Global ETD Search

391	Etablierung und Charakterisierung primärer equiner Trachealepithelzellen: Ein in vitro-Modell zur Untersuchung der Expression und Funktion pulmonaler beta-adrenerger Rezeptoren Shibeshi Alemayehu, Workineh 17 November 2009 (has links) Die Kultivierung equiner Trachealepithelzellen stellt ein nützliches Modell dar, die (patho)-physiologischen Mechanismen der obstruktiven Atemwegserkrankungen des Pferdes auf zellulärer Ebene zu untersuchen. Ziel dieser Arbeit war es, Methoden für die Isolation, Charakterisierung und weitergehende Kultivierung equiner Trachealepithelzellen (ETEZ) zu etablieren und validieren und die Expression und Funktionalität der beta-adrenergen Rezeptoren an frisch isolierten ETEZ und deren Primärkulturen mittels pharmakologischer und biochemischer Verfahrenstechniken zu analysieren. Epithelzellen wurden durch Trypsinverdau aus der Trachea gesunder Pferde gewonnen, indem zuerst die Mukosa der Trachea freigelegt und diese dann vom daruntergelegenen Bindegewebe stumpf getrennt wurde. Das gewonnene Gewebe wurde zerkleinert und enzymatisch mit 0,25% Trypsin-EDTA-Lösung für 2 h bei 37°C verdaut. Durch Siebung und Zentrifugation wurden die Zellen gereinigt, vereinzelt und gesammelt, wobei kontaminierende Fibroblasten später durch differentielle Adhäsion von den Epithelzellen getrennt wurden. Die isolierten Zellen wurden sowohl licht- bzw. elektronenmikroskopisch charakterisiert, als auch immunzytochemisch hinsichtlich Zytokeratin (für Epithelzellen) und Vimentin (für Fibroblasten) gefärbt. Die durchschnittliche Zellausbeute wurde mit der Neubauer-Zählkammer bestimmt und betrug 6,10 ± 0,63×106 Zellen pro 500 mg zerkleinertem Gewebe (n = 11). Die Zellvitalität wurde mittels Trypanblau-Färbung ermittelt und betrug 94,70 ± 1,17% (n = 11). Immunfluoreszensfärbungen zeigten, dass 93,57 ± 1,67% (n = 11) der frisch isolierten Zellen und ca. 100% (n = 5) der Primärkulturen auf Zytokeratin 5/6/18 positiv reagierten. Auf Anti-Vimentin reagierten dagegen nur 9,83 ± 0,94% (n = 11) der Zellen positiv. Die Zellen wurden in einer Dichte von 6,90 x 104 Zellen/cm2 in serumfreiem AECGM ausgesät und bildeten innerhalb einer Woche einen konfluenten Monolayer. Die konfluenten Zellen wurden mittels Dispase II abgelöst. Die erste (P1) und die zweite (P2) Passage konnte erfolgreich in serumfreien AECGM kultiviert und auf der Stufe P2 30 Tage lang gehalten werden. Weitethin wurden die Expression und Funktionalität der b-adrenergen Rezeptoren in frisch isolierten und kultivierten Epithelzellen untersucht. Mittels Radioligandenbindungsstudien, Westernblot, Immunfluoreszensfärbung und cAMP-Assays konnten erstmalig die Dichte, Affinität, Subtypen, Proteinexpression und zelluläre Lokalisation der beta-adrenergen Rezeptoren sowie die Rezeptorfunktion bestimmt werden. Messungen an frisch isolierten ETEZ ergaben für die mittlere Dissoziationskonstante (KD) von 31,78 ± 6,57 pM (n = 7) und eine maximale b-adrenerge Rezeptordichte (BMax) von 12727 ± 883,6 Bindungsstellen/Zelle (n = 7) ermittelt aus Sättigungsexperimenten mit dem b-adrenergen Rezeptorantagonisten [125I] Iodocyanopindolol (ICYP) in Anwesenheit des nicht selektiven beta-Rezeptorantagonisten (±)-CGP 12177. Für Primärkulturen ergaben sich Werte für KD von 15,26 ± 3,37 pM (n =6) und für BMax von 3730 ± 212 Bindungsstellen/Zelle (n = 6). Bei Verdrängungsexperimenten wurde die ICYP konzentrationsabhängig durch den beta2-selektiven Rezeptorantagonisten ICI 118.551 und den beta1-selektiven Rezeptorantagonisten CGP 20712A verdrängt, wobei für ICI 118.551 eine 10.000-fach höhere Affinität (Ki = 1,74 ± 0,15 nM in frisch-isolierten Zellen und 1,19 ± 0,41 nM in Primärkultur) gezeigt wurde als für CGP 20712A (Ki = 17 ± 7,90 μM in frisch isolierten Zellen). Die cAMP-Bildung wurde in frisch isolierten ETEZ konzentrationsabhängig durch die beta-adrenergen Rezeptoragonisten Isoproterenol, Epinephrin und Norepinephrin in der Reihenfolge ihrer Potenz mit einer EC50 von 58 nM (n = 6), 13,60 μM (n = 6) bzw. 0,43 mM (n = 6) stimuliert. Diese cAMP-Bildung konnte durch Behandlung der Zellen mit 100 nM der beta2-selektiven ICI 118.551, nicht aber durch 300 nM des beta1-selektiven CGP 20712A blockiert werden. Mit einem beta2-adrenergen Rezeptorantikörper konnte eine 72 kDa Proteinbande und mit demselben Antikörper in