Global ETD Search

61	A COMPARISON OF OBESITY CANDIDATE GENES IN THE ANABOLIC NEUROPEPTIDE PATHWAY IN THE SAMOAN AND AMERICAN SAMOAN POPULATIONS SMELSER, DIANE T. January 2006 (has links) No description available. Health Sciences, Public Health Obesity Samoan Population Anabolic Neuropeptide Pathway Candidate Gene Association Study Neuropeptide Y
62	Deep breath and relax: a study of NPS/NPSR1 Zhu, Hongyan 20 April 2011 (has links) No description available. Biology neuropeptide S neuropeptide S receptor 1 stress respiration asthma anxiety
63	Évaluation de traceurs pour cibler les récepteurs peptidiques surexprimés dans les cancers du sein Dumulon-Perreault, Véronique January 2009 (has links) Le cancer du sein est le cancer le plus répandu chez les Canadiennes. Grâce aux avancées technologiques et scientifiques, l'incidence de ce cancer est stable depuis une quinzaine d'année et le taux de mortalité diminue. Le plus important dans le traitement du cancer est un diagnostic précoce et un suivi de la thérapie bien adapté au type de cancer. La tomographie d'émission par positrons (TEP) permet de visualiser la distribution spatiale et temporelle de molécules radiomarquées. Le principal traceur utilisé en oncologie, le 2-deoxy-2-[18]Fluoro-D-deoxyglucose ( 18 [F]FDG), est un analogue du glucose. Il permet de visualiser les tumeurs et d'évaluer le métabolisme du glucose dans les cellules. Par contre, il a une lacune importante : il n'est pas spécifique aux cellules cancéreuses car il marque les cellules qui ont un métabolisme du glucose élevé. Malgré cela, le FDG reste un traceur très utilisé. Cependant, le développement de nouveaux composés spécifiques à certains récepteurs surexprimés dans différents types de cancer reste une idée à exploiter afin d'améliorer l'imagerie TEP. Le neuropeptide Y (NPY) est un peptide de 36 acides aminés qui est un neurotransmetteur très abondant dans le système nerveux central et périphérique. Il a plusieurs rôles physiologiques importants. Il est un stimulateur puissant de la prise de nourriture, un anxiolytique et un puissant vasoconstricteur. Quatre types de récepteurs humains ont été clonés, soient : Y1R, Y2R, Y4R et Y5R. Le récepteur Y1 est présent dans 85% des carcinomes mammaires primaires chez l'humain. Dans les tissus sains, le récepteur Y2 est exprimé de façon prédominante tandis que sur les cellules cancéreuses, c'est l'expression du récepteur YI qui prédomine. Le ratio de l'expression Y1/Y2 pourrait donc être exploité afin de détecter de façon plus précoce le cancer du sein. La bombésine (BBN), un peptide de 14 acides amines, a été découvert chez la grenouille Bombina Bombina . L'équivalent humain du BBN, le GRP possède 27 acides amines. La bombésine se lie à 3 types de récepteurs humains dont le récepteur à relâche de gastrine (GRPR). Il est surexprimé dans 65% des cas de carcinomes canalaires in situ . Le GRPR peut également être utilisé comme marqueur du caractère malin dans les cas de cancer. Un hétérodimère est l'union de deux molécules différentes pour n'en former qu'une seule. Dû au fait que les récepteurs Y1 et GRP ne sont pas surexprimés dans 100% des cas de cancer du sein l'utilisation d'une seule molécule qui ciblerait à la fois les deux récepteurs serait avantageuse pour l'imagerie du cancer du sein. Les avantages à l'utilisation d'un hétérodimère plutôt qu'un mélange de deux composés radioactifs sont : une dose de radioactivité administrée moins grande pour le même résultat et les interactions possibles entre les composés sont évitées. Puisque deux récepteurs surexprimés dans les cas de cancer du sein sont visés du même coup par le peptide, une plus grande captation tumorale est attendue. Le premier objectif de l'étude est de développer un peptide capable de lier spécifiquement le récepteur Y1 du NPY dans les cas de cancer du sein. Le second objectif est de développer un peptide hétérodimère ciblant préférentiellement les récepteurs Y1 et GRP dans les cas de cancer du sein. Les peptides seront combinés à un radio-isotope, le 64 Cu, afin de permettre l'imagerie TEP. Plusieurs techniques seront utilisées pour caractériser les différents peptides incluant des études de compétition in vitro , de stabilité plasmatique ainsi que de biodistribution. Afin d'évaluer tout le potentiel du traceur hétérodimère, une étude comparative entre ce dernier et les deux traceurs monomères sera présentée."--Résumé abrégé par UMI Radiotraceur TEP Cancer du sein Hétérodimère peptidique Bombésine Neuropeptide Y
