Global ETD Search

1	Monoamines and Peptides Interact to Inhibit Glutamatergic Signaling in Caenorhabditis elegans Wragg, Rachel T. 03 September 2010 (has links) No description available. Biology monoamines neuropeptides chemosensation
2	Characterizing the effect of serotonergic input on medullary Phox2b neurons Proch, Katherine Louise 01 May 2019 (has links) Biological functions take place within tightly controlled parameters, including pH, which is managed in part through the ventilatory chemoreflex. This reflex is mediated by central respiratory chemoreceptors (CRCs) specialized to detect blood pH/CO2. Two neuronal populations are thought to mediate this response: the serotonergic (5-HT) neurons of the medullary raphé, and the Phox2b expressing neurons of the retrotrapezoid nucleus (RTN). These groups are both responsive to CO2 stimuli in vivo and in vitro. There are also apparent one-way connections from the raphé to the RTN, which is sensitive to 5-HT. Due to its complex innervation, study of RTN neurons while isolated from other cells, especially 5-HT neurons, has been limited. Here, we developed a culture model that simplifies this circuit, limiting cell types to those found in the rostral ventral medulla. This protocol yielded healthy RTN and 5-HT neurons in vitro, as well as other cell types from that area. Upon study with patch-clamp electrophysiology, cultured RTN neurons responded to CO2 and 5-HT in similar ways to what is reported for different RTN neuron preparations. Using this model, RTN neuron chemosensitivity was significantly decreased during application of 5-HT7 antagonists (SB258719, SB269970) and a 5-HT2A antagonist (MDL 11,939). The effect of 5-HT7 antagonists was recapitulated in slice recordings. Therefore, signaling at 5-HT7 and 5-HT2A receptors is necessary for RTN neuron chemosensitivity. Exogenous 5-HT application also increased RTN neuron firing rate without potentiating the response to CO2, most likely indicating that the necessary 5-HT stimulation must come from neurons that can alter their activity during acidosis. We conclude that RTN neuron chemosensitivity is largely driven by chemosensitive 5-HT neurons, and should be considered an integrative or relay center, rather than an independently chemosensitive one. breathing chemosensation respiration SIDS Neuroscience and Neurobiology
3	Connecting the Circadian Clock with Chemosensation Chatterjee, Abhishek 2011 May 1900 (has links) Chemoreception is a primitive sense universally employed by organisms for finding and selecting food, rejecting toxic chemicals, detecting mates and offspring, choosing sites for egg-laying, recognizing territories and avoiding predators. Chemosensory responses are frequently modulated based on the internal environment of the organism. An organism’s internal environment undergoes regular changes in anticipation and in response to daily changes in its external environment, e.g., light-dark cycle. A resettable timekeeping mechanism called the circadian clock internally drives these cyclical changes with a ~24 hour period. Using electrophysiological, behavioral and molecular analyses, I tested where and how these two conserved processes, viz., the circadian timekeeping mechanism and the chemosensory pathway, intersect each other at organismal and cellular levels. The presence of autonomous peripheral oscillators in the chemosensory organs of Drosophila, prompted us to test whether chemosensory responses are under control of the circadian clock. I found that local oscillators in afferent (primary) chemosensory neurons drive rhythms in physiological and behavioral responses to attractive and aversive chemical signals. During the middle of the night, high level of G proteincoupled receptor kinase 2 (GPRK2), a clock controlled signaling molecule present in chemosensory neurons, suppresses tastant-evoked responses and promotes olfactory responses. G-protein mediated signaling was shown to be involved in generating optimal response to odorants. Multifunctional chemosensory clocks exert control on feeding and metabolism. I propose that temporal plasticity in innate behaviors should offer adaptive advantages to flies. Molneuro Chemosensation Circadian Rhythm Clock Feeding