der Fluoreszenzfärbung Rezeptorantigene auf der Zelloberfläche nachgewiesen werden. Zusammenfassend konnten mit dem etablierten Protokoll große Mengen equiner Trachealepithelzellen isoliert und kultiviert werden. Die Ergebnisse dieser Studie zeigen erstmalig, dass primäre equine Trachealepithelzellen funktionale beta2-adrenerge Rezeptoren exprimieren und das Protokoll zur Etablierung eines zellbasierten Modells geeignet ist, um in vitro verschiedene Funktionen und eine Pharmaka-induzierte Regulation der beta-adrenergen Signalkaskade hinsichtlich physiologischer und pathophysiologischer Zustände bei Atemwegserkrankungen des Pferdes und hierfür relevante pharmakologische und toxikologische Zielstrukturen untersuchen zu können. info:eu-repo/classification/ddc/610 ddc:610
392	Electrophysiology and Arrhythmogenesis in the Human Right Ventricular Outflow Tract Aras, Kedar, Gams, Anna, Faye, Ndeye R., Brennan, Jaclyn, Goldrick, Katherine, Li, Jinghua, Zhong, Yishan, Chiang, Chia-Han, Smith, Elizabeth H., Poston, Megan D., Chivers, Jacqueline, Hanna, Peter, Mori, Shumpei, Ajijola, Olujimi A., Shivkumar, Kalyanam, Hoover, Donald B., Viventi, Jonathan 01 March 2022 (has links) BACKGROUND: Right ventricular outflow tract (RVOT) is a common source of ventricular tachycardia, which often requires ablation. However, the mechanisms underlying the RVOT's unique arrhythmia susceptibility remain poorly understood due to lack of detailed electrophysiological and molecular studies of the human RVOT. METHODS: We conducted optical mapping studies in 16 nondiseased donor human RVOT preparations subjected to pharmacologically induced adrenergic and cholinergic stimulation to evaluate susceptibility to arrhythmias and characterize arrhythmia dynamics. RESULTS: We found that under control conditions, RVOT has shorter action potential duration at 80% repolarization relative to the right ventricular apical region. Treatment with isoproterenol (100 nM) shortened action potential duration at 80% repolarization and increased incidence of premature ventricular contractions (=0.003), whereas acetylcholine (100 μM) stimulation alone had no effect on action potential duration at 80% repolarization or premature ventricular contractions. However, acetylcholine treatment after isoproterenol stimulation reduced the incidence of premature ventricular contractions (=0.034) and partially reversed action potential duration at 80% repolarization shortening (=0.029). Immunolabeling of RVOT (n=4) confirmed the presence of cholinergic marker VAChT (vesicular acetylcholine transporter) in the region. Rapid pacing revealed RVOT susceptibility to both concordant and discordant alternans. Investigation into transmural arrhythmia dynamics showed that arrhythmia wave fronts and phase singularities (rotors) were relatively more organized in the endocardium than in the epicardium (=0.006). Moreover, there was a weak but positive spatiotemporal autocorrelation between epicardial and endocardial arrhythmic wave fronts and rotors. Transcriptome analysis (n=10 hearts) suggests a trend that MAPK (mitogen-activated protein kinase) signaling, calcium signaling, and cGMP-PKG (protein kinase G) signaling are among the pathways that may be enriched in the male RVOT, whereas pathways of neurodegeneration may be enriched in the female RVOT. CONCLUSIONS: Human RVOT electrophysiology is characterized by shorter action potential duration relative to the right ventricular apical region. Cholinergic right ventricular stimulation attenuates the arrhythmogenic effects of adrenergic stimulation, including increase in frequency of premature ventricular contractions and shortening of wavelength. Right ventricular arrhythmia is characterized by positive spatial-temporal autocorrelation between epicardial-endocardial arrhythmic wave fronts and rotors that are relatively more organized in the endocardium. acetylcholine (pharmacology) adrenergic agents cardiac electrophysiology cholinergic agents electrocardiography female heart ventricles human rights humans isoproterenol (pharmacology) male pericardium tachycardia ventricular (etiology) ventricular premature complexes arrhythmias Biomedical Sciences
