Global ETD Search

111	Optogenetic Inhibition of the mPFC During Delay Discounting White, Shelby M. 05 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Impulsivity, or the tendency to act prematurely without foresight, has been linked to a diverse range of pathological conditions. Foresight refers to the ability to envision future rewards and events (i.e. prospectively sample) and has been associated with decreased impulsivity. One form of impulsivity is measured by the ability to delay gratification and is often studied in the framework of Delay Discounting (DD). DD provides the means to study impulsivity in a number of pathological conditions. However, whether impulsivity precedes the development of pathological states or results from the pathological state itself is not fully understood. This necessitates an understanding of neurobiological mechanisms contributing to decision making in both non-impulsive as well as impulsive populations of individuals. Animal models allow invasive techniques to be used to dissect the neurocircuitry involved in decision making. Given that the decision-making process is an ongoing process rather than an isolated event, optogenetics provide the temporal and spatial specificity necessary for evaluating brain region specific contributions to decision making in DD. In the present study, optogenetics were used to assess the contribution of the medial Prefrontal Cortex (mPFC), a brain region involved in ‘goal-directed’ behavior, in the planning of future choices (i.e. prospective plans) and subsequent measures of impulsivity in an adjusting amount DD procedure. Optogenetic inhibition of mPFC was conducted in Wistar rats during different epochs of a DD task in order to assess how mPFC affects planning behavior in a population of rat not considered to be highly impulsive. Although no direct effects on planning behavior (e.g. consistency) were observed, inhibiting mPFC after a trial has been initiated and directly before a choice was made (Epoch 2) was observed to increase measures of impulsivity in comparison to days where no optogenetic manipulation occurred in a delay-specific manner. This suggests that mPFC differentially contributes to decision making at different delays. A pattern of associations between choice latency, impulsivity, and consistency began to emerge for inactivation occurring in Epoch 2, suggesting that mPFC contributes to some aspect of planning choices during this epoch. Moreover, these results indicate that mPFC is involved in decision making in Wistar Rats. Understanding the direct role that mPFC plays in promoting choices of delayed rewards provides a neurobiological target for treatment aimed at reducing impulsivity in the clinical population. ArchT mPFC Delay Discounting Impulsive Choice Intertemporal Choice Wistar Impulsivity Strategy Prospection Epoch-specific Decision Making Optogenetics
112	Bidirectional Control of Infant Rat Social Behavior via Dopaminergic Innervation of the Basolateral Amygdala Opendak, Maya, Raineki, Charlis, Perry, Rosemarie E., Rincón-Cortés, Millie, Song, Soomin C., Zanca, Roseanna M., Wood, Emma, Packard, Katherine, Hu, Shannon, Woo, Joyce, Martinez, Krissian, Vinod, K. Y., Brown, Russell W., brown1@etsu.edu, Deehan, Gerald A., Froemke, Robert C., Serrano, Peter A., Wilson, Donald A. 15 December 2021 (has links) Social interaction deficits seen in psychiatric disorders emerge in early-life and are most closely linked to aberrant neural circuit function. Due to technical limitations, we have limited understanding of how typical versus pathological social behavior circuits develop. Using a suite of invasive procedures in awake, behaving infant rats, including optogenetics, microdialysis, and microinfusions, we dissected the circuits controlling the gradual increase in social behavior deficits following two complementary procedures-naturalistic harsh maternal care and repeated shock alone or with an anesthetized mother. Whether the mother was the source of the adversity (naturalistic Scarcity-Adversity) or merely present during the adversity (repeated shock with mom), both conditions elevated basolateral amygdala (BLA) dopamine, which was necessary and sufficient in initiating social behavior pathology. This did not occur when pups experienced adversity alone. These data highlight the unique impact of social adversity as causal in producing mesolimbic dopamine circuit dysfunction and aberrant social behavior. amygdala animals basolateral nuclear complex dopamine humans optogenetics rats social behavior parenting development adversity Biomedical Sciences Psychology
