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The role of Lhx2 during organogenesis : analysis of the hepatic, hematopoietic and olfactory systems /Kolterud, Åsa, January 2004 (has links)
Diss. (sammanfattning) Umeå : Univ., 2004. / Härtill 4 uppsatser.
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Molecular and functional anatomy of the mouse olfactory epithelium /Vedin, Viktoria, January 2006 (has links)
Diss. (sammanfattning) Umeå : Umeå universitet, 2006. / Härtill 4 uppsatser.
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Odor processing and associative olfactory learning in the moth Manduca sexta. / 烟草天蛾嗅覺系統運作及氣味學習的原理研究 / CUHK electronic theses & dissertations collection / Yan cao tian e xiu jue xi tong yun zuo ji qi wei xue xi de yuan li yan jiuJanuary 2010 (has links)
Neural representations of odors get associated with other stimuli through experience. Are action potentials the neural representation that directly gets associated with reinforcement during conditioning? In Manduca , I found that odor presentations elicited only one or two spikes at odor onset (and sometimes offset) in each of a small portion of Kenyon cells, a population of neurons known to be crucial for olfactory associative learning. By using a series of odor-taste associative conditioning paradigms with various sucrose presentation timings, I carefully controlled the temporal overlap between Kenyon cell spiking and sucrose reinforcement timing. I found that in paradigms that led to learning, spiking in Kenyon cells ended well before the reinforcement was given. Further, increasing the temporal overlap between Kenyon cell spiking and sucrose reinforcement actually reduced learning efficacy. Therefore, spikes in Kenyon cells are not the neural representation that gets directly reinforced, and Hebbian spike timing--dependent plasticity in Kenyon cells alone cannot underlie this learning. / Two important focuses in neuroscience are to study how animals process sensory stimuli, and how such stimuli get associated with other sensory modalities through experience. Often, sensory stimuli elicit the oscillatory synchronization of neurons in different parts of the brain, and thus may constitute an important stage in sensory processing. Odor-evoked oscillatory synchronization has been observed in a wide variety of animals, including mammals and insects. Despite differences in details of anatomical structure, animals from widely different phyla appear to use similar strategies to encode odors. Here, using the moth Manduca sexta, I examined the factors that cause odor-evoked oscillatory synchronization of olfactory neurons and that determine the frequency of these oscillations. I found that frequency of oscillations decreased from ∼40 Hz to ∼20 Hz during the course of a lengthy odor pulse. This decrease in oscillatory frequency appeared in parallel with a decrease in net olfactory receptor output, suggesting that the intensity of olfactory receptor neuron input to the antennal lobe, the first olfactory relay center, may determine oscillatory frequency. However, I found that changing odor concentration had little effect on oscillatory frequency. Combining the results of recordings made in vivo and computational models, I found that increasing odor concentration recruited additional, but less well-tuned olfactory receptor neurons to respond to the odor. Firing rates of these neurons were tightly constrained by adaptation and saturation. My work established that, in the periphery, odor concentration is mainly encoded by the size of the olfactory receptor neuron population that responded to the odor, whereas oscillatory frequency is determined by the adaptation and saturation of this response. / Ong, Chik Ying Rose. / Advisers: Siu Kai Kong; Mark Stopfer. / Source: Dissertation Abstracts International, Volume: 72-04, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 132-147). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. Ann Arbor, MI : ProQuest Information and Learning Company, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.
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Regulation of adenylyl cyclases by CaM kinases : a possible role during signal desensitization in olfaction /Wei, Jia. January 1998 (has links)
Thesis (Ph. D.)--University of Washington, 1998. / Vita. Includes bibliographical references (leaves [115]-133).
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Role of the calcium-stimulated adenylyl cyclases in neuroplasticity /Wong, Scott Thaddeus. January 2000 (has links)
Thesis (Ph. D.)--University of Washington, 2000. / Vita. Includes bibliographical references (leaves 128-157).