393	Imidazoline Desensitization of Epinephrine Responses in Rat Vas Deferens Rice, P J., Hardin, J. C., Hamdi, A, Abraham, S T. 01 December 1991 (has links) Repeated exposure of the rat vas deferens to the imidazoline oxymetazoline (OXY) results in a progressive loss of response which can appear selective for imidazoline agonists. The present study tests the hypothesis that imidazolines produce desensitization through prolonged blockade or inactivation of alpha-1 adrenoreceptors. Repeated exposure to OXY, naphazoline (NPZ) or tetrahydrozoline (THZ) produces a concentration- and time-dependent rightward shift and depression of the (-)-epinephrine concentration-effect curve, suggesting a mechanism of prolonged receptor blockade or inactivation. (-)-Epinephrine Kd values were similar when estimated after either receptor inactivation with phenoxybenzamine or repeated exposure to imidazolines. The differences in the ability of individual imidazolines to produce desensitization (order of potency: OXY greater than NPZ greater than or equal to THZ) do not follow their intrinsic activity (NPZ approximately THZ approximately OXY) or affinity (OXY greater than or equal to NPZ greater than THZ). The ability of individual imidazoline and phenethylamine agonists to produce a response in imidazoline-desensitized rat vas deferens reflects agonist intrinsic efficacy. Desensitization by imidazoline exposure does not affect contraction produced by either KCl or neurokinin A. Imidazolines produce effects similar to receptor inactivation and their desensitization in vas deferens can be explained without invoking an imidazoline subtype of alpha-1 adrenoreceptor. animals epinephrine (physiology) imidazoles (pharmacology) kinetics male oxymetazoline (pharmacology) rats inbred strains vas deferens (drug effects) GCOP
394	Genetically-programmed suicide of adrenergic cells in the mouse leads to severe left ventricular dysfunction, impaired weight gain, and symptoms of neurological dysfunction Owji, Aaron 01 January 2015 (has links) Phenylethanolamine-N-methyltransferase (Pnmt) catalyzes the conversion of noradrenaline to adrenaline and is the last enzyme in the catecholamine biosynthetic pathway. Pnmt serves as a marker for adrenergic cells, and lineage-tracing experiments have identified the embryonic heart and hindbrain region as the first sites of Pnmt expression in the mouse. Pnmt expression in the heart occurs before the adrenal glands have formed and prior to sympathetic innervation, suggesting that the heart is the first site of catecholamine production in the mouse. The function of these Pnmt+ cells in heart development remains unclear. In the present study, we test the hypothesis that (i) a genetic ablation technique utilizing a suicide reporter gene selectively destroys Pnmt cells in the mouse, and (ii) Pnmt cells are required for normal cardiovascular and neurological function. To genetically ablate adrenergic cells, we mated Pnmt-Cre mice, in which Cre-recombinase is under the transcriptional regulation of the Pnmt promoter, and a Cre -activated diphtheria toxin A (DTA) mouse strain (ROSA26-eGFP-DTA), thereby causing activation of the toxic allele (DTA) in Pnmt-expressing (adrenergic) cells resulting in selective "suicide" of these cells in approximately half of the offspring. The other half serve as controls because they do not have the ROSA26-eGFP-DTA construct. In the Pnmt+/Cre; R26+/DTA offspring, we achieve a dramatic reduction in Pnmt transcript and Pnmt immunoreactive area in the adrenal glands. Furthermore, we show that loss of Pnmt cells results in severe left ventricular dysfunction that progressively worsens with age. These mice exhibit severely reduced cardiac output and ejection fraction due to decreased LV contractility and bradycardia at rest. Surprisingly, these mice appear to have a normal stress response, as heart rate and ejection fraction increased to a similar extent compared to controls. In addition to baseline cardiac dysfunction, these mice fail to gain body weight in a normal manner and display gross neurological dysfunction, including muscular weakness, abnormal gaiting, and altered tail suspension reflex, an indicator of neurological function. This work demonstrates that selective Pnmt cell destruction leads to severe left ventricular dysfunction, lack of weight gain, and neurological dysfunction. This novel mouse is expected to shed insight into the role of Pnmt cells in the heart, and suggests a role for Pnmt cells in neurological regulation of feeding behavior, metabolism, and motor control. Cardiovascular biology heart development catecholamines adrenaline heart function mouse model left ventricular dysfunction ablation echocardiography adrenergic cells pnmt Biotechnology Molecular Biology
395	Pharmaceutical and Natural (Exercise) Mechanisms to Mitigate the Negative Impact of PTSD and Chronic Stress on Synaptic Plasticity and Memory Miller, Roxanne M 01 November 2017 (has links) Synapses can be altered due to experiences in a process called synaptic plasticity, which causes memory formations. Synapses can be strengthened through methods known as long-term potentiation (LTP) or weakened through long-term depression (LTD). Stresses can cause changes by altering synapses through either LTP or LTD. Rats were used to study the effects of post-traumatic stress disorder (PTSD)-like symptoms and a prophylactic treatment using pharmaceuticals. The first model used was the single prolonged stress (SPS) with two weeks of chronic light, which was not as effective for causing changes in synaptic plasticity. The second model, seven days of social defeat (SD) with two weeks of chronic light was more effective at inducing PTSD-like behavior symptoms and causing changes in LTP levels in the ventral hippocampus, amygdala, and prefrontal cortex between stressed and non-stressed rats. For the prophylactic treatment, propranolol and mifepristone were administered one week prior to and throughout the two weeks of the social defeat protocol. The drugs were able to prevent the changes due to stress on LTP in the three aforementioned brain regions, but did not change the anxious behavior of the rats. An enzyme-linked immunosorbent assay (ELISA) was used to determine corticosterone and norepinephrine levels between the different groups of rats. No significant differences were detected between SD and control rats, but SD injected rats were different from controls indicating that the injections were causing added stress. Reverse transcriptase quantitative polymerase chain reaction (RT-qPCR) was used to detect changes in the adrenergic, corticoid, AMPA, and NMDA receptors. There were a few significant changes to some of the targets indicating that the stress protocol and drugs were having an effect on the mRNA expression. Propranolol and mifepristone could possibly be used as a prophylactic treatment for traumatic stress. In a separate study, techniques were used to determine the negative effects chronic stress (non-PTSD-like) has on synaptic plasticity in the dorsal hippocampus and to show how exercise was able to mitigate some of those negative stress effects. Electrophysiology showed differences in LTP between four groups of mice: sedentary no stress (SNS), sedentary with stress (SWS), exercise with stress (EWS), and exercise no stress (ENS). SWS had the lowest amount of LTP, whereas ENS had the highest. SNS and EWS had similar levels of LTP, which were in between the SWS and ENS groups. Corticosterone blood levels measured by an ELISA showed significant increases in the stressed groups compared to the non-stressed groups. The radial arm maze showed that both groups of exercise mice made fewer reference memory errors the second week of testing compared to the sedentary groups. RT-qPCR determined that brain-derived neurotrophic factor (BDNF) and corticoid and dopamine 5 receptors were likely causing some of the memory changes. chronic stress LTP LTD corticoid receptor dopamine receptor adrenergic receptor exercise propranolol mifepristone BDNF hippocampus amygdala prefrontal cortex Life Sciences Physiology
396	Pharmaceutical and Natural (Exercise) Mechanisms to Mitigate the Negative Impact of PTSD and Chronic Stress on Synaptic Plasticity and Memory Miller, Roxanne M 01 November 2017 (has links) Synapses can be altered due to experiences in a process called synaptic plasticity, which causes memory formations. Synapses can be strengthened through methods known as long-term potentiation (LTP) or weakened through long-term depression (LTD). Stresses can cause changes by altering synapses through either LTP or LTD. Rats were used to study the effects of post-traumatic stress disorder (PTSD)-like symptoms and a prophylactic treatment using pharmaceuticals. The