113	Rôle des neurones sérotoninergiques de la voie raphé-hippocampe ventral dans les comportements anxieux Perreault, Félix 08 1900 (has links) Il y a longtemps qu’on a attribué à l’hippocampe un rôle central dans la mémoire, mais ce n’est pas son unique rôle. Un nombre grandissant d’études attestent que l’hippocampe peut être séparé en deux régions, dorsale et ventrale, qui sont fonctionnellement différentes. La partie dorsale de l’hippocampe est responsable du rôle classique dans la mémoire spatiale et contextuelle, alors que la région ventrale de l’hippocampe est importante dans l’expression de l’anxiété et de la motivation, entre autres. Les projections des noyaux du raphé, l’unique source d’afférences sérotoninergiques de l’hippocampe, auraient un rôle régulateur sur ses fonctions, dont le comportement anxieux. Toutefois, les fonctions de la projection sérotoninergique raphé-hippocampe ventral ne sont pas entièrement caractérisées et les différents rôles des sous-populations de neurones sérotoninergiques au sein même de la projection raphé-hippocampe ventral sont peu connus. Dans ce projet de recherche, nous avons utilisé des tests comportementaux et des outils optogénétiques, afin de déterminer le rôle de la projection sérotoninergique raphé-hippocampe ventral dans le comportement d’aversion. Notre hypothèse est que la sérotonine régule l’anxiété en agissant sur l’hippocampe ventral via cette projection. Nous démontrons entre autres que l’activation de la projection sérotoninergique raphé-hippocampe ventral induit une hausse de l’anxiété, mais spécifiquement chez les femelles. Nous démontrons aussi que l’activation de la projection réduit la locomotion. Nos données offrent un nouveau point de vue sur le rôle du raphé médian dans l’anxiété ainsi que sur l’importance du sexe dans l’expression du comportement anxieux. / It has been known for a long time that the hippocampus has a central role in memory, but it isn’t its sole function. A growing number of studies are showing that the hippocampus can be split in two regions, dorsal and ventral, that are functionally different. The dorsal part is responsible for the classic and well-known role of the hippocampus in spatial and contextual memory, while the ventral region is important for the expression of anxiety and motivation, among other roles. The only serotonergic input of the hippocampus are the raphe nuclei and it has been suggested that it has a regulatory effect over its functions, such as anxiety. Nonetheless, the functions of the raphe-ventral hippocampus serotonergic projection are not fully characterized and sub-populations of serotonergic neurons inside the projection itself aren’t known. In this research project, we used behavioral tests and optogenetic tools to determine whether the raphe to ventral hippocampus serotonergic projection is able to influence aversive behaviors. Our hypothesis is that serotonin regulates anxiety through its influence on the ventral hippocampus via the raphe-ventral hippocampus serotonergic projection. We found that optogenetic activation of the projection induces heightened anxiety, but only in female mice. Our data offer new insight as to how the median raphe regulates anxiety and the importance of sex in the expression of anxiety. Anxiété Sérotonine Hippocampe ventral Noyaux du raphé Optogénétique Anxiety Serotonin Ventral hippocampus Raphe nuclei Optogenetics
114	Implementation of an all-optical setup for insect brain optogenetic stimulation and two-photon functional imaging Zanon, Mirko 14 April 2020 (has links) Insect brain is a very complex but at the same time small, simplified and accessible model with respect to the mammalian one. In neuroscience a huge number of works adopt drosophila as animal model, given its easiness of maintenance and, overall, of genetical manipulation. With such a model one can investigate many behavioral tasks and at the same time have access to a whole brain in vivo, with improved specificity and cellular resolution capabilities. Still, a remarkable goal would be to gain a precise control over the neural network, in order to fully manipulate specific areas of the brain, acting directly on network nodes of interest. This is possible thanks to optogenetics, a technique that exploits photosensitive molecules to modulate molecular events in living cells and neurons. At the same time, it is possible to perform a neuronal readout with light, exploiting calcium-based reporters; in this way, neuronal response investigation can gain in temporal and spatial resolution. This is an all-optical approach that brings many advantages in the neural network study and an insight in the functional connectivity of the system under investigation. We present here a setup that combines a two-photon imaging microscope, capable of in vivo imaging with a sub-cellular resolution and an excellent penetration depth down to hundreds of microns, with a diode laser optogenetic stimulation. With such a setup we investigate the drosophila brain in vivo, stimulating single units of the primary olfactory system (the so-called glomeruli, about 20 μm of diameter). By our knowledge this is one of the first time a similar all-optical approach is used in such an animal model: we confirm, in this way, the possibility to perform these experiments in vivo, with all the advantages coming from the improved accessibility of our model. Moreover, we present the results using a sample co-expressing GCaMP6 and ChR2-XXL, optimal performing sensor and actuator, largely exploited in the field for their high efficiency: these were rarely used in combination, since their spectral overlap, nevertheless we are able to show the feasibility of this combined approach, enabling to take advantage from the use of both these performing molecules. Finally, we will show different approaches of data analysis to infer relevant information about correlation and time response of different areas of the brain, that can give us hints in favor of some functional connectivity between olfactory subunits.
