Global ETD Search

31	Role of neuropeptide Y and its receptor analogues in focal cerebral ischemia in the rat Chen, Shaohua, 陳韶華 January 2002 (has links) published_or_final_version / Medicine / Doctoral / Doctor of Philosophy Neuropeptide Y Cerebral ischemia. Rats - Physiology.
32	Regulation of gene expression and survival by neurotrophic factors Williams, Alan January 1998 (has links) No description available. 572
33	Calcium signalling in a fluid transporting epithelium MacPherson, Matthew January 2001 (has links) No description available. 572.8
34	The Regulation of Expression of Hemokinin-1 Tran, Anne H. 23 February 2010 (has links) The regulation of the immune system is complex, with many factors involved in controlling immune cell development, activation and homeostasis. These factors include neuropeptides as well as classic immunoregulatory molecules such as cytokines, chemokines and hormones. Neuropeptides and tachykinins in particular are known to be involved in immune response modulation through a cascade of events including vasodilation, plasma extravasation, the activation of immune cells, the secretion of pro-inflammatory cytokines and the recruitment of more immune cells. Furthermore, there is growing evidence that tachykinins play a role in hematopoiesis with Substance P as the proposed effector molecule. In 2000, our lab discovered a new tachykinin with remarkable structural similarity to SP and SP-like neurokinin receptor binding affinity. This molecule was designated Hemokinin-1 due to its expression in hematopoietic cells and its function in B cell development. Further gene expression analysis of HK-1 reveals a wide expression pattern although HK-1 transcripts are found predominantly in peripheral tissues while SP is mainly expressed in neuronal tissue. Based on this differential expression pattern, it has been suggested that HK-1 may act as the peripheral tachykinin and may have functions distinct from SP. In addition, given the crossreactivity of the SP antibodies to HK-1, it is important to determine whether HK-1 is the actual mediator of some functions previously attributed to SP. In this thesis, we examine the differential expression pattern of HK-1 to determine molecular mechanisms of regulation of HK-1 transcription and ultimately provide clues to its function in the immune system. In our analysis of the HK-1 promoter, we found a major difference in the basic transcriptional control of HK-1 and SP at the level of transcription initiation and identified several transcription factors including CREB and NFκB involved in regulating TAC4 gene expression in immune cells. Data presented in this thesis also reveal that the HK-1 gene is a direct target of Early B-cell Factor, a transcription factor known to activate B cell-specific genes as well as genes involved in adipogenesis and neuronal development. Our results show EBF regulates HK-1 gene expression in differentiating B cells as well as a monocytic cell line. Our data indicate EBF may also be responsible for the high levels of HK-1 transcript in the olfactory epithelium, suggesting a bridge between the nervous system and the immune system. Tachykinin Neuropeptide Neuroimmunology Transcription Promoter Expression 0982
35	The role of the neuropeptides NPF, sNPF, ITP and PDF in the circadian clock of Drosophila melanogaster / Die Rolle der Neuropeptide NPF, sNPF, ITP und PDF in der circadianen Uhr von Drosophila melanogaster Luibl [née Hermann], Christiane January 2014 (has links) (PDF) Organisms have evolved endogenous clocks which allow them to organize their behavior, metabolism and physiology according to the periodically changing environmental conditions on earth. Biological rhythms that are synchronized to daily changes in environment are governed by the so-called circadian clock. Since decades, chronobiologists have been investigating circadian clocks in various model organisms including the fruitfly Drosophila melanogaster, which was used in the present thesis. Anatomically, the circadian clock of the fruitfly consists of about 150 neurons in the lateral and dorsal protocerebrum, which are characterized by their position, morphology and neurochemistry. Some of these neurons had been previously shown to contain either one or several neuropeptides, which are thought to be the main signaling molecules used by the clock. The best investigated of these neuropeptides is the Pigment Dispersing Factor (PDF), which had been shown to constitute a synchronizing signal between clock neurons as well as an output factor of the clock. In collaboration with various coworkers, I investigated the roles of three other clock expressed neuropeptides for the generation of behavioral rhythms and the partly published, partly unpublished data are presented in this thesis. Thereby, I focused on the Neuropeptide F (NPF), short Neuropeptide F (sNPF) and the Ion Transport Peptide (ITP). We show that part of the neuropeptide composition within the clock network seems to be conserved among different Drosophila species. However, the PDF expression pattern in certain neurons varied in species deriving from lower latitudes compared to higher latitudes. Together with findings on the behavioral level provided by other people, these data suggest that different species may have altered certain properties of their clocks - like the neuropeptide expression in certain neurons - in order to adapt their behavior to different habitats. We then investigated locomotor rhythms in Drosophila melanogaster flies, in which neuropeptide circuits were genetically manipulated either by cell ablation or RNA interference (RNAi). We found that none of the investigated neuropeptides seems to be of equal importance for circadian locomotor rhythms as PDF. PDF had been previously shown to be necessary for rhythm maintenance in constant darkness (DD) as well as for the generation of morning (M) activity and for the right phasing of the evening (E) activity in entrained conditions. We now demonstrate that NPF and ITP seem to promote E activity in entrained conditions, but are clearly not the only factors doing so. In addition, ITP seems to reduce nighttime activity. Further, ITP and possibly also sNPF constitute weak period shortening components in DD, thereby opposing the effect of PDF. However, neither NPF or ITP, nor sNPF seem to be necessary in the clock neurons for maintaining rhythmicity in DD. It had been previously suggested that PDF is released rhythmically from the dorsal projection terminals. Now we discovered a rhythm in ITP immunostaining in the dorsal projection terminals of the ITP+ clock neurons in LD, suggesting a rhythm in peptide release also in the case of ITP. Rhythmic release of both ITP and PDF seems to be important to maintain rhythmic behavior in DD, since constantly high levels of PDF and ITP in the dorsal protocerebrum lead to behavioral arrhythmicity. Applying live-imaging techniques we further demonstrate that sNPF acts in an inhibitory way on few clock neurons, including some that are also activated by PDF, suggesting that it acts as signaling molecule within the clock network and has opposing effects to PDF. NPF did only evoke very little inhibitory responses in very few clock neurons, suggesting that it might rather be used as a clock output factor. We were not able to apply the same live-imaging approach for the investigation of the clock neuron responsiveness to ITP, but overexpression of ITP with various driver lines showed that the peptide most likely acts mainly in clock output pathways rather than inter-clock neuron communication. Taking together, I conclude that all investigated peptides contribute to the control of locomotor rhythms in the fruitfly Drosophila melanogaster. However, this control is in most aspects dominated by the actions of PDF and rather only fine-tuned or complemented by the other peptides. I assume that there is a high complexity in spatial and temporal action of the different neuropeptides in order to ensure correct signal processing within the clock network as well as clock output. / Die meisten Organismen haben endogene Uhren entwickelt, mit deren Hilfe sie ihre Verhaltensweisen, ihren Metabolismus und auch ihre Physiologie an die periodisch wechselnden Umweltbedingungen auf unserer Erde anpassen können. Die sogenannten circadianen Uhren steuern dabei biologische Rhythmen, die an täglich wiederkehrende Umweltfaktoren angepasst sind. Schon seit Jahrzehnten wurden diese circadianen Uhren von Chronobiologen in verschiedensten Modellorganismen untersucht. Zu diesen gehört auch die Taufliege Drosophila melanogaster, welche im Rahmen dieser Doktorarbeit Verwendung fand. Anatomisch besteht die circadiane Uhr der Taufliege aus etwa 150 sogenannten Uhrneuronen, die sich im dorsalen und lateralen Protocerebrum der Fliege befinden. Diese können anhand ihrer Position