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Information processing in the olfactory system of different amphibian speciesWeiss, Lukas 07 September 2020 (has links)
No description available.
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Developmental Strategy for Generating Sensory Neuron DiversityLi, Qingyun January 2015 (has links)
<p>Sensory neuron diversity is a common theme in the animal kingdom. It provides the cellular infrastructure that supports the accurate perception of the external world. Among all sensory systems, the olfactory system demonstrates an extreme in the extraordinarily diversified neuronal classes it holds. The system-wide cellular diversity is in sharp contrast with the individual specialization of olfactory receptor neurons (ORNs) per se. How the nervous system, particularly the olfactory system, uses limited genetic information to generate a huge variety of neurons with distinct properties remains elusive. </p><p>The adult Drosophila olfactory system is an excellent model to address this question due to its conserved organizational principles and reduced complexity. The fly olfactory appendages contain 50 ORN classes, each of which expresses a single receptor gene from a family of ~80 genes. Stereotyped clusters of 1-4 ORN classes define about 20 sensilla subtypes, belonging to 3 major morphological types. All cellular components within a sensillum are born by a single sensory organ precursor (SOP) via asymmetric divisions. The molecular mechanisms that determine SOP differentiation potentials to develop into distinct sensilla subtypes and the associated ORN classes are unknown.</p><p>From a genetic screen, we identified two mutant alleles in the rotund (rn) gene locus, which has a critical function in diversifying ORN classes. Rn is required in a subset of SOPs to confer novel sensilla subtype differentiation potentials from otherwise default ones within each sensilla type lineage. In rn mutants, ORNs in rn-positive sensilla subtypes are converted to lineage-specific default rn-negative fates, resulting in only half of the normal ORN diversity. This work is described in Chapter 2.</p><p>Based on an unbiased time-course transcriptome analysis, we discovered two critical downstream targets of Rn, Bric-à-brac (Bab) and Bar. In light of the knowledge about leg development, we found these genes, along with Apterous (Ap) and Dachshund (Dac), are part of the conserved proximal-distal (PD) gene network that play a crucial role in patterning the antennal precursor field prior to proneural gene-mediated SOP selection. Interactions between these PD genes under the influence of morphogen gradients separate the developing antennal disc into 7 concentric domains. Each ring is represented by a unique combination of the aforementioned transcription factors, coding the differentiation potentials for a limited number of sensilla subtypes. Genetic perturbations of the network lead to predictable changes in the ratios of different sensilla subtypes and corresponding ORN classes. In addition, using CRISPR/Cas9 technology, we were able to add tags to specific rn isoforms in the endogenous locus, and show positive regulation of Bab and negative regulation of Bar by the direct binding of Rn to the promoters in vivo. This work is presented in Chapter 3.</p><p>We proposed a three-step mechanism to explain ORN diversification, starting from pre-patterning of the precursor field by PD genes, followed by SOP selection by proneural genes, and ended with Notch-mediated neurogenesis. The final outcomes are greatly determined by the pre-patterning phase, which may be modified during evolution to compensate special olfactory needs by individual species. In our model, each step serves a single purpose, which displays context-dependent functions. By changing contexts, reassembly of the same logical steps may guide neuronal diversification in parallel systems with completely different identities. This step-wise mechanism seems to be a common strategy that is used by many other systems to generate neuronal diversity.</p> / Dissertation
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Neuroplasticity in olfactory sensation /Watt, William C. January 2003 (has links)
Thesis (Ph. D.)--University of Washington, 2003. / Vita. Includes bibliographical references (leaves 87-99).