115	Optogenetic Tools for In-Vitro Neurophysiology Norman, Olivia Rose January 2014 (has links) No description available. Biomedical Engineering Neurosciences Biology Optogenetics Channelrhodopsin-2 Voltage Clamp Current Clamp HEK-293 MC3T3-E1 Gap Junctions
116	Modulation de l'activité de structures cérébrales sous-corticales par optogénétique Castonguay, Alexandre 03 1900 (has links) L’optogénétique est une technique prometteuse pour la modulation de l’activité neuronale. Par l’insertion d’une opsine microbienne dans la membrane plasmique de neurones et par son activation photonique, il devient possible de réguler l’activité neuronale avec une grande résolution temporelle et spatiale. Beaucoup de travaux ont été faits pour caractériser et synthétiser de nouvelles opsines. Ainsi, plusieurs variétés d’opsines sont désormais disponibles, chacune présentant des cinétiques et sensibilités à des longueurs d’onde différentes. En effet, il existe des constructions optogénétiques permettant de moduler à la hausse ou à la baisse l’activité neuronale, telles la channelrhodopsine-2 (ChR2) ou la halorhodopsine (NpHR), respectivement. Les promesses de cette technologie incluent le potentiel de stimuler une région restreinte du cerveau, et ce, de façon réversible. Toutefois, peu d’applications en ce sens ont été réalisées, cette technique étant limitée par l’absorption et la diffusion de la lumière dans les tissus. Ce mémoire présente la conception d’une fibre optique illuminant à un angle de 90° à sa sortie, capable de guider la lumière à des structures bien précises dans le système nerveux central. Nous avons conduit des tests in vivo dans le système visuel de souris transgéniques exprimant la ChR2 dans l’ensemble du système nerveux central. Dans le système visuel, les signaux rétiniens sont conduits au corps genouillé latéral (CGL) avant d’être relayés au cortex visuel primaire (V1). Pour valider la capacité de mon montage optogénétique à stimuler spécifiquement une sous-population de neurones, nous avons tiré profit de l’organisation rétinotopique existant dans le système visuel. En stimulant optogénétiquement le CGL et en tournant la fibre optique sur elle-même à l’aide d’un moteur, il devient possible de stimuler séquentiellement différentes portions de cette structure thalamique et conséquemment, différentes représentations du champ visuel. L’activation des projections thalamiques sera enregistrée au niveau de l’aire V1 à l’aide de l’imagerie optique intrinsèque, une technique qui permet d’imager les variations de la concentration d’oxygène et du volume sanguin dans le tissu neuronal, sur une grande surface corticale. Comme l’organisation rétinotopique est maintenue au niveau de l’aire V1, l’espace activé au niveau du cortex révèlera l’étendue spatiale de notre stimulation optogénétique du CGL. Les expériences in vivo démontrèrent qu’en déplaçant la fibre optique dans le CGL, il nous était possible de stimuler différents sous- ensembles de neurones dans cette structure thalamique. En conclusion, cette étude montre notre capacité à développer un système à base de fibre optique capable de stimuler optogénétiquement une population de neurone avec une grande précision spatiale. / Optogentics is a promising technic for neuronal activity modulation. By inserting a microbial opsin in the plasma membrane and by its photonic activation, it is possible to regulate neuronal activity with high temporal and spatial resolution. A lot of work has been done to characterize and synthetize new opsins. Thus, a wide variety of opsins are now available, presenting different kinetics and sensibility to specific wavelengths. Indeed, different opsins can either increase or decrease neuronal activity such as channelrhodopsin-2 (ChR2) or halorhodopsin (NpHR), respectively. This technology has the potential to stimulate a specific region within the brain in a highly reversible manner. However, little work was accomplished in this way, because to limitations due to absorption and scattering of light in