4	Nutrient sensing mechanisms in the small intestine : localisation of taste molecules in mice and humans with and without diabetes. Sutherland, Kate January 2009 (has links) The mucosa of the small intestine is clearly able to discriminate specific chemical components of ingested meals to stimulate gastrointestinal feedback pathways and reduce further food intake. Luminal carbohydrates delay gastric emptying and initiate satiation, which are mediated by reflexes via the vagus nerve upon activation of vagal afferent endings in the mucosa. Nutrients activate these nerve fibres through intermediary epithelial cells, which release neuromediators upon transduction of luminal signals through the apical membrane. 5-hydroxytryptamine (5-HT) and glucagon-like peptide-1 (GLP-1) are released from enteroendocrine cells in response to luminal carbohydrates and both slow gastric emptying and inhibit food intake via vagal afferent pathways. The molecular mechanisms for carbohydrate detection and transduction leading to 5-HT and GLP-1 release are unknown. However molecules key to transduction of taste by receptor cells in the lingual epithelium are expressed in the gastrointestinal mucosa. The studies in this thesis aimed to investigate 1) the possibility that taste molecules expressed in the intestine form part of the carbohydrate sensing pathway that leads to 5-HT and GLP-1 release, which in turn activate mucosal vagal afferents and 2) to gauge any alterations in taste molecule expression that may relate to adaptation of carbohydrate-induced gastric motility reflexes that occurs in dietary and disease states. Firstly these studies show key taste molecules, including sweet taste receptors T1R2 and T1R3, the Gprotein gustducin (alpha-subunit Gαgust), and the taste transduction channel TRPM5, are expressed in the mouse gastrointestinal mucosa shown by RT-PCR and were further localised to individual epithelial ‘taste’ cells using immunohistochemistry. Quantification of transcript levels by real time RT-PCR revealed the proximal small intestine as the preferential site of sweet taste receptor expression along the gastrointestinal tract. This finding was also confirmed in humans using gastric and intestinal mucosal biopsies obtained at enteroscopy with significantly higher transcript expression levels in the small intestine compared to stomach. In the mouse, double label immunohistochemistry with Gα[subscript]gust antibody, as a marker of intestinal taste cells, was performed using lectin UEA-1, a marker of intestinal brush cells, and 5-HT or GLP-1 to link intestinal taste transduction to 5-HT and GLP-1 release. Results show Gα[subscript]gust is expressed within a subset of all three cell types in the small intestine but predominantly within UEA-1-expressing cells. Although Gα[subscript]gust, 5-HT and GLP-1 are largely expressed in mutually exclusive cells, within the jejunum a portion Gαgust positive cells coexpressed 5-HT or GLP-1. This Indicates a subpopulation of intestinal taste cells may be dedicated to carbohydrate-evoked gastrointestinal reflexes through 5-HT and GLP-1 mediated pathways, however, taste transduction within the small intestine appears to predominantly link to alternate mediators. After nutrient detection at the luminal surface, activation of mucosal afferents by 5-HT released from enterochromaffin cells is well documented, however although vagal afferents express GLP-1 receptors direct activation has not been demonstrated. For this purpose the effects of GLP-1 on gastrointestinal vagal afferents were investigated through single fibre recordings in in vitro tissue preparations. GLP-1 had no effect on the activity of mouse gastroesophageal vagal afferents but a rat duodenal preparation proved too problematic to be able to test GLP-1 specifically on duodenal vagal afferents. Altered gastric motility in response to carbohydrate meals due to prior dietary patterns and diabetes mellitus suggest adaptation in feedback mechanisms. Towards the second aim of this thesis taste molecule expression was quantified in fed and fasted mice by real time RT-PCR and revealed taste gene transcription is altered with the changing luminal environment, specifically transcription of taste genes was significantly decreased after feeding compared to the fasted state. Studies comparing expression in the duodenum of type 2 diabetics and non-diabetic controls show no significant difference in taste transcript levels between the two groups. However taste molecule expression was correlated to blood glucose levels in diabetics suggesting transcription of these signal molecules is adapted to both luminal and systemic carbohydrate levels. Findings in both the mouse and human gastrointestinal tract in terms of intestinal chemosensing are discussed. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1363582 / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Sciences, 2009
