gekoppelte Arbeitsteilung. Junge Honigbienen versorgen die Brut (Ammenbienen), während ältere Honigbienen (Sammlerinnen) außerhalb des Stocks Pollen und Nektar eintragen. Die biogenen Amine Octopamin und Tyramin sind an der Steuerung der Arbeitsteilung maßgeblich beteiligt. Sie interagieren mit Zielzellen über die Bindung an G Protein gekoppelte Rezeptoren. A. mellifera besitzt fünf charakterisierte Octopaminrezeptoren (AmOctαR1, AmOctβR1-4), einen charakterisierten Tyraminrezeptor (AmTyr1) sowie einen weiteren putativen Tyraminrezeptor. In der vorliegenden Arbeit wurde dieser putative Aminrezeptor als zweiter Tyraminrezeptor (AmTyr2) identifiziert, lokalisiert und pharmakologisch charakterisiert. Die von der cDNA abgeleitete Aminosäuresequenz weist strukturelle Eigenschaften und konservierte Motive von G Protein gekoppelten Rezeptoren auf. Phylogenetisch ordnet sich der AmTyr2 Rezeptor bei den Tyramin 2 Rezeptoren anderer Insekten ein. Die funktionelle und pharmakologische Charakterisierung des putativen Tyraminrezeptors erfolgte in modifizierten HEK293 Zellen, die mit der Rezeptor cDNA transfiziert wurden. Die Applikation von Tyramin aktiviert Adenylylcyclasen in diesen Zellen und resultiert in einem Anstieg des intrazellulären cAMP Gehalts. Der AmTyr2 Rezeptor kann durch Tyramin in nanomolaren Konzentrationen halbmaximal aktiviert werden. Während es sich bei Octopamin um einen wirkungsvollen Agonisten des Rezeptors handelt, sind Mianserin und Yohimbin effektive Antagonisten. Für die Lokalisierung des Rezeptorproteins wurde ein polyklonaler Antikörper generiert. Eine AmTyr2-ähnliche Immunreaktivität zeigt sich im Gehirn in den optischen Loben, den Antennalloben, dem Zentralkomplex und in den Kenyon Zellen der Pilzkörper. Des Weiteren wurde die Rolle der Octopamin- und Tyraminrezeptoren bei der Steuerung der altersabhängigen Arbeitsteilung analysiert. Die Genexpression des AmOctαR1 in verschiedenen Gehirnteilen korreliert unabhängig vom Alter mit der sozialen Rolle, während sich die Genexpression von AmOctβR3/4 und den Tyraminrezeptoren AmTyr1 und AmTyr2 maximal mit dem Alter aber nicht der sozialen Rolle ändert. Sammlerinnen weisen einen höheren Octopamingehalt im Gesamtgehirn auf als Ammenbienen; bei Tyramin zeigen sich keine Unterschiede. Während Tyramin offensichtlich keine direkte Rolle spielt, werden durch Octopamin gesteuerte Prozesse der altersabhängigen Arbeitsteilung bei der Honigbiene vermutlich über den AmOctαR1 vermittelt. Die Ergebnisse der vorliegenden Arbeit zeigen die wichtige Rolle von biogenen Aminen, insbesondere Octopamin bei der sozialen Organisation von Insektenstaaten. N2 - The honey bee Apis mellifera exhibits an age-dependent division of labour. Young bees take care of the brood (nurse bees), while older honey bees (foragers) leave the hive to provide the colony with pollen and nectar. The biogenic amines octopamine and tyramine are significantly involved in regulating the division of labour. They interact with target cells via binding to G protein-coupled receptors. A. mellifera has five characterised octopamine receptors (AmOctαR1, AmOctβR1-4), one characterised tyramine receptor (AmTyr1) and an additional putative tyramine receptor. In the present study, the putative amine receptor was identified as a second tyramine receptor (AmTyr2), was localized and characterised pharmacologically. The deduced amino acid sequence shows structural properties and conserved motifs of G protein-coupled receptors. Phylogenetically the AmTyr2 receptor clusters with tyramine 2 receptors from other insect species. Functional and pharmacological characterisation of the putative tyramine receptor was carried out using modified HEK293 cells trans¬fected with the receptor cDNA. Application of tyramine activates adenylyl cyclases in these cells, which leads to an elevated intracellular cAMP level. Half maximal activation can be achieved by applying tyramine with concentrations in the nanomolar range. While octopa¬mine is an effective agonist of the receptor, mianserin and yohimbine are the most effective antagonists. A polyclonal antibody was generated for the localisation of the receptor protein. AmTyr2 like immunoreactivity can be observed in the optic lobes, the Kenyon cells of the mushroom bodies, the antennal lobes and the central complex of the brain. Furthermore, the role of the octopamine and tyramine receptors in regulating the age-dependent division of labour was analysed. The gene expression of the AmOctαR1 in different brain neuropiles correlates with the social role of the honey bee, while the gene expression of AmOctβR3/4, AmTyr1 and AmTyr2 mostly changes with age but not social role. Additionally, foragers have higher octopamine brain titres than nurse bees. No differences can be observed for the titre of tyramine. Octopamine-regulated processes in age-dependent division of labour are probably mediated via the AmOctαR1. Tyramine has obviously no direct impact on the age-dependent division of labour. The present study shows the important role of biogenic amines, particularly octopamine in the social organisation of insect societies. KW - Apis mellifera KW - honey bee KW - Honigbiene KW - biogene Amine KW - biogenic amines KW - Octopamin KW - octopamine KW - Tyramin KW - tyramine KW - Arbeitsteilung KW - division of labor Y1 - 2015 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-80982 ER -