64	Actions of appetite regulating peptides on supraoptic nucleus (SON) oxytocin neurones Velmurugan, Sathya January 2009 (has links) Oxytocin has established roles in parturition and lactation, but can also be released in response to non-reproductive stimuli, such as hyperosmolarity and stress. As a majority of appetite regulating peptides activate the hypothalamo-pituitary-adrenal stress axis, and oxytocin is also a stress hormone in the rat, it was hypothesized that the oxytocin system in the neurohypophysial axis could be a target for appetite-regulating peptides of central and peripheral origin. The effects of central administration of neuropeptide Y (NPY; a central orexigenic peptide and a central and peripheral neurotransmitter co-released with noradrenaline; n=5 rats) and systemic administration of secretin (a peripheral gut peptide belonging to the family of brain-gut peptides; n=26) and leptin (a peripheral anorexigenic peptide from adipose tissue; n=23) on the electrical activity of SON oxytocin neurones in vivo were studied in urethane-anaesthetized female rats with extracellular recording. Effects were compared with the excitatory responses to cholecystokinin (CCK; a peripheral anorexigenic gut peptide; n=45). Influences of fasting and pregnancy and effects of these peptides on the activity of SON vasopressin neurones were also studied. Results: (1) All the central and peripheral appetite peptides tested increased the electrical activity of SON oxytocin neurones. (a) NPY: Basal firing rate of 3.5 ± 1.05 (mean ± s.e.m) spikes/s was increased by 1 ± 0.45 spikes/s 1min after NPY (basal vs 0-10min post-NPY: P=0.03, paired t-test; n=5). (b) Secretin: Basal rate of 4.1 ± 0.4 spikes/s was increased by 1.7 ± 0.2 spikes/s 2.5min after secretin (basal vs 0-10min post-secretin: P<0.001, paired t-test; n=26). (c) Leptin: Basal rate of 3.4 ± 0.4 spikes/s was increased by 0.4 ± 0.08 spikes/s 1.5min after leptin (basal vs 0-10min post-leptin: P=0.01, paired t-test; n=23). (d) CCK: Basal rate of 3.6 ± 0.3 spikes/s was increased by 1.1 ± 0.15 spikes/s 1min after CCK (basal vs 0-10min post- CCK: P<0.001, Wilcoxon signed rank test; n=45). (2) Secretin induced excitatory responses were greater than to other peptides (P<0.001, Kruskal-Wallis one-way ANOVA on ranks). (3) Secretin dose-dependently increased SON oxytocin neurone electrical activity and peripheral oxytocin release in anaesthetized rats. (4) Intracerebroventricular infusion and microdialysis studies with benoxathian (α1 adrenergic antagonist) revealed that secretininduced excitation of SON oxytocin and vasopressin neurones involves central excitatory noradrenergic pathways. (5) Fasting for 18h did not alter the excitation of SON oxytocin neurones induced by secretin, CCK and leptin. (6) The pathway leading to excitation of oxytocin neurones by CCK was not influenced by prior leptin administration. (7) SON oxytocin neurones were responsive to leptin during late pregnancy. (8) NPY-induced excitation of oxytocin neurones was intact in anaesthetised late pregnant rats, contrasting with attenuated oxytocin secretory responses observed previously in conscious rats. (9) Systemic NPY excited SON oxytocin neurones. (10) Systemic CCK administration either inhibited (77%) or did not affect (23%) SON vasopressin neurones, while leptin had no significant effect, and responses to secretin were predominantly excitatory (67%). Systemic NPY inhibited vasopressin neurones, but central NPY was ineffective. Conclusion: Appetite peptides target SON oxytocin neurones. Postprandially released secretin and leptin might, like CCK, induce peripheral oxytocin release, so as to regulate water and electrolyte homeostasis, which is inevitably disturbed during feeding. Any central release of oxytocin induced by these peptides, might regulate feeding behaviour and satiety. Oxytocin neurone excitation induced by NPY may be relevant during stress responses. 612.3