im Gehirn, ihrer Morphologie als auch ihrer neurochemischen Eigenschaften charakterisiert werden. Es wurde bereits in früheren Arbeiten gezeigt, dass einige dieser Uhrneuronen jeweils ein oder mehrere Neuropeptide exprimieren, welche mit großer Wahrscheinlichkeit die wichtigsten Signalmoleküle der Uhr darstellen. Dabei ist der „Pigment Dispersing Factor“ (PDF) wohl das Neuropeptid, welches bisher in Bezug auf seine Funktion in der Uhr die größte Aufmerksamkeit fand. Es ist daher auch das Neuropeptid, das bei Weitem am besten untersucht ist. So wurde bereits gezeigt, dass PDF die Oszillationen der Uhrneuronen untereinander synchronisiert und auch in Ausgangssignalwegen der Uhr zu nachgeschalteten Gehirnregionen eine Rolle spielt. In Zusammenarbeit mit verschiedenen Kollegen, wurde im Rahmen dieser Doktorarbeit untersucht, welche Rolle drei andere Neuropeptide, welche in den Uhrneuronen exprimiert werden, in der Generierung von Verhaltensrhythmen spielen. Der Fokus lag dabei auf der Untersuchung des Neuropeptids F (NPF) des short Neuropeptids F (sNPF) und des Ion Transport Peptids (ITP). Wir konnten für manche dieser Peptide zeigen, dass ihre Verwendung im Uhrnetzwerk unterschiedlicher Drosophila-Arten konserviert zu sein scheint. Im Falle von PDF zeigten sich jedoch Unterschiede in der zellspezifischen Expression in Arten aus südlichen Breitengraden im Vergleich zu Arten aus nördlichen Breitengraden. Zusammen mit ergänzenden Verhaltensdaten anderer Arbeitsgruppen, gehen wir davon aus, dass unterschiedliche Arten bestimmte Eigenschaften ihrer Uhr – wie etwa die Neuropeptid-Expression in bestimmten Zellen – verändert haben, um ihr Verhalten bestmöglich an ihr jeweiliges Habitat anzupassen. Des Weiteren wurde in dieser Arbeit die Aktivitätsrhythmik in Fliegen untersucht, in welchen gezielt bestimmte Neuropeptid-Systeme auf genetischem Wege - entweder durch Zellablation oder RNA-Interferenz (RNAi) - manipuliert wurden. Wir konnten zeigen, dass wohl keines der untersuchten Peptide eine ähnlich große Rolle für die Aktivitätsrhythmik spielt wie PDF. Aus früheren Arbeiten geht hervor, dass PDF sowohl für die Aufrechterhaltung eines Rhythmus in konstanter Dunkelheit (DD), als auch für die Generierung der Morgenaktivität und für die richtige Phasenlage der Abendaktivität in Licht-Dunkel Zyklen (LD) essentiell ist. Ergebnisse der vorliegenden Arbeit zeigen nun, dass NPF und ITP die Abendaktivität in LD fördern, dass sie jedoch nicht die einzigen Faktoren sind, die dies bewerkstelligen. ITP scheint außerdem Aktivität während der Nacht zu hemmen. Des Weiteren stellen ITP und möglicherweise auch sNPF eine schwache Perioden verkürzende Komponente in DD dar, ganz im Gegensatz zu PDF, welches eine Perioden verlängernde Wirkung besitzt. Jedoch scheinen weder ITP, NPF noch sNPF für die generelle Aufrechterhaltung eines Rhythmus in DD nötig zu sein. Vorhergehende Arbeiten wiesen bereits darauf hin, dass PDF wahrscheinlich rhythmisch an den dorsalen Nervenendigungen ausgeschüttet wird. Unsere jetzigen Ergebnisse zeigen desweiteren eine Oszillation in der ITP-Immunfärbung in den dorsalen Projektionen der ITP+ Uhrneuronen in LD, was auch auf eine rhythmische Ausschüttung dieses Peptids schließen lässt. Die rhythmische Freisetzung beider Peptide scheint für die Aufrechterhaltung eines Verhaltensrhythmus in DD wichtig zu sein, da eine konstant hohe Menge an ITP und PDF im dorsalen Gehirn den Freilauf-Rhythmus störten. Die live-Imaging Experimente dieser Arbeit zeigten, dass sNPF auf manche Uhrneuronen inhibitorisch wirkt – auch auf einige, die durch PDF aktiviert werden können. sNPF könnte also als Signalmolekül innerhalb des Uhrnetzwerkes fungieren. Auch NPF führte zu inhibitorischen Zellantworten, jedoch waren diese äußerst schwach und betrafen nur wenige Uhrneuronen, was darauf schließen lässt, dass dieses Peptid wahrscheinlich am Signalausgang der Uhr beteiligt ist. Es war uns bisher nicht möglich dieselben live-Imaging Untersuchungen auch für ITP durchzuführen, jedoch zeigten Überexpressionsstudien mit verschiedenen Treiberlinien, dass auch ITP mit großer Wahrscheinlichkeit im Signalausgang der Uhr fungiert. Zusammenfassend lässt sich sagen, dass alle hier untersuchten Neuropeptide an der Kontrolle der rhythmischen Lokomotoraktivität von Drosophila melanogaster mitwirken. Dabei ist PDF eindeutig der dominierende Faktor, während die anderen Neuropeptide die Wirkung von PDF eher feinregulieren oder komplementieren. Aus den Daten kann geschlossen werden, dass die örtliche und zeitliche Funktionsweise dieser verschiedenen Peptide sehr komplex ist, um sowohl die Prozessierung von Signalen innerhalb des Uhrnetzwerkes als auch in den weitgehend noch unbekannten Ausgangswegen der Uhr zu gewährleisten. Taufliege Biologische Uhr Neuropeptide ddc:570
36	The characterization, functional expression, and localization of the first arthropod myokinin receptor from the southern cattle tick, Boophilus microplus (Acari: ixodidae) Holmes, Steven P. 30 September 2004 (has links) Myokinins are invertebrate neuropeptides with myotropic and diuretic activity. The lymnokinin receptor from the snail Lymnaea stagnalis was the only previously identified myokinin receptor. A cDNA encoding a neuropeptide receptor was cloned from the southern cattle tick, Boophilus microplus. The deduced amino acid sequence was 40 % identical to the lymnokinin receptor. The receptor transcript is present in all tick life stages as determined by semiquantitative RT-PCR. When expressed in mammalian CHO-K1 cells, myokinins at nanomolar concentrations induced increases in intracellular calcium as measured by fluorescent cytometry. The rank order of potency for peptides tested was FFFSWS-NH2≥FFFSWG-NH2≥FFSWG-NH2>FYSWG-NH2>muscakinin>lymnokinin>>APTGFFGVR-NH2. The receptor coupled to a pertussis toxin insensitive G protein. Absence of extracellular calcium did not inhibit the calcium response, indicating the release of Ca2+ from intracellular stores. Receptor transcript was detected by RT-PCR in the dissected synganglia, ovaries, salivary glands, guts and Malpighian tubules of partially engorged adult female ticks. It is concluded that the B. microplus receptor is the first myokinin receptor cloned from an arthropod, and the first neuropeptide receptor known from the Acari. The presence of this receptor transcript in multiple tissues and all life stages suggests a multifunctional role in ticks. Boophilus microplus GPCR neuropeptide receptor myokinin
37	The Regulation of Sleep and Wakefulness by the Hypothalamic Neuropeptide Orexin/Hypocretin YAMANAKA, AKIHIRO, INUTSUKA, AYUMU 02 1900 (has links) No description available. neuropeptide optogenetics hypothalamus sleep orexin/hypocretin
38	Influence of Nutrition during the Juvenile Period on Gene Expression Within the Hypothalamic Arcuate Nucleus and on Age at Puberty in Heifers Allen, Carolyn C. 2010 August 1900 (has links) Developmental changes within the hypothalamus are necessary for maturation of the reproductive neuroendocrine axis. Recent reports have implicated several neuronal networks in this process, but genes involved in their regulation have not been elucidated. Using a well-established model for nutritional induction of precocious puberty, objectives were to 1) use microarray technology to examine changes in gene expression within the arcuate nucleus (ARC) of the hypothalamus in pre-pubertal heifers fed high or low-concentrate diets, and 2) determine if high-concentrate diets are required for nutritional induction of precocious puberty. In Experiment 1, early-weaned, cross-bred heifers were fed either a high-forage/low-gain (HF/LG; 0.45 kg/d) or a highconcentrate/ high-gain (HC/HG; 0.91 kg/d) diet for 91 d. Analysis of microarray data indicated that 346 genes were differentially expressed (P < 0.05) between HC/HG and HF/LG heifers. Expression of three key metabolic genes [neuropeptide Y (NPY), agoutirelated protein (AGRP), and growth hormone receptor (GHR)] observed to be differentially expressed in the microarray analysis was investigated further by quantitative PCR. Real-time RT-PCR indicated that expression of NPY, AGRP and GHR was lower (P < 0.05) in HC/HG compared to HF/LG heifers. In contrast, concentrations of insulin (P < 0.05), IGF-1 (P < 0.002) and leptin (P = 0.1) were greater in HC/HG compared to HF/LG. For Experiment 2, 48 heifers were used in 2 replicates (24 heifers/replicate) in a 2 x 2 factorial design to examine the roles of diet type (HF vs HC) and rate of gain (LG, 0.45 kg/d vs HG, 0.91 kg/d) on age at puberty. Heifers were fed HC/HG, HC/LG, HF/HG or HF/LG (n = 12/group) for 14 wk, and then switched to a common growth diet (0.68 kg/d) until puberty. Heifers in both HG groups reached puberty at a younger age (54.5 ± 1.8 wk) than heifers in both LG groups (60.2 ± 1.9 wk; P < 0.04). A marked increase (P < 0.01) in serum concentrations of leptin occurred in HC/HG heifers between 24 and 30 wk of age. This increase in circulating leptin was not observed in other groups. Overall, results indicate that nutritional regulation of reproductive neuroendocrine development involves the control of NPY, AGRP and GHR expression. The abrupt increase noted for circulating leptin in heifers fed HC/HG diets, if timed and sustained appropriately, could represent an important temporal cue for activation of the neuroendocrine system and the onset of puberty. Puberty Arcuate Nucleus Heifers Neuropeptide Y Leptin