biological tissue. This master’s thesis presents the conception of a side-firing optical fiber, capable of guiding light to specific structures within the brain. We conducted in vivo experiments in the visual system of transgenic mice expressing ChR2 in the entire central nervous system. In the visual system, retinal inputs are relayed to the lateral geniculate nucleus (LGN) before reaching the primary visual cortex (V1). To validate the capacity of the designed optogenetic assembly to stimulate specific sub-populations of neurons, we took advantage of the retinotopic organization existing in the visual system. By optogenetically stimulating the LGN and rotating the optical fiber around its axis with a motor, it is possible to sequentially stimulate different portions of this thalamic structure and consequently, different portions of the visual field. Activation of thalamic projections will be recorded in area V1 using intrinsic optical imaging, a technic allowing to image variations of blood oxygenation and blood volume in neuronal tissue over large cortical areas. Activation at the level of the cortex will reveal the spatial extent of the optogenetic stimulation in the LGN as retinotopic organization is maintained in V1 cortical area. In vivo experiments showed that displacing the optical fiber in the LGN allowed stimulation of different neuronal populations within this thalamic structure. In conclusion, this study demonstrates our capacity to develop a fiber-based system capable of optogenetically stimulating neuronal tissue with high spatial precision. Optogénétique Imagerie optique intrinsèque Système visuel Fibre optique Optogenetics Intrinsic optical imaging Visual system Optical fiber
117	MAPPING BRAIN CIRCUITS IN HEALTH AND DISEASE Qiuyu Wu (6803957) 02 August 2019 (has links) <p>Intricate neural circuits underlie all brain functions. However, these neural circuits are highly dynamic. The ability to change, or the plasticity, of the brain has long been demonstrated at the level of isolated single synapses under artificial conditions. Circuit organization and brain function has been extensively studied by correlating neuronal activity with information input. The primary visual cortex has become an important model brain region for the study of sensory processing, in large part due to the ease of manipulating visual stimuli. Much has been learned from studies of visual cortex focused on understanding the signal-processing of visual inputs within neural circuits. Many of these findings are generalizable to other sensory systems and other regions of cortex. However, few studies have directly demonstrated the orchestrated neural-circuit plasticity occurring during behavioral experience. </p> <p>It is vital to measure the precise circuit connectivity and to quantitatively characterize experience-dependent circuit plasticity to understand the processes of learning and memory formation. Moreover, it is important to study how circuit connectivity and plasticity in neurological and psychiatric disease states deviates from that in healthy brains. By understanding the impact of disease on circuit plasticity, it may be possible to develop therapeutic interventions to alleviate significant neurological and psychiatric morbidity. In the case of neural trauma or ischemic injury, where neurons and their connections are lost, functional recovery relies on neural-circuit repair. Evaluating whether neurons are reconnected into the local circuitry to re-establish the lost connectivity is crucial for guiding therapeutic development.</p> <p>There are several major technical hurdles for studies aiming to quantify circuit connectivity. First, the lack of high-specificity circuit stimulation methods and second, the low throughput of the gold-standard patch-clamp technique for measuring synaptic events have limited progress in this area. To address these problems, we first engineered the patch-clamp experimental system to automate the patching process, increasing the throughput and consistency of patch-clamp electrophysiology while retaining compatibility of the system for experiments in <i>ex vivo </i>brain slices. We also took advantage of optogenetics, the technology that enables control of neural activity with light through ectopic expression of genetically encoded photo-sensitive channels in targeted neuronal populations. Combining optogenetic stimulation of pre-synaptic axonal terminals and whole-cell patch-clamp recording of post-synaptic currents, we mapped the distribution and strength of synaptic connections from a specific group of neurons onto a single cell. With the improved patch-clamp efficiency using our automated system, we efficiently mapped a significant number of neurons in different experimental conditions/treatments. This approach yielded large datasets, with sufficient power to make meaningful comparisons between groups.</p> <p>Using this method, we first studied visual experience-dependent circuit plasticity in the primary visual cortex. We measured the connectivity of local feedback and recurrent neural projections in a Fragile X syndrome mouse model and their healthy counterparts, with or without a specific visual experience. We found that repeated visual experience led to increased excitatory drive onto inhibitory interneurons and intrinsically bursting neurons in healthy animals. Potentiation at these synapses was absent or abnormal in Fragile X animals. Furthermore, recurrent excitatory input onto regular spiking neurons within the same layer remained stable in healthy animals but was depressed in Fragile X animals following repeated visual experience. These results support the hypothesis that visual experience leads to selective circuit plasticity which may underlie the mechanism of visual learning. This circuit plasticity process is impaired in a mouse model of Fragile X syndrome. </p> <p>In a separate study, in collaboration with the laboratory of Dr. Gong Chen, we applied the circuit-mapping method to measure the effect of a novel brain-repair therapy on functional circuit recovery following ischemic injury, which locally kills neurons and creates a glial scar. By directly reprogramming astrocytes into neurons within the region of the glial scar, this gene-therapy technology aims to restore the local circuit and thereby dramatically improve behavioral function after devastating neurological injury. We found that direct reprogramming converted astrocytes into neurons, and importantly, we found that these newly reprogrammed neurons integrated appropriately into the local circuit. The reprogramming also improved connections between surviving endogenous neurons at the injury site toward normal healthy levels of connectivity. Connections formed onto the newly reprogrammed neurons spontaneously remodeled, the process of which resembled neural development. By directly demonstrating functional connectivity of newly reprogrammed neurons, our results suggest that this direct reprogramming gene-therapy technology holds significant promise for future clinical application to restore circuit connectivity and neurological function following brain injury.</p> Neuroscience Circuit mapping Optogenetics Fragile X ischemic brain injury patch-clamp electrophysiology Ex vivo brain slices In vivo direct reprogramming Primary visual cortex
118	Konstruktion und Charakterisierung einer lichtaktivierten Phosphodiesterase Gasser, Carlos Fernando 03 December 2015 (has links) Genetisch kodierte Photorezeptoren in Modellorganismen begründen die Optogenetik. Sie ermöglicht die nicht-invasive, reversible und räumlich-zeitlich präzise Perturbation von zellulären und physiologischen Signalprozessen durch Licht. Natürliche photoaktivierte Adenylylzyklasen (PACs) steigern die intrazelluläre Konzentration des Botenstoffs zyklischen Adenosinmonophosphats (cAMP) durch Blaulicht. Damit erlauben sie die optogenetische Analyse von cAMP-abhängigen Signalwegen. Diese Arbeit komplementiert PACs durch die synthetische rotlichtaktivierte Phosphodiesterase LAPD zur