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Investigação molecular e funcional de proteínas do Grupo Polycomb e seu envolvimento com a neurogênese olfatória / Molecular and functional investigation of Polycomb Group proteins and their involvement in olfactory neurogenesisSouza, Mateus Augusto de Andrade, 1989- 03 December 2015 (has links)
Orientador: Fabio Papes / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-27T05:41:39Z (GMT). No. of bitstreams: 1
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Previous issue date: 2015 / Resumo: Em mamíferos, os neurônios sensoriais do Sistema Olfatório (OSNs) se encontram no interior da cavidade nasal, mas estão diretamente expostos ao ambiente externo. Por um lado, tal localização permite a esses neurônios o acesso imediato aos estímulos químicos ambientais, tomando vantagem do fluxo respiratório. Por outro lado, esses neurônios estão constantemente sujeitos a injúrias por agentes nocivos, como toxinas e patógenos, capazes de destruir essas células sensoriais. Sua perda constante, contudo, é contrabalanceada pela geração de novos OSNs durante toda a vida do indivíduo, fato que torna o Sistema Olfatório um dos poucos locais do organismo com neurogênese contínua na idade adulta. A regeneração dos OSNs tem atraído a atenção da comunidade científica tanto pelo seu potencial uso como modelo de estudo do Sistema Nervoso quanto pela sua potencial aplicação para o tratamento de doenças neurodegenerativas. Nesse sentido, muito conhecimento já foi produzido sobre a dinâmica de fatores de transcrição que acompanha a diferenciação dos progenitores neuronais olfatórios em OSNs. Porém, uma grande lacuna no conhecimento diz respeito a outros elementos capazes de coordenar esse processo, como os fatores moduladores da cromatina. Diante desse cenário, escolhemos como objeto de estudo as proteínas do Grupo Polycomb (PcG), que constituem uma maquinaria de controle transcricional relacionada a modificações na organização da cromatina. Neste trabalho, genes PcG selecionados foram caracterizados molecular e funcionalmente no epitélio olfatório principal de camundongos (MOE). Através de ensaios de hibridação in situ, cinco dos seis genes avaliados apresentaram expressão ubíqua por todo o epitélio (Cbx2, Cbx4, Phc2, Ezh1, Bcl6), enquanto um (Ezh2) mostrou-se expresso somente nos estratos basais do MOE. Em ensaios de colocalização, provamos que Ezh2 é expresso exclusivamente nos progenitores olfatórios, onde o processo de diferenciação se inicia, e em parte dos OSNs recém-diferenciados, ainda não funcionais. Esta foi a primeira vez que a expressão de um gene PcG foi analisada detalhadamente no Sistema Olfatório. O interessante perfil de expressão de Ezh2 foi sugestivo de um possível papel funcional relacionado à diferenciação dos progenitores olfatórios. Para investigar essa hipótese, utilizamos como ferramenta experimental a habilidade do MOE em se regenerar após a indução de injúrias específicas. Para isso, o MOE de camundongos foi lesionado quimicamente com o composto diclobenil, que leva à perda abrupta de OSNs, estimulando a proliferação e a diferenciação dos progenitores olfatórios para repovoar as regiões lesionadas. Os animais assim tratados receberam, por via intranasal, o fármaco GSK126, uma molécula inibidora específica da atividade da proteína EZH2. Acompanhando a regeneração subsequente do MOE, observamos que a inibição da atividade de EZH2 levou ao incremento de OSNs no epitélio, favorecendo a sua regeneração. Interessantemente, esse incremento também foi observado em MOEs não lesionados, mostrando que o efeito de GSK126 não é dependente da indução de injúrias prévias. Através dessa investigação molecular e funcional, buscamos contribuir para o melhor entendimento da diferenciação neuronal do MOE, e apontamos as proteína PcG como elementos importantes para esse processo / Abstract: In mammals, the olfactory sensory neurons (OSNs) are located inside the nasal cavity, but they are directly exposed to the external environment. Taking advantage of the respiratory flux, this location favors the access to the chemical stimuli presented by the environment. On the other hand, it leads OSNs to be continually damaged by pathogens and toxic substances carried by the inhaled air. However, the persistence of neuronal progenitors in the olfactory epithelium makes the constant reposition of the OSNs possible. This unique ability of regeneration makes the Olfactory System one of the few sites of neurogenesis throughout the adult life. Olfactory