65	Evolutionary and Pharmacological Studies of NPY and QRFP Receptors Xu, Bo January 2014 (has links) The neuropeptide Y (NPY) system consists of 3-4 peptides and 4-7 receptors in vertebrates. It has powerful effects on appetite regulation and is involved in many other biological processes including blood pressure regulation, bone formation and anxiety. This thesis describes studies of the evolution of the NPY system by comparison of several vertebrate species and structural studies of the human Y2 receptor, which reduces appetite, to identify amino acid residues involved in peptide-receptor interactions. The NPY system was studied in zebrafish (Danio rerio), western clawed frog (Xenopus tropicalis), and sea lamprey (Petromyzon marinus). The receptors were cloned and functionally expressed and their pharmacological profiles were determined using the native peptides in either binding studies or a signal transduction assay. Some peptide-receptor preferences were observed, indicating functional specialization. A receptor family closely related to the NPY receptors, called the QRFP receptors, was investigated. A QRFP receptor was cloned from amphioxus, Branchistoma floridae, showing that the receptor arose before the origin of the vertebrates. Evolutionary studies demonstrated that the ancestral vertebrate had as many as four QRFP receptors, only one of which remains in mammals today. This correlates with the NPY receptor family, located in the same chromosomal regions, which had seven members in the ancestral vertebrate but only 4-5 in living mammals. Some vertebrates have considerably more complex NPY and QRFP receptor systems than humans and other mammals. Two studies investigated interactions of NPY-family peptides with the human Y2 receptor. Candidate residues, selected based on structural modeling and docking, were mutated to disrupt possible interactions with peptide ligands. The modified receptors were expressed in cultured cells and investigated by measuring binding and functional responses. Several receptor residues were found to influence peptide-receptor interactions, some of which are involved in maintaining receptor structure. In a pilot study, the kinetics of peptide-receptor interaction were found to be very slow, of the order several hours. In conclusion, this thesis clarifies evolutionary relationships for the complex NPY and QRFP peptide-receptor systems and improves the structural models of the human NPY-family receptors, especially Y2. These results will hopefully facilitate drug design for targeting of NPY-family receptors. Neuropeptide Y genome duplication Evolution vertebrate Pharmacology Modelling Kinetics
66	Morphological and functional effects of insulin signaling and the bHLH transcription factor Dimmed on different neuron types in Drosophila Liu, Yiting January 2016 (has links) In Drosophila, the insulin signaling pathway is at the interface between dietary conditions and control of growth and development, reproduction, stress responses and life span. Eight insulin like peptides (Dilp1-8), an insulin tyrosine kinase receptor (dInR) and its downstream components, as well as a relaxin-like receptor type (Lgr3) form the core of this signaling. Here we showed that the dInR mediates post-mitotic cell growth specifically in about 300 peptidergic neurons expressing the basic helix loop helix (bHLH) transcription factor Dimmed (Paper I). Overexpression of dInR in Dimm positive neurons leads to increased size of cell body, Golgi apparatus and nucleus, whereas dInR knockdown causes an opposite effect. Manipulation of downstream components of insulin signaling induces similar changes in Dimm positive neurons. This mechanism is nutrient dependent. In Paper II, we further investigate the relation between Dimmed and dInR for regulation of cell growth. Coexpressing Dimm and dInR in a range of Dimm negative neurons results in increased cell size in both larval and adult stages. We provide further evidence that dInR regulates cell growth in a Dimm dependent manner and that DILP6 from glia cells is involved in this regulation. In addition, we find that Dimm alone is capable of triggering cell growth in certain neuron types at different developmental stages. Furthermore, ectopic Dimm alone can block apoptosis. Dimm is a known master regulator of peptidergic cell fate. In paper III we find that ectopic expression of Dimm in Dimm negative motor neurons results in transformation the neurons towards a neuroendocrine phenotype. They acquire enlarged axon terminations and boutons, lose both pre- and postsynaptic markers, and display diminished levels of wingless and its receptor dFrizzled. Furthermore they show increased expression of several Dimm targets. Finally, combined ectopic Dimm and dInR expression gives