5	Nutrient sensing mechanisms in the small intestine : localisation of taste molecules in mice and humans with and without diabetes. Sutherland, Kate January 2009 (has links) The mucosa of the small intestine is clearly able to discriminate specific chemical components of ingested meals to stimulate gastrointestinal feedback pathways and reduce further food intake. Luminal carbohydrates delay gastric emptying and initiate satiation, which are mediated by reflexes via the vagus nerve upon activation of vagal afferent endings in the mucosa. Nutrients activate these nerve fibres through intermediary epithelial cells, which release neuromediators upon transduction of luminal signals through the apical membrane. 5-hydroxytryptamine (5-HT) and glucagon-like peptide-1 (GLP-1) are released from enteroendocrine cells in response to luminal carbohydrates and both slow gastric emptying and inhibit food intake via vagal afferent pathways. The molecular mechanisms for carbohydrate detection and transduction leading to 5-HT and GLP-1 release are unknown. However molecules key to transduction of taste by receptor cells in the lingual epithelium are expressed in the gastrointestinal mucosa. The studies in this thesis aimed to investigate 1) the possibility that taste molecules expressed in the intestine form part of the carbohydrate sensing pathway that leads to 5-HT and GLP-1 release, which in turn activate mucosal vagal afferents and 2) to gauge any alterations in taste molecule expression that may relate to adaptation of carbohydrate-induced gastric motility reflexes that occurs in dietary and disease states. Firstly these studies show key taste molecules, including sweet taste receptors T1R2 and T1R3, the Gprotein gustducin (alpha-subunit Gαgust), and the taste transduction channel TRPM5, are expressed in the mouse gastrointestinal mucosa shown by RT-PCR and were further localised to individual epithelial ‘taste’ cells using immunohistochemistry. Quantification of transcript levels by real time RT-PCR revealed the proximal small intestine as the preferential site of sweet taste receptor expression along the gastrointestinal tract. This finding was also confirmed in humans using gastric and intestinal mucosal biopsies obtained at enteroscopy with significantly higher transcript expression levels in the small intestine compared to stomach. In the mouse, double label immunohistochemistry with Gα[subscript]gust antibody, as a marker of intestinal taste cells, was performed using lectin UEA-1, a marker of intestinal brush cells, and 5-HT or GLP-1 to link intestinal taste transduction to 5-HT and GLP-1 release. Results show Gα[subscript]gust is expressed within a subset of all three cell types in the small intestine but predominantly within UEA-1-expressing cells. Although Gα[subscript]gust, 5-HT and GLP-1 are largely expressed in mutually exclusive cells, within the jejunum a portion Gαgust positive cells coexpressed 5-HT or GLP-1. This Indicates a subpopulation of intestinal taste cells may be dedicated to carbohydrate-evoked gastrointestinal reflexes through 5-HT and GLP-1 mediated pathways, however, taste transduction within the small intestine appears to predominantly link to alternate mediators. After nutrient detection at the luminal surface, activation of mucosal afferents by 5-HT released from enterochromaffin cells is well documented, however although vagal afferents express GLP-1 receptors direct activation has not been demonstrated. For this purpose the effects of GLP-1 on gastrointestinal vagal afferents were investigated through single fibre recordings in in vitro tissue preparations. GLP-1 had no effect on the activity of mouse gastroesophageal vagal afferents but a rat duodenal preparation proved too problematic to be able to test GLP-1 specifically on duodenal vagal afferents. Altered gastric motility in response to carbohydrate meals due to prior dietary patterns and diabetes mellitus suggest adaptation in feedback mechanisms. Towards the second aim of this thesis taste molecule expression was quantified in fed and fasted mice by real time RT-PCR and revealed taste gene transcription is altered with the changing luminal environment, specifically transcription of taste genes was significantly decreased after feeding compared to the fasted state. Studies comparing expression in the duodenum of type 2 diabetics and non-diabetic controls show no significant difference in taste transcript levels between the two groups. However taste molecule expression was correlated to blood glucose levels in diabetics suggesting transcription of these signal molecules is adapted to both luminal and systemic carbohydrate levels. Findings in both the mouse and human gastrointestinal tract in terms of intestinal chemosensing are discussed. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1363582 / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Sciences, 2009