Degradation von cAMP und zyklischem Guanosinmonophosphat (cGMP). LAPD ist eine Chimäre aus dem photosensorischen Modul von Deinococcus radiodurans Bakteriophytochrom (DrBPhy) und der Effektordomäne der cAMP/cGMP-spezifischen H. sapiens Phosphodiesterase 2A (HsPDE2A). Die Fusionsstelle wurde von den helikalen Linkern zwischen Sensor- und Effektormodulen durch strukturelle Überlagerung abgeleitet. LAPD inkorporierte den Chromophor Biliverdin (BV) nach Expression in E. coli und Reinigung vollständig und entsprach spektral und photochemisch dem Wildtyp-DrBPhy. Durch Bestrahlung mit Rot- und Fernrotlicht (R bzw. FR) wurde LAPD in die metastabilen photochemischen Zustände Pfr (fernrot) bzw. Pr (rot) umgewandelt. Vollständig aktivierte LAPD katalysierte die Hydrolyse von cGMP und cAMP in derselben Größenordnung wie Wildtyp-HsPDE2A. LAPD degradierte cGMP und cAMP bei 6- bzw. 4-facher Steigerung von vmax unter R im Vergleich zu dunkeladaptiertem Enzym. Die Aktivität von R-adaptierter LAPD wurde durch FR reduziert. Die enzymatische Aktivität und Lichtregulation von LAPD-Linkervarianten waren abhängig von der Linkerlänge. LAPD degradierte lichtabhängig cGMP in einer PDE-Reporterzelle. Dabei genügte die endogene BV-Konzentration der Säugerzelle zur Sättigung des Lichteffekts. / Genetically encoded photoreceptors in model organisms establish optogenetics. It enables non-invasive, reversible, and spatio-temporally precise perturbation of cellular and physiological signalling by light. Natural photoactivated adenylate cyclases (PACs) increase the intracellular concentration of the second messenger cyclic adenosine monophosphate (cAMP) under blue light. Hence, PACs allow the optogenetic analysis of cAMP-dependent signalling. This work complements PACs with the synthetic red-light-activated phosphodiesterase LAPD for degradation of cAMP and cyclic guanosine monophosphate (cGMP). LAPD is a chimera made up of the photosensory module of Deinococcus radiodurans bacteriophytochrome (DrBPhy) and the effector domain of cAMP/cGMP-specific H. sapiens Phosphodiesterase 2A (HsPDE2A). The fusion site was derived from the helical linkers between sensor and effector modules via structural superposition. LAPD incorporated the chromophor biliverdin (BV) after expression in E. coli and purification quantitatively, and spectrally and photochemically resembled the wildtype DrBPhy. Upon irradiation with red and far-red light (R and FR, resp.), LAPD was converted to the metastable photochemical states Pfr (far-red) and Pr (red), respectively. Fully activated LAPD catalized the hydrolysis of cGMP and cAMP with rates similar to wildtype HsPDE2A. LAPD degraded cGMP and cAMP with 6- and 4-fold increase of vmax under R, respectively, as compared to the dark state. The activity of R-adapted LAPD was reduced upon irradiation with FR. Enzymatic activity and light regulation of LAPD linker variants depended on the linker length. LAPD light-dependently degraded cGMP in a PDE reporter cell line. Endogenous BV concentrations were sufficient to saturate the light effect in the mammalian cell, which enables a true optogenetic approach. cGMP cAMP Optogenetik Bakteriophytochrom Phosphodiesterase zyklische Nukleotide synthetische Photorezeptoren optogenetics bacteriophytochrome phosphodiesterase cyclic nucleotide synthetic photoreceptor 570 Biowissenschaften, Biologie 32 Biologie WE 5320 ddc:570
119	Design and electrophysiological characterization of rhodopsin-based optogenetic tools Schneider, Franziska 15 May 2014 (has links) Kanalrhodpsine (ChRs) sind lichtaktivierbare Kationenkanäle, welche als primäre Fotorezeptoren in Grünalgen dienen. In der Optogenetik werden ChRs verwendet um neuronale Membranen zu depolarisieren und mit Licht Aktionspotentiale auszulösen. Das mit blauem Licht aktivierte Chlamydomonas Kanalrhodopsin 2 (C2) und effiziente Mutanten wie C2 H134R stellen die am häufigsten genutzten depolarisierenden, optogenetischen Werkzeuge dar. Komplementär zu ChRs werden Protonen- und Chloridpumpen aus Archaebakterien