first model used was the single prolonged stress (SPS) with two weeks of chronic light, which was not as effective for causing changes in synaptic plasticity. The second model, seven days of social defeat (SD) with two weeks of chronic light was more effective at inducing PTSD-like behavior symptoms and causing changes in LTP levels in the ventral hippocampus, amygdala, and prefrontal cortex between stressed and non-stressed rats. For the prophylactic treatment, propranolol and mifepristone were administered one week prior to and throughout the two weeks of the social defeat protocol. The drugs were able to prevent the changes due to stress on LTP in the three aforementioned brain regions, but did not change the anxious behavior of the rats. An enzyme-linked immunosorbent assay (ELISA) was used to determine corticosterone and norepinephrine levels between the different groups of rats. No significant differences were detected between SD and control rats, but SD injected rats were different from controls indicating that the injections were causing added stress. Reverse transcriptase quantitative polymerase chain reaction (RT-qPCR) was used to detect changes in the adrenergic, corticoid, AMPA, and NMDA receptors. There were a few significant changes to some of the targets indicating that the stress protocol and drugs were having an effect on the mRNA expression. Propranolol and mifepristone could possibly be used as a prophylactic treatment for traumatic stress. In a separate study, techniques were used to determine the negative effects chronic stress (non-PTSD-like) has on synaptic plasticity in the dorsal hippocampus and to show how exercise was able to mitigate some of those negative stress effects. Electrophysiology showed differences in LTP between four groups of mice: sedentary no stress (SNS), sedentary with stress (SWS), exercise with stress (EWS), and exercise no stress (ENS). SWS had the lowest amount of LTP, whereas ENS had the highest. SNS and EWS had similar levels of LTP, which were in between the SWS and ENS groups. Corticosterone blood levels measured by an ELISA showed significant increases in the stressed groups compared to the non-stressed groups. The radial arm maze showed that both groups of exercise mice made fewer reference memory errors the second week of testing compared to the sedentary groups. RT-qPCR determined that brain-derived neurotrophic factor (BDNF) and corticoid and dopamine 5 receptors were likely causing some of the memory changes. chronic stress LTP LTD corticoid receptor dopamine receptor adrenergic receptor exercise propranolol mifepristone BDNF hippocampus amygdala prefrontal cortex Life Sciences Physiology
397	An Examination of the Role of Adrenergic Receptor Stimulation in Mediating the Link Between Early-Life Stress and the Sensitization of Neuroinflammatory-Based Depressive-Like Behavior in Isolated Guinea Pig Pups Kessler, Rachel Renate 30 May 2023 (has links) No description available. Behavioral Sciences Behavioral Psychology Developmental Psychology early-life adversity stress inflammation guinea pigs maternal separation sensitization depressive-like behavior attachment disruption adrenergic stimulation propranolol
398	cAMP BIOSENSORS AND SPATIOTEMPORAL cAMP SIGNALING IN ADULT CARDIAC MYOCYTES Warrier, Sunita 06 April 2007 (has links) No description available. cyclic AMP cAMP cardiac myocytes biosensors signaling G-protein Coupled receptors PGE1: beta-adrenergic receptor muscarinic receptor acetylcholine prostaglandin FRET CFP YFP
399	Social Stress Induces Immunoenhancement During Allergic Airway Inflammation and Infection Reader, Brenda Faye January 2013 (has links) No description available. Dentistry Psychology Psychobiology Neurosciences Microbiology Medicine Immunology psychoneuroimmunology NPY IL-1 Porphyromonas gingivalis Aspergillus fumigatus neutrophils inflammation allergic airway inflammation stress anxiety adrenergic receptors
400	Alpha1-Adrenergic Receptor Activation Mimics Ischemic Postconditioning in Cardiac Myocytes Janota, Danielle Marie 04 August 2014 (has links) No description available. Biomedical Research Biology alpha1-adrenergic receptors cardiac, heart myocardial infarction ischemia reperfusion postconditioning autophagy apoptosis cell death myocytes cardiomyocytes HL-1

Search results