rise to stronger phenotypes. In paper IV we studied another DILP possibly involved in growth regulation, the under-investigated DILP1. We generated Dilp1-Gal4 lines and anti DILP1 antibodies and found that DILP1 is transiently expressed in brain insulin producing cells (IPCs) from pupal stages to newly hatched adult flies. Diapausing virgin female flies display a high expression level of dilp1/DILP1 over at least 9 weeks of adult life. DILP1 expression is also correlated with the persistence of larval/pupal fat body and its expression is regulated by other DILPs and short neuropeptide F (sNPF). Flies mutant in dilp1 display increased food intake, but decreased stress resistance and life span. We found no obvious role of DILP1 in growth regulation. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 3: Manuscript. Paper 4: Manuscript.</p> insulin signaling Dimm neuropeptide insulin receptor insulin-like peptide drosophila
67	Identification and functional characterization of relaxin-type and pedal peptide/orcokinin-type neuropeptides in the starfish Asterias rubens Lin, Ming January 2017 (has links) Neuropeptides are neuronal signaling molecules that regulate many physiological and behavioural processes in vertebrates and invertebrates. Investigation of neuropeptide signaling in echinoderms (e.g. starfish) can provide insights into the evolution of neuropeptide systems because as deuterostomian invertebrates they occupy an "intermediate" phylogenetic position between vertebrates and protostomian invertebrates. Recent analysis of neural transcriptome data from the starfish Asterias rubens has identified 40 transcripts encoding neuropeptide precursors. Here the expression and function of neuropeptides derived from four of these precursors was investigated: relaxin-like gonad-stimulating peptide precursor (AruRGPP), relaxin-like peptide precursor 2 (AruRLPP2), pedal peptide-like neuropeptide precursors 1 and 2 (ArPPLNP1 and ArPPLNP2). AruRGP induces spawning of ovarian fragments from A. rubens. Analysis of the expression of AruRGPP in A. rubens using mRNA in situ hybridization revealed expression by cells in the radial nerve cords, circumoral nerve ring and tube feet. Furthermore, a band of AruRGPP-expressing cells was also identified in the body wall epithelium lining the cavity that surrounds the sensory terminal tentacle and optic cushion at the tips of the arms. Discovery of these cells is important because they are candidate physiological mediators for hormonal control of starfish spawning in response to environmental cues. Interestingly, AruRLPP2 is also expressed in the same region of the arm tip as AruRGPP but the physiological role(s) of AruRLP2 is not yet known. Analysis of the expression of ArPPLNP1 and ArPPLNP2 using mRNA in situ hybridization revealed a widespread pattern of expression in A. rubens. Furthermore, immunohistochemical localization of peptides derived from these precursors revealed immunostaining in neuronal processes innervating muscles. Consistent with this pattern of expression, peptides derived from ArPPLNP1 and ArPPLNP2 act as muscle relaxants in starfish. Interestingly, this contrasts with previous findings from protostomian invertebrates, where pedal peptide/orcokinin-type neuropeptides act as muscle contractants.
68	The effects of neuroendocrine factors on islet cell gene expression. January 1996 (has links) by Hinny Shuk-Yee Lam. / Year shown on spine: 1997. / Thesis (M.Phil.)--Chinese University of Hong Kong, 1996. / Includes bibliographical references (leaves 92-117). / Declaration --- p.i / Acknowledgements --- p.ii / Abstract --- p.iii / Table of Contents --- p.v / Chapter Chapter 1 --- Introduction --- p.1 / Chapter 1.1 --- Pancreas and Islets of Langerhans --- p.1 / Chapter 1.1.1 --- Islet Hormones and Glucose Balance --- p.3 / Chapter 1.1.2 --- Glucagon and Its Derived Peptides --- p.4 / Chapter A. --- Tissue-specific Post-translational Processing --- p.4 / Chapter B. --- Features of Proglucagon Gene --- p.6 / Chapter 1.1.3 --- Insulin and Features of Its Gene --- p.9 / Chapter 1.2 --- Regulation of Islet Hormone Secretion --- p.12 / Chapter 1.2.1 --- Endocrine Control --- p.12 / Chapter A --- GIP --- p.13 / Chapter B. --- Truncated GLP-1 --- p.13 / Chapter 1.2.2 --- Paracrine Control --- p.14 / Chapter 1.2.3 --- Neuroendocrine Control --- p.15 / Chapter 1.3 --- Neuropeptide Y --- p.16 / Chapter 1.3.1 --- NPY in Central Nervous System --- p.17 / Chapter 1.3.2 --- NPY in Pancreas --- p.17 / Chapter 1.3.3 --- NPY and Islet Hormones --- p.18 / Chapter 1.4 --- Synthesis and Secretion --- p.19 / Chapter 1.5 --- Objectives of Study --- p.23 / Chapter Chapter 2 --- Materials and Methods --- p.26 / Chapter 2.1 --- Effects of NPY on Islet Gene Expression --- p.26 / Chapter 2.1.1 --- Tissue Culture --- p.26 / Chapter A. --- Materials --- p.26 / Chapter B. --- Maintenance and Passage --- p.26 / Chapter C. --- Experimental Protocol --- p.28 / Chapter 2.1.2 --- Total RNA Isolation --- p.28 / Chapter A. --- Materials --- p.28 / Chapter B. --- Extraction Using FastPrep System --- p.29 / Chapter C. --- Quantification of RNA --- p.30 / Chapter D. --- Preparation of Reagents --- p.30 / Chapter 2.1.3 --- Northern Blot Analysis --- p.31 / Chapter A. --- Materials --- p.31 / Chapter B. --- Formaldehyde Gel Electrophoresis --- p.32 / Chapter C. --- Transfer onto Nylon Membrane --- p.33 / Chapter D. --- Labeling of cDNA Probes --- p.34 / Chapter E. --- Hybridization and Autoradiography --- p.35 / Chapter F. --- Preparation of Reagents --- p.36 / Chapter 2.1.4 --- Preparation of cDNA Probe --- p.37 / Chapter A. --- Materials --- p.37 / Chapter B. --- Preparation of Competent Cells --- p.37 / Chapter C. --- Transformation --- p.38 / Chapter D. --- Plasmid DNA Isolation --- p.39 / Chapter E. --- Restriction Enzyme Digestion --- p.41 / Chapter F. --- Agarose Gel Electrophoresis --- p.42 / Chapter G. --- Isolation of DNA Fragments --- p.42 / Chapter H. --- Preparation of Reagents --- p.43 / Chapter 2.1.5 --- Data Analysis --- p.46 / Chapter 2.2 --- Effects of NPY on Cytosolic Calcium --- p.46 / Chapter 2.2.1 --- Tissue Culture --- p.47 / Chapter 2.2.2 --- Confocal Laser Scanning Microscopy --- p.47 / Chapter A. --- Materials --- p.47 / Chapter B. --- Loading of Dye --- p.48 / Chapter C. --- Cytosolic Calcium Measurement --- p.49 / Chapter D. --- Preparation of Reagents --- p.49 / Chapter Chapter 3 --- Results --- p.51 / Chapter 3.1 --- Studies on Islet Gene Expression --- p.51 / Chapter 3.1.1 --- Effect of NPY on Proglucagon Expression --- p.51 / Chapter A. --- Effect at 11 mM Glucose --- p.51 / Chapter B. --- Effect at 5 mM Glucose --- p.52 / Chapter 3.1.2 --- Effect of NPY on Proinsulin Expression --- p.52 / Chapter 3.1.3 --- "Effect of PYY, PP and FSK on Proglucagon Expression" --- p.53 / Chapter 3.2 --- Studies on Cytosolic Calcium --- p.65 / Chapter 3.2.1 --- Features of InRlG9 Cells --- p.65 / Chapter 3.2.2 --- Effect of NPY on Cellular Calcium Level --- p.66 / Chapter Chapter 4 --- Discussion --- p.77 / Chapter Chapter 5 --- References --- p.92 Islands of Langerhans Gene expression Islets of Langerhans Gene Expression Neuropeptide Y
69	Neuronal basis of temporal polyethism and sky-compass based navigation in \(Cataglyphis\) desert ants / Die neuronale Grundlage von Alterspolyethismus und Himmelskompassnavigation in der Wüstenameise \(Cataglyphis\) Schmitt, Franziska January 2017 (has links) (PDF) Desert ants of the genus Cataglyphis (Formicinae) are widely distributed in arid areas of the palearctic ecozone. Their habitats range from relatively cluttered environments in the Mediterranean area to almost landmark free deserts. Due to their sophisticated navigational toolkit, mainly based on the sky-compass, they were studied extensively for the last 4 decades and are an exceptional model organism for navigation. Cataglyphis ants exhibit a temporal polyethism: interior workers stay inside the dark nest and serve as repletes for the first ∼2 weeks of their adult life (interior I). They then switch to nursing and nest maintenance (interior II) until they transition to become day-active outdoor foragers after ∼4 weeks. The latter switch in tasks involves a transition phase of ∼2-3 days during which the ants perform learning and orientation walks. Only after this last phase do the ants start to scavenge for food as foragers. In this present thesis I address two main questions using Cataglyphis desert ants as a model organism: 1. What are the underlying mechanisms of temporal polyethism? 2. What is the neuronal basis of sky-compass based navigation in Cataglyphis ants? Neuropeptides are important regulators of insect physiology and behavior and as such are promising candidates regarding the regulation of temporal polyethism in Cataglyphis ants. Neuropeptides are processed from large precursor proteins and undergo substantial post-translational modifications. Therefore, it is crucial to biochemically identify annotated peptides. As hardly any peptide data are available for ants and no relevant genomic data has been recorded for Cataglyphis, I started out to identify the neuropeptidome of adult Camponotus floridanus (Formicinae) workers (manuscript 1). This resulted in the first neuropeptidome described in an ant species – 39 neuropeptides out of 18 peptide families. Employing a targeted approach, I identified allatostatin A (AstA), allatotropin (AT), short neuropeptide F (sNPF) and tachykinin (TK) using mass spectrometry and immunohistology to investigate the distribution of AstA, AT and TK in the brain (manuscript 2). All three peptides are localized in the central complex, a brain center for sensory integration and high-order control of locomotion behavior. In addition, AstA and TK were also found in visual and olfactory input regions and in the mushroom bodies, the centers for learning and memory formation. Comparing the TK immunostaining in the brain of 1, 7 and 14 days old dark kept animals revealed that the distribution in the central complex changes, most prominently in the 14 day old group. In the Drosophila central complex TK modulates locomotor activity levels. I therefore hypothesize that TK is involved in the internal regulation of the interior I–interior II transition which occurs after ∼2 weeks of age. I designed a behavioral setup to test the effect of neuropeptides on the two traits: ’locomotor activity level’ and ’phototaxis’ (manuscript 3). The test showed that interior I ants are less active than interior II ants, which again are less active than foragers. Furthermore, interior ants are negatively phototactic compared to a higher frequency of positive phototaxis in foragers. Testing the influence of AstA and AT on the ants’ behavior revealed a stage-specific effect: while interior I behavior is not obviously influenced, foragers become positively phototactic and more active after AT injection and less active after AstA injection. I further tested the effect of light exposure on the two behavioral traits of interior workers and show that it rises locomotor activity and results in decreased negative phototaxis in interior ants. However, both interior stages are still more negatively phototactic than foragers and only the activity level of interior II ants is raised to the forager level. These results support the hypothesis that neuropeptides and light influence behavior in a stage-specific manner. The second objective of this thesis was to investigate the neuronal basis of skycompass navigation in Cataglyphis (manuscript 4). Anatomical localization of the sky-compass pathway revealed that its general organization is highly similar to other insect species. I further focused on giant synapses in the lateral complex, the last relay station before sky-compass information enters the central complex. A comparison of their numbers between newly eclosed ants and foragers discloses a rise in synapse numbers from indoor worker to forager, suggesting task-related synaptic plasticity in the sky-compass pathway. Subsequently I compared synapse numbers in light preexposed ants and in dark-kept, aged ants. This experiment showed that light as opposed to age is necessary and sufficient to trigger this rise in synapse number. The number of newly formed synapses further depends on the spectral properties of the light to which the ants were exposed to. Taken together, I described neuropeptides in C. floridanus and C. fortis, and provided first evidence that they influence temporal polyethism in Cataglyphis ants. I further showed that the extent to which neuropeptides and light can influence behavior depends on the animals’ state, suggesting that the system is only responsive under certain circumstances. These results provided first insight into the neuronal regulation of temporal polyethism in Cataglyphis. Furthermore, I characterized the neuronal substrate for sky-compass navigation for the first time in Cataglyphis. The high level of structural synaptic plasticity in this pathway linked to the interior–forager transition might be particularly relevant for the initial calibration of the ants’ compass system. / Wüstenameisen der Gattung Cataglyphis sind weit verbreitet in ariden Gebieten der paläarktischen Ökozone. Die