zur neuronalen Inhibierung durch lichtinduzierte Hyperpolarisation verwendet. In der vorliegenden Arbeit untersuchten wir die ChR-Chimäre C1V1, ein grünlichtaktiviertes ChR, das sich durch hervorragende Membranlokalisierung und hohe Fotoströme in HEK-Zellen auszeichnet. C1V1 und C1V1-Mutanten mit feinabgestimmten spektralen und kinetischen Eigenschaften ermöglichen die neuronale Aktivierung mit Wellenlängen bis 620 nm sowie die unabhängige Aktivierung zweier Zellpopulationen in Kombination mit C2. Um die strukturelle Basis von Kanalöffnung und Ionentransport in ChRs zu verstehen, wurden gezielt Mutationen in C2 und C1V1 eingeführt. Die Fotoströme der entsprechenden Mutanten wurden auf Kationenselektivität und kinetische Veränderungen untersucht. Während Aminosäuren, die den Kanal an der zytosolischen Seite begrenzen, die Kationenfreisetzung und Einwärtsgleichrichtung der ChRs bestimmen, spielen zentral im Kanal gelegende Aminosäuren ein entscheidende Rolle für Kationenselektivität und -kompetition. Ein enzymkinetisches Modell ermöglichte außerdem die Zerlegung der Fotoströme in Beiträge der verschiedenen, konkurrierenden Kationen. Im letzten Teil der Arbeit wurde pHoenix, ein optogenetisches Werkzeug zur Ansäuerung synaptischer Vesikel, entwickelt. In Neuronen des Hippocampus wurde pHoenix verwendet, um die treibenden Kräfte für die vesikuläre Neurotransmitteraufnahme sowie den Zusammenhang zwischen Vesikelfüllstand und Freisetzungswahrscheinlichkeit zu analysieren. / Channelrhodopsins (ChRs) are light-activated cation channels functioning as primary photoreceptors in green algae. In the emerging field of optogenetics, ChRs are used to depolarize neuronal membranes, thus allowing for light-induced action-potential firing. The blue light-activated Chlamydomonas channelrhodopsin 2 (C2) and high-efficiency mutants such as C2 H134R represent the most commonly used depolarizing optogenetic tools. Complementary to ChRs, green to yellow light-activated proton and chloride pumps originating from archea enable neuronal inhibition by membrane hyperpolarization. In the present work, we developed the chimeric ChR C1V1, a green-light activated ChR with excellent membrane targeting and high photocurrents in HEK cells. Action spectrum and kinetic properties of C1V1 were further fine-tuned by site-directed mutagenesis. The ensemble of C1V1 variants allows for neuronal activation with wavelengths up to 620 nm and can be used in two-color optogenetic experiments in combination with C2 derivatives. In order to understand the structural motifs involved in channel gating and ion transport, conserved residues in C2 and C1V1 were mutated and photocurrents of the respective mutants were analyzed for kinetic characteristics and cation selectivity. In these experiments, residues of the inner gate region were shown to alter cytosolic cation release and inward rectification, whereas central gate residues determine cation competition and selectivity, as well as the equilibrium between the two open channel conformations. Moreover, an enzyme-kinetic model was used to quantitatively dissect ChR photocurrents into the contribution of different competing cations. Finally, we designed pHoenix, an optogenetic tool enabling green-light induced acidification of synaptic vesicles. In hippocampal neurons, pHoenix was used to study both the energetics of vesicular neurotransmitter uptake and the impact of the vesicular contents on synaptic vesicle release. Optogenetik mikrobielle Rhodopsine Kanalrhodopsin Kationenselektivität lichtaktivierte Vesikelansäuerung optogenetics microbial rhodopsin channelrhodopsin selectivity light-activated vesicle acidification 570 Biowissenschaften, Biologie 32 Biologie WD 2200 ddc:570