6	Analysis of the Drosophila Sugar Receptor Genes Slone, Jesse David January 2009 (has links) <p>Gustation, also known as taste perception, is critical for the survival of most animal species. The fruit fly Drosophila melanogaster employs 68 different gustatory receptors (GRs) for the detection of sugars, bitter or toxic compounds, and pheromones. However, with a few notable exceptions, the functions of most GRs involved in feeding are unknown. Our research has focused on a cluster of highly-related Drosophila Grs, known as the Gr64 family, that have been shown to be critical for the perception of multiple sugars. Furthermore, we have demonstrated that another gene related to the Gr64 genes, Gr61a, is a sugar receptor that is narrowly tuned to a subset of pyranose sugars and may (along with the Gr64 genes) be indispensable for early fly development. </p><p>As a complementary approach to our behavioral analysis, we have examined the expression pattern of the Drosophila sugar receptors using knock-in driver alleles created by homologous recombination. As expected, most of these drivers have shown strong expression in various taste tissues. Intriguingly, some of these knock-in alleles also show expression in the maxillary palp and antenna, tissues previously thought to be involved only in olfaction. These expression patterns raise interesting questions about the true range of function of these chemosensory receptors and whether or not they might be involved in olfaction as well as gustation.</p> / Dissertation Biology, Genetics Biology, Neuroscience Biology, Entomology chemosensation Drosophila gustatory receptors sugar receptors taste
7	Evolution of the G protein-coupled receptor signaling system : Genomic and phylogenetic analyses Krishnan, Arunkumar January 2015 (has links) Signal transduction pathways mediated by G protein-coupled receptors (GPCRs) and their intracellular coupling partners, the heterotrimeric G proteins, are crucial for several physiological functions in eukaryotes, including humans. This thesis describes a broad genomic survey and extensive comparative phylogenetic analysis of GPCR and G protein families from a wide selection of eukaryotes. A robust mining of GPCR families in fungal genomes (Paper I) provides the first evidence that homologs of the mammalian families of GPCRs, including Rhodopsin, Adhesion, Glutamate and Frizzled are present in Fungi. These findings further support the hypothesis that all main GPCR families share a common origin. Moreover, we clarified the evolutionary hierarchy by showing for the first time that Rhodopsin family members are found outside metazoan lineages. We also characterized the GPCR superfamily in two important model organisms (Amphimedon queenslandica and Saccoglossus kowalevskii) that belong to different metazoan phyla and which differ greatly in morphological characteristics. Curation of the GPCR superfamily (Paper II) in Amphimedon queenslandica (an important model to understand evolution of animal multicellularity) reveals the presence of four of the five GRAFS families and several other GPCR gene families. However, we find that the sponge GPCR subset is divergent from GPCRs in other studied bilaterian and eumetazoan lineages. Mapping of the GPCR superfamily (Paper III) in a hemichordate Saccoglossus kowalevskii (an essential model to understand the evolution of the chordate body plan) revealed the presence of all major GPCR GRAFS families. We find that S. kowalevskii encodes local expansions of peptide and somatostatin- like GPCRs. Furthermore, we delineate the overall evolutionary hierarchy of vertebrate-like G protein families (Paper IV) and provide a comparative perspective with GPCR repertoires. The study also maps the individual gene gain/loss events of G proteins across holozoans with more expanded invertebrate taxon sampling than earlier reports. In addition, Paper V describes a broad survey of nematode chemosensory GPCR families and provides insights into the evolutionary events that shaped the GPCR mediated chemosensory system in protostomes. Overall, our findings further illustrate the evolutionary hierarchy and the diversity of the major components of the G protein-coupled receptor signaling system in eukaryotes. GPCRs G proteins Sensory system Signal transduction Olfaction Chemosensation Hemichordates Sponges Porifera Bilaterians Holozoans Fungi Opisthokonts
8	Maltooligosaccharide Chemosensation By Intestinal Enteroendocrine L-Cells Regulates the Endogenous Release of Gut Hormones and Contributes to Weight Management In Vivo Marwa Mohamed Mohamed El Hindawy (5929655) 14 January 2021 (has links) <p>As obesity has become one of the most prevalent metabolic diseases, and diabetes mellitus has become the seventh leading causes of death in the United States, alternative food/nutrition-based approaches to tackle obesity that are both efficacious and cost effective are in high demand. Since starch and its derived products are the principal dietary supply of glucose, strategies of using slowly digestible starch to achieve moderated glycemic response and prolonged glucose delivery, as well as to locationally digest starch into the ileum, have shown successful results such as moderation of insulinemia and reducing food intake in obese animals. An important regulator of appetite suppression is the neuroendocrine system of the gut-brain axis. Glucagon-like peptide-1 (GLP-1), oxyntomodulin (OXM), and peptide YY (PYY) are the main anorexigenic peptide products of the intestinal enterendocrine L-cells that regulate postprandial insulin levels as well as satiety signals. The stimulation of the enteroendocrine L-cells throughout the gastrointestinal tract through glucose, fatty acids and proteins has been extensively studied and confirmed. However, the stimulatory effect of complex dietary carbohydrates on L-cells is not described. In this dissertation, we investigated the <i>in vitro</i> intestinal cell chemosensation of L-cells to α-amylase starch digestion products, named maltooligosaccharides (MOS), and in the possible application of using slowly digestible starch delivery of MOS <i>in vivo</i>.</p> <p>In Chapter II of this dissertation, we reported a significantly higher stimulatory effect of MOS on GLP-1 and OXM secretion compared to glucose in mouse and human L-cells, respectively. Additionally, maltotriose enhanced the relative expression of the gastrointestinal peptide, cholecystokinin. Moreover, MOS exhibited protective effects on barrier function and monolayer integrity of intestinal epithelial cells. </p> <p>In Chapters III and IV, we performed a multiomics approach where transcriptomic analysis and global protein profiling of mouse L-cells treated with different types of MOS showed that the carbohydrates exhibit their effects through the induction of exocytosis of GLP-1- or OXM-containing vesicles and not through a positive regulation of the proglucagon gene expression. It is suggested that MOS induce higher secretion, but not higher synthesis, of the proglucagon gene products. In addition, maltotriose treatment downregulated the relative expression of the glucotoxicity marker, thioredoxin-interacting protein, and upregulated the relative expression of tight junction proteins supporting a role of MOS in barrier function integrity.</p> <p>Translating the <i>in vitro</i> findings into an <i>in vivo</i> application that is beneficial for human health required the use of controllable tool for the delivery of MOS throughout the small intestine for sensing by a higher number of L-cells. Slowly digestible starch (SDS), compared to rapidly digestible starch, provided such a tool. For this purpose, we used alginate-entrapped SDS microspheres that digest distally into the ileum to examine the role of SDS in the intervention and prevention of obesity in C57BL/6J diet-induced obese (DIO) and lean mice models.</p> <p>Results showed that 20% SDS in low-fat diets significantly improved weight loss and food intake reduction in DIO mice converted to low-fat diet for 12 weeks. Similarly, 15% SDS in high-fat diets showed significant reduction in body fat percent and significant increase in lean body mass as well as considerable reduction in weight gain rate and food intake in lean mice fed on 45% of calories high-fat diet. Immunohistochemistry of small intestine of mice in both the intervention and prevention studies revealed an even and thorough distribution of GLP-1 positive L-cells.</p> <p>Overall, this dissertation proposes several insights into L-cell sensation of dietary starch-degraded MOS delivered by the consumption of slowly digestible starch. MOS exhibit unique influences on L-cell sensitivity and gut hormone productivity. Future research investigating the mechanisms of intestinal sensing of MOS, as well as the development of bioactive carbohydrate structures that could preserve body weight and modulate glucose tolerance <i>in vivo</i> is needed to translate these findings into nutritional recommendations and food products beneficial for human health. The intricate role of dietary carbohydrates on gut physiological response, related to satiety and food intake could be a new approach for design of foods for health applications.</p> slowly digestible starch GLP-1 OXM L-cells Carbohydrate chemosensation
9	Function and Evolution of Putative Odorant Carriers in the Honey Bee (Apis mellifera) Foret, Sylvain, sylvain.foret@anu.edu.au January 2007 (has links) The remarkable olfactory power of insect species is thought to be generated by a combinatorial action of G-protein-coupled olfactory receptors (ORs) and olfactory carriers. Two such carrier gene families are found in insects: the odorant binding proteins (OBPs) and the chemosensory proteins (CSPs). In olfactory sensilla, OBPs and CSPs are believed to deliver hydrophobic air-borne molecules to ORs, but their expression in non-olfactory tissues suggests that they also may function as general carriers in other developmental and physiological processes. ¶ Bioinformatics and experimental approaches were used to characterise the OBP and CSP gene families in a highly social insect, the western honey bee (Apis mellifera). Comparison with other insects reveals that the honey bee has the smallest set of these genes, consisting of only 21 OBPs and 6 CSPs. These numbers stand in stark contrast to the 66 OBPs and 7 CSPs in the mosquito Anopheles gambiae and the 46 OBPs and 20 CSPs in the beetle Tribolium castaneum. The genes belonging to both families are often organised in clusters, and evolve by lineage specic expansions. Positive selection has been found to play a role in generating a greater sequence diversication in the OBP family in contrast to the CSP gene family that is more conserved, especially in the binding pocket. Expression proling under a wide range of conditions shows that, in the honey, bee only a minority of these genes are antenna-specic. The remaining genes are expressed either ubiquitously, or are tightly regulated in specialized tissues or during development. These findings support the view that OBPs and CSPs are not restricted to olfaction, and are likely to be involved in broader physiological functions. ¶ Finally, the detailed expression study and the functional characterization of a member of the CSP family, uth (unable-to-hatch), is reported. This gene is expressed in a maternal-zygotic fashion, and is restricted to the egg and embryo. Blocking the zygotic expression of uth with double-stranded RNA causes abnormalities in all body parts where this gene is highly expressed. The treated embryos are `unable-to-hatch' and cannot progress to the larval stages. Our ndings reveal a novel, essential role for this gene family and suggest that uth is an ectodermal gene involved in embryonic cuticle formation. Olfaction Odorant Binding Proteins OBP OBPs Chemosensory proteins CSP CSPs insects bee honeybee honey bee chemosensation embryonic development molecular evolution protein families
10	Neurological Responses to a Glucose Diet in Caenorhabditis elegans Dumesnil, Dennis 08 1900 (has links) TRPV channels play a role in both mammalian insulin signaling, with TRPV1 expression in pancreatic beta-cells, and in C. elegans insulin-like signaling through expression of OSM-9, OCR-1, and OCR-2 in stress response pathways. In response to a glucose-supplemented diet, C. elegans are know to have sensitivity to anoxic stress, exhibit chemotaxis attraction, and display reduced egg-laying rate. Transcriptome analysis reveals that glucose stimulates nervous system activity with increased transcript levels of genes regulating neurotransmitters. Ciliated sensory neurons are needed for a reduced egg-laying phenotype on a glucose-supplemented diet. Egg-laying rate is not affected when worms graze on glucose-supplemented Delta-PTS OP50 E. coli, which is defective in glucose uptake. This suggests a possible sensory neuron obstruction by exopolysaccharides produced by standard OP50 E. coli on glucose, eliciting a starvation response from the worm and causing reduced egg-laying rate. Glucose chemotaxis is affected in specific TRPV subunit allele mutants: ocr-2(vs29) and osm-9(yz6), serotonin receptor mutants: ser-1(ok345) and mod-1(ok103), and G-alpha protein mutant: gpa-10(pk362). TRPV deletion mutants had no effect on glucose chemotaxis, alluding to the modality role pf TRPV alleles in specific sensory neurons. The role of serotonin in a reduced egg-laying rate with glucose remains unclear. C. elegans Glucose Neuron Sensory, Chemosensation TRPV Transient Receptor Potential Vanilloid Egg-laying Exopolysaccharide Microbiome Glucose -- Physiological effect. TRP channels.

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