39	Regulation of Neuropeptide Y and GnRH Receptor Gene Expression by Sex Steroids and GnRH in Orange-Spotted Grouper, Epinephelus coioides Wu, Chung-lin 04 February 2005 (has links) The aim of the present research was to investigate the expression profiles of GnRH-R and neuropeptide Y (NPY) genes in brain and pituitary of Orange-spotted Grouper, Epinephelus coioides and also to understand the regulatory mechanism by administering different sex steroids. GnRH-R (TMD2 to TMD6) was partially involved cloned in this study. Tissue distribution analysis revealed a significant expression of GnRH-R in pituitary compared to others tissues. The expression of GnRH-R in brain and pituitary of groupers at different ages showed a significant increased during the fourth year, probably indicating the time of maturation. However, there was no significant difference in the expression of GnRH-R during different seasons. Treatment of two and three year old groupers with different sex steroids revealed an increase in the expression of GnRH-R in pituitary by E2 in both the age groups tested, while T could induce the expression of GnRH-R only in three year old groupers. The result, thus, indicates that the sensitivity of grouper to sex steroid is dependent on the age and the kind of steroid adminstered. In different sections of brain, the GnRH-R expression was in general lower in the group treated with E2 or T compared to the control group. The expression of the gene was more or less the same in two year and three year old control groups. This result may have been caused by suppression of GnRH-R expression in forebrain and midbrain after sex steroid injection. Administration of T induced a significant increase in the expression of GnRH-R in forebrain and midbrain, while E2 treatment did not have a similar effect. In hindbrain, the expression profile GnRH-R was not affected by sex steroid treatment in both two year and three year old groupers. The results suggest that sex steroids can only regulate the expression of GnRH-R in the forebrain and midbrain, probably due to the wide distribution of steroid¡¦s receptor in these regions. LHRH and pimozide injections to two year old groupers showed an increase in the expression of GnRH-R in pituitary after LHRH treatment while there was no stimulatory effect on other sections of the brain. In contrast, treating the fish with pimozide alone or pimozide together with LHRH did not stimulate GnRH-R expression in brain. Thus, the study suggests that LHRH can significantly increase the expression of GnRH-R in pituitary while dopamine has no stimulatory effect. Studies on NPY showed that the gene was distributed in different sections of brain especially in the forebrain but it was also present in gills, liver, intestine ¡K etc. The presence of NPY in gills, though less compared to that in brain, suggests that NPY might play an important role in osmosis regulation. The expression of NPY decreased with increase in age which may be due to the effect of other regulatory factors. Treatment of two and three year old groupers with different sex steroids did not effect the expression of NPY significantly in brain, which is different from other published reports. This may be due to the difference in the zoning of brain regions. In the present study, forebrain and midbrain were sampled together for analyses. The expression of NPY in brain did not change by treating the fish with LHRH or pimozide. GnRH receptor Epinephelus coioides neuropeptide Y
40	Leptin and neuropeptide Y as a link between body fat, fertility and appetite in ruminants / Morrison, Christopher D. January 2001 (has links) Thesis (Ph. D.)--University of Missouri-Columbia, 2001. / Typescript. Vita. Includes bibliographical references (leaves 125-162). Also available on the Internet.

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