regeneration has attracted the attention scientific community because of its potential as a model of study of the Nervous System and application in the treatment of neurodegenerative diseases. A great amount of knowledge has been accumulated about the transcription factor dynamics that follows the differentiation of neuronal progenitors into OSNs. However, there is a great gap about other elements that could coordinate this process, such as chromatin modulator factors. In this scenario, we decided to study the Polycomb Group (PcG) proteins, a transcription control machinery involved in chromatin structure organization. In the present study, selected PcG genes were molecular and functionally analyzed in the mouse main olfactory epithelium (MOE). Using in situ hybridization assays, we characterized the expression of six PcG genes. Five of them were shown to be expressed throughout the MOE (Cbx2, Cbx4, Phc2, Ezh1, Bcl6), while one (Ezh2) was found only in the basal layers of this epithelium. Using colocalization strategies, we proved that Ezh2 gene is expressed exclusively in the olfactory progenitor cells, where the differentiation process begins, and in part of the newly differentiated OSNs that are still not functional. It was the first time that a PcG gene expression profile was finely analyzed in the Olfactory System. This interesting expression profile presented by Ezh2 suggested a possible involvement with the MOE neuronal progenitor differentiation. For this functional investigation, we used MOE¿s neuronal regeneration after specific injuries as an experimental tool. For this purpose, the MOE was chemically damaged by the compound dichlobenil, which causes a great loss of OSNs, stimulating proliferation and differentiation of neuronal progenitor cells, leading to the repopulation of the damaged tissue. Next, mice received by intranasal route the pharmacological inhibitor GSK126, which blocks EZH2 protein activity. The observation of the MOE regeneration that followed showed us that GSK126 application resulted in an increased number of OSNs, improving MOE regeneration. Interestingly, this increase was also found in intact MOEs, pointing that GSK126¿s effects do not depend on previous olfactory injuries. By this molecular and functional investigation, we aimed at a better understanding of olfactory neuronal differentiation, and we targeted the PcG proteins as relevant elements to this process / Mestrado / Genetica Animal e Evolução / Mestre em Genética e Biologia Molecular
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Olfactory Training in Patients with Parkinson's DiseaseHähner, Antje, Tosch, Clara, Wolz, Martin, Klingelhöfer, Lisa, Fauser, Mareike, Storch, Alexander, Reichmann, Heinz, Hummel, Thomas 22 January 2014 (has links) (PDF)
Objective: Decrease of olfactory function in Parkinson's disease (PD) is a well-investigated fact. Studies indicate that pharmacological treatment of PD fails to restore olfactory function in PD patients. The aim of this investigation was whether patients with PD would benefit from “training” with odors in terms of an improvement of their general olfactory function. It has been hypothesized that olfactory training should produce both an improved sensitivity towards the odors used in the training process and an overall increase of olfactory function.
Methods: We recruited 70 subjects with PD and olfactory loss into this single-center, prospective, controlled non-blinded study. Thirty-five patients were assigned to the olfactory training group and 35 subjects to the control group (no training). Olfactory training was performed over a period of 12 weeks while patients exposed themselves twice daily to four odors (phenyl ethyl alcohol: rose, eucalyptol: eucalyptus, citronellal: lemon, and eugenol: cloves). Olfactory testing was performed before and after training using the “Sniffin' Sticks” (thresholds for phenyl ethyl alcohol, tests for odor discrimination, and odor identification) in addition to threshold tests for the odors used in the training process.
Results: Compared to baseline, trained PD patients experienced a significant increase in their olfactory function, which was observed for the Sniffin' Sticks test score and for thresholds for the odors used in the training process. Olfactory function was unchanged in PD patients who did not perform olfactory training.
Conclusion: The present results indicate that olfactory training may increase olfactory sensitivity in PD patients.
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