von ihnen bewohnten Habitate reichen von landmarkenreichen Arealen im Mittelmeerraum, zu beinahe landmarkenfreien Wüstengebieten. Aufgrund ihres hochentwickelten Navigationssystems, welches größtenteils auf dem Himmelskompass basiert, wurden sie in den letzten 4 Jahrzehnten extensiv studiert und sind ein einzigartiges Modellsystem für Navigation. Cataglyphis weisen einen alterskorrelierten Polyethismus auf: Innendienstler dienen als Speichertiere für die ersten ∼2 Wochen ihres adulten Lebens (Interior I). Sie gehen daraufhin zu Brutpflege und Nestbau (Interior II) über bis sie nach ∼4 Wochen zu tagaktiver Furagiertätitkeit außerhalb ihres Nestes wechseln. Dieser letzte Übergang dauert ∼2-3 Tage und wird von den Ameisen genutzt, um Lernund Orientierungsläufe durchzuführen. In der vorliegenden Arbeit befasse ich mich vor allem mit zwei Fragen, die ich mit Hilfe von Cataglyphis als Modellorganismus beantworten möchte: 1. Welches sind die zugrunde liegenden Mechanismen des Alterspolyethismus? 2. Was ist die neuronale Grundlage von Navigation, die auf dem Himmelskompass basiert? Neuropeptide sind bedeutende Regulatoren der Physiologie und des Verhaltens von Insekten und als solche vielversprechende Kandidaten im Hinblick auf die Regulation des Alterspolyethismus in Cataglyphis Ameisen. Neuropeptide werden aus größeren Vorläuferproteinen herausgeschnitten und posttranslational stark modifiziert. Daher ist es wichtig, annotierte Peptide auch biochemisch zu identifizieren. Da für Ameisen kaum Peptiddaten zur Verfügung stehen und es zudem keine relevanten genomischen Daten für Cataglyphis gibt, identifizierte ich zunächst das Neuropeptidom adulter Camponotus floridanus (Formicinae) Arbeiterinnen (Manuskript 1). Daraus resultierte das erste Neuropeptidom, das für eine Ameisenart beschrieben wird—39 Neuropeptide aus 18 Peptidfamilien. In einer weiteren Studie identifizierte ich gezielt die Neuropeptidfamilien Allatostatin A (AstA), Allatotropin (AT), das kurze Neuropeptid F (sNPF) und Tachykinin (TK) mittels Massenspektroskopie und untersuchte die Verteilung von AstA, AT und TK im Gehirn mit Hilfe der Immunhistologie (Manuskript 2). Alle drei Peptide sind im Zentralkomplex lokalisiert, dem Gehirnzentrum welches sensorische Eingänge integriert und in einer übergeordneten Rolle Lokomotorverhalten steuert. AstA und TK sind zudem in den visuellen und olfaktorischen Eingangsregionen, sowie den Pilzkörpern, den Zentren für Lernen und Gedächtnisbildung, zu finden. Ein Vergleich der TK-Immunfärbung im Gehirn von 1, 7 und 14 Tage alten im Dunkeln gehaltenen Tieren zeigt, dass sich die Verteilung im Zentralkomplex verändert— dies ist besonders prominent in der 14 Tage alten Gruppe. In Drosophila moduliert TK im Zentralkomplex Lokomotoraktivität. Basierend darauf stelle ich die Hypothese auf, dass TK in der internen Regulierung des Übergangs von Interior I zu Interior II involviert ist, welchen die Tiere im Alter von ∼2 Wochen durchlaufen. Für eine dritte Studie konstruierte ich ein Verhaltenssetup um den Einfluss von Neuropeptiden und Licht auf die beiden Verhaltensmerkmale ’Lokomotoraktivität’ und ’Phototaxis’ zu testen (Manuskript 3). Der Test zeigte, dass Interior I Ameisen weniger aktiv sind als Interior II Ameisen, welche wiederum weniger aktiv sind als Furageure. Zudem sind Interior Ameisen negativ phototaktisch, verglichen mit einer häufiger zu beobachtenden positiven Phototaxis bei Furageuren. Im Test zeigte sich auch, dass der Einfluss von AstA und AT stadiumsspezifisch ist: während das Verhalten von Interior I Tieren nicht offensichtlich beeinflusst wird, werden Furageure durch die Injektion von AT positiv phototaktisch, sowie aktiver und AstA-Injektion führt zu geminderter Lokomotoraktivität. Darüber hinaus testete ich den Lichteinfluss auf beide Verhaltensmerkmale in den Innendienststadien und zeige, dass er Lokomotoraktivität steigert und in einer geminderten negativen Phototaxis resultiert. Beide Innendienststadien sind jedoch weiterhin negativer phototaktisch als Furageure und nur die Lokomotoraktivtät von Interior II Ameisen wird auf das Niveau von Furageuren angehoben. Diese Ergebnisse stützen die Hypothese, dass Neuropeptide und Licht stadiumsspezifisch Verhalten beeinflussen. Der zweite Aspekt dieser Thesis war es, die neuronale Grundlage der Himmelskompassnavigation in Cataglyphis aufzuklären (Manuskript 4). Die neuroanatomische Lokalisation der Himmelskompasssehbahn zeigt, dass die allgemeine Organisation dieser neuronalen Bahn der bei bisher untersuchten anderen Insekten stark ähnelt. Ich habe mich daraufhin auf Riesensynapsen im lateralen Komplex konzentriert, der letzten Verschaltungsstation ehe die Himmelskompassinformation in den Zentralkomplex übertragen wird. Ein Vergleich zwischen der Synapsenzahl in frisch geschlüpfte Ameisen und erfahrenen Furageueren zeigte einen Anstieg der Synapsenzahl von Innendienst zu Furaguer, was aufgabenabhängige synaptische Plastizität in der Himmelskompasssehbahn suggeriert. In einem weiteren Versuch verglich ich die Riesensynapsenzahlen lichtexponierter Tiere und dunkel gehaltener, gealteter Tiere. Dieses Experiment zeigte, dass der Zuwachs an Riesensynapsen durch den Lichteinfluss ausgelöst wird und keinen altersabhängigen Prozess darstellt. Zudem verändert sich die Anzahl der neu gebildeten Riesensynapsen in Abhängigkeit von den spektralen Eigenschaften des Lichts, dem die Ameisen ausgesetzt sind. Zusammengefasst beschrieb ich in dieser Thesis Neuropeptide in C. floridanus und Cataglyphis und lieferte erste Evidenz, dass diese den Alterspolyethismus in Cataglyphis beeinflussen. Zudem zeigte ich, dass das Ausmaß in dem Neuropeptide und Lichtexposition Verhalten beeinflussen können, stadiumsspezifisch ist. Dies suggeriert, dass das System nur unter bestimmten Bedingungen auf externe Einflüsse reagiert. Diese Ergebnisse lieferten erste wichtige Einblicke in die neuronale Grundlage von Alterspolyethismus in Cataglyphis. Zudem charakterisierte ich erstmals das neuronale Substrat der Himmelskompassnavigation in Cataglyphis. Das hohe Maß an synaptischer Plastizität in dieser Sehbahn beim Übergang von Innenzu Außendienst, könnte besondere Relevanz für die initiale Kalibrierung des Kompasssystems haben. Cataglyphis Neuroethologie Neuropeptide Neuronale Plastizität Soziale Insekten ddc:573
70	Molecular Evolution of Neuropeptide Y Receptors in Vertebrates Salaneck, Erik January 2001 (has links) <p>The three evolutionarily related peptides neuropeptide Y (NPY), peptide YY (PYY) and pancreatic polypeptide (PP) are ligands to at least five G-protein coupled receptors in mammals, which are denoted by numbers. NPY has many physiological effects including stimulation of appetite and regulation of circadian rhythm and blood pressure. This work describes the ancient origin of the NPY receptor genes as deduced from molecular cloning of six receptors in four distantly related vertebrate species. Three of the receptors have been functionally expressed <i>in vitro</i> to determine ligand binding properties. </p><p>The first Y2 receptor from any non-mammalian species was cloned from the chicken. The receptor was found to exhibit substantial structural and pharmacological differences to mammalian Y2, but showed similar anatomical distribution. </p><p>A receptor was cloned in a primitive vertebrate, an agnathan fish, the river lamprey <i>Lampetra fluviatilis</i>. Phylogenetic analyses indicated that it represents an orthologue to the ancestor of Y4 and the teleost subtypes Yb and Yc. </p><p>Three NPY receptors were cloned from a shark, the spiny dogfish <i>Squalus acanthias</i>. These were found to correspond to the three mammalian subtypes Y1, Y4 and y6, and was thereby the first complete Y1 subfamily in any species outside the mammalian lineage. This suggests that all three receptor subtypes arose in the common ancestor of sharks and mammals 420-450 million years ago. </p><p>The sixth described receptor was cloned from the zebrafish, <i>Danio rerio</i>, and was shown to have equal identity to all three mammalian Y1 subfamily receptors. Phylogenetic analyses including the shark and lamprey sequences suggested that Yb may represent a fourth Y1 subfamily gene.</p><p>It has previously been found that the genes for Y1, Y4 and y6 are located on separate chromosomes. Taken together, these results show that the NPY receptor family expanded by chromosomal duplications early in vertebrate evolution, prior to the origin of gnathostomes. This work will be important for the determination of the time points for the origin of the many functions of NPY as well as for the understanding of the processes that shaped the vertebrate genome.</p> Neurosciences Neuropeptide Y Receptor Evolution Neurovetenskap Neurology Neurologi

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