120	Elektrophysiologische Untersuchung des gerichteten Protonentransportes in mikrobiellen Rhodopsinen Vogt, Arend 06 March 2017 (has links) Mikrobielle Rhodopsine sind lichtsensitive Membranproteine und agieren als Sensoren, Biokatalysatoren oder Ionentransporter. Die Ionentransporter unterteilen sich in lichtgetriebene Ionenpumpen und in lichtaktivierte Kanalrhodopsine. Besonders die Protonenpumpe Bakteriorhodopsin steht schon lange im Fokus biophysikalischer Untersuchungen. Obwohl die Protonenpumpen seit über 40 Jahren intensiv untersucht werden, ist das Wissen über deren elektrophysiologische Eigenschaften noch immer gering. Aus diesem Grund widmete sich diese Arbeit der elektrophysiologischen Charakterisierung der mikrobiellen Rhodopsine mit dem Fokus auf Protonenpumpen. Hierfür wurden vor allem „Two-Electrode Voltage Clamp“ -Messungen (TEVC) an Oozyten des afrikanischen Krallenfrosches Xenopus leavis durchgeführt. Die Untersuchung verschiedener Protonenpumpen hat gezeigt, dass diese eine unerwartet große Diversität in ihren elektrophysiologischen Eigenschaften aufweisen. Von besonderem Interesse war die Beobachtung, dass einige Protonenpumpen neben Pumpströmen auch passive einwärts gerichtete Photoströme zeigten. Besonders deutlich war der „Pump-Kanal-Dualismus“ bei dem Gloeobacter-Rhodopsin ausgeprägt. Andere Protonenpumpen, wie das Bakteriorhodopsin oder Coccomyxa-Rhodopsin, zeigten keine einwärts gerichteten Photoströme. Das Coccomyxa-Rhodopsin wurde aufgrund seiner hohen Photostrom-Amplituden in Oozyten für eine Mutationsanalyse ausgewählt. Diese Mutationsanalyse verhalf die strukturellen Ursachen für die funktionalen Unterschiede zu identifizieren, welche sowohl zwischen den Protonenpumpen untereinander als auch gegenüber Kanalrhodopsinen beobachtet wurden. Mutationen im Gegenion-Komplex führen zu rein passiven oder inaktiven Transportern. Dagegen übernimmt der extrazelluläre Halbkanal in Protonenpumpe die Aufgabe einen passiven Protonen-Rückfluss während des Pumpzyklus zu verhindern, denn Mutationen in dieser Region verursachen passive Photoströme zusätzlich zum aktiven Pumpstrom. / Microbial rhodopsins are light-sensitive membrane proteins and operate as sensors, enzymes or ion-transporters. The ion transporters are subdivided into light-driven ion pumps and light-gated channels. Biophysical research has put focus on the proton pump bacteriorhodopsin for long time. Despite the fact that light-driven proton pumps are investigated for over 40 years, the knowledge about their electrophysiological properties is surprisingly low. For this reason, this thesis is devoted to the electrophysiological characterization of microbial rhodopsins with special focus on light-driven proton pumps. For this purpose, “Two-Electrode Voltage Clamp”-recordings (TEVC) were primarily performed using oocytes from African clawed frog Xenopus leavis. The investigation of diverse proton pumps has shown that the differences in their electrophysiological behaviors are unexpectedly high. Special interest was laid on proton pumps which show passive inward directed photocurrents when the electrochemical load exceeds a certain level. The dualism of pump and channel activity was particularly pronounced in the proton pump Gloeobacter-rhodopsin. Other proton pumps, for instance bacteriorhodopsin or Coccomyxa-rhodopsin, do not show inward directed photocurrents. Due to high photocurrent amplitudes, the Coccomyxa-rhodopsin was selected for an efficient mutagenesis study. This study allowed the identification of structural key determinants for the differences among proton pumps themselves and for the differences of proton pumps in comparison with light-gated ion channels (channelrhodopsins). Therefore, mutations of the counter-ion-complex cause inactive or purely passive transporters. The extracellular half-channel is the key element in proton pumps which prevents passive proton-backflow during the pump-cycle. Mutations in this region lead to passive leak-currents in overlap with the remaining pump-activity. Optogenetik mikrobielle Rhodopsine Protonenpumpe Protonenkanal Kanalrhodopsine optogenetics microbial rhodopsins proton pump proton channel channelrhodopsins 570 Biowissenschaften, Biologie 32 Biologie WE 5420 WD 2800 ddc:570

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