Global ETD Search

71	Biochemische und biophysikalische Charakterisierung von Rhodopsin-Guanylylzyklasen Scheib, Ulrike 19 March 2019 (has links) Rhodopsin-Guanylylzyklasen (RhGC) sind einzigartige Photorezeptoren, die kürzlich in Pilzen der Abteilung Blastocladiomycota entdeckt wurden [1]. RhGCs gehören zu den Enzym-Rhodopsinen und die Licht-sensitive mikrobielle Rhodopsin Domäne ist kovalent mit einer Typ III Guanylylzyklase verbunden. Guanylylzyklasen bilden den sekundären Botenstoff cGMP, der zusammen mit cAMP eine Vielzahl biologischer Prozesse reguliert [2–12]. In der vorliegenden Arbeit wurden die fünf neu-entdeckten RhGCs mithilfe unterschiedlicher biochemischer und biophysikalischer Methoden charakterisiert. Elektrophysiologische Messungen erbrachten einen indirekten Nachweis für eine Grünlicht-aktivierte cGMP Synthese bei den RhGCs aus Blastocladiella emersonii (Be) und Catenaria anguillulae (Ca). Die Licht-aktivierte Guanylylzyklasen Funktion dieser RhGCs konnte durch ELISA Experimente und nach Aufreinigung der Photorezeptoren bestätigt werden. Belichtung führte zu einer 100-fachen oder 200-fachen Erhöhung von cGMP mit einem vmax von 1.8 oder 11.6 µmol/min/mg(Protein) bei BeRhGC oder CaRhGC. Im Dunkeln verblieb bei beiden Photorezeptoren die cGMP-Konzentration auf dem Niveau von Kontrollzellen. Durch eine enzymkinetische Analyse der isolierten Guanylylzyklase Domänen (Be/CaGC) konnte die konstitutive Aktivität der enzymatischen Einheit gezeigt werden, die im Vergleich zu den Volllängen Photorezeptoren 3-6x reduziert war. Weiterhin wurden die Photozyklen der isolierten Rhodopsin Domänen mithilfe spektroskopischer Methoden untersucht und Photointermediate identifiziert, die typisch für mikrobielle Rhodopsine sind. Die M-Intermediate zerfielen langsam mit τ ~ 100 ms bei BeRh und τ ~ 500 ms bei CaRh. Um die kinetischen und spektroskopischen Parameter der Photorezeptoren zu verändern, wurden die Be/Ca Rhodopsin Domänen mutiert. Zusätzlich wurde die Substratspezifität der RhGCs geändert und eine Doppelmutation (E497K/C566D) in der katalytischen Domäne erzeugte Rhodopsin-Adenylylzyklasen (RhACs). Die Licht-induzierte cAMP Synthese der RhACs wurde in Xenopus Oocyten getestet und im Vergleich zu BeRhAC zeigte CaRhAC eine erhöhte Licht-zu-Dunkel-Aktivität (6x) einhergehend mit einer verringerten Dunkelaktivität (5.5x). Um weitere Einblicke in die kürzlich entdeckten RhGCs zu erhalten, wurden die isolierten Zyklase Domänen, Be/CaGC und CaAC, in Gegenwart von NTP Analoga kristallisiert. Neben hochauflösenden monomeren GC Strukturen ohne Ligand wurde eine 2.25 Å Struktur der mutierten Zyklase, CaAC, mit dem ATP Analogon ATPαS gelöst. Die CaAC Struktur zeigt ein antiparalleles Arrangement der Dimer-Untereinheiten und die Bindung der Nukleotidbase durch die zuvor mutierten Reste. Aufgrund der Ähnlichkeit zu anderen Typ III Zyklasen kann auf einen klassischen Reaktionsablauf bei RhGCs rückgeschlossen werden. Abschließend wurde die Anwendbarkeit von Ca/BeRhGC sowie CaRhAC in hippokampalen Rattenneuronen und CHO Zellen getestet. Diese Experimente zeigen, dass sowohl RhGCs als auch YFP-CaRhAC als optogenetische Werkzeuge eingesetzt werden können, um die Zellbotenstoffe cGMP bzw. cAMP präzise mit Licht zu regulieren. / Rhodopsin-guanylyl cyclases (RhGC) are unique photoreceptors recently discovered in Blastocladiomycota fungi [1]. In RhGCs the light-sensitive microbial rhodopsin domain is covalently linked to a type III guanylyl cyclase. Guanylyl cyclases form the second messenger cGMP, which together with cAMP regulates a variety of biological processes [2–12]. Due to their architecture, RhGCs are classified as microbial enzyme rhodopsins. In the present work, the five newly discovered RhGCs were characterized using different biochemical and biophysical methods. Electrophysiological measurements provided indirect evidence for green light-activated cGMP synthesis of the RhGCs from Blastocladiella emersonii (Be) and Catenaria anguillulae (Ca). The light-activated guanylyl cyclase function could be confirmed by ELISA experiments and after purification of these photoreceptors. Green illumination led to a 100-fold or 200-fold increase in cGMP with a vmax of 1.8 or 11.6 µmol/min/mg(protein) for BeRhGC or CaRhGC. In the dark the cGMP concentration remained at the level of control cells for both photoreceptors. A kinetic analysis of the isolated guanylyl cyclase domains (Be/CaGC) revealed the constitutive activity of the enzymatic domain, which was 3-6x reduced compared to the full-length photoreceptors. A spectroscopic characterization of the Be/Ca rhodopsin domains allowed the identification of photocycle intermediates, which are typical for microbial rhodopsins. The M-intermediates decayed slowly with a τ ~ 100 ms for BeRh and τ ~ 500 ms for CaRh. The Be/Ca rhodopsin domains were mutated to change the kinetic and spectroscopic parameters of the photoreceptors. In addition, the substrate specificity of the RhGCs was switched to ATP by a double mutation (E497K/C566D) in the catalytic domain. The light-induced cAMP synthesis of the generated rhodopsin-adenylyl cyclases (Be/CaRhACs) was shown in Xenopus oocytes and after purification of the proteins. Compared to BeRhAC, CaRhAC showed an increased light-to-dark activity (6x) and a decreased activity in darkness (5.5x). To get further insight into the recently discovered RhGCs, the isolated cyclase domains, Be/CaGC and CaAC, were crystallized in the presence of NTP analogues. High-resolution monomeric GC structures without a bound ligand were produced. Additionally, a 2.25 Å structure of the mutated cyclase, CaAC, with the ATP analogue ATPαS was solved. The CaAC structure shows an antiparallel arrangement of the dimer subunits and the nucleotide base is bound by the previously mutated residues. Due to the similarity to other type III cyclases, a classical reaction sequence for RhGCs can be deduced. Finally, the applicability of Ca/BeRhGC and CaRhAC was tested in hippocampal rat neurons and CHO cells. These application-oriented approaches show that both RhGCs and YFP-CaRhAC can be used as optogenetic tools to precisely control cGMP and cAMP with light. Photorezeptor mikrobielles Rhodopsin Zyklase cNMP photoreceptor microbial rhodopsin cyclase cNMP 572 Biochemie WE 5260 WD 2800 WD 5100 ddc:572
72	Incorporation, polarization and maturation of human photoreceptor transplants in the mouse retina Tessmer, Karen 18 April 2023 (has links) Photoreceptors are highly specialized neurons within the eye and the key retinal cells sensing light. They are indispensable for our visual perception and loss of photoreceptors consequently leads to loss of vision, a sense that alone is responsible for more than 30% of the input to our brain. Vision impairment and blindness is a leading cause of disability in the industrialized world and is in many cases ultimately due to a degeneration of the photoreceptors, which cannot be halted or reversed. Retinal degenerative diseases encompass a heterogeneous group of etiologies, mainly caused by various mutations in a plethora of proteins involved in the visual process. Currently, several therapeutic options are being explored, with so far one gene therapy for a rare inherited blinding condition being clinically approved. However, the gene therapy approach requires not only the presence of remaining photoreceptors but the tailoring of the therapy to each individual mutation. An alternative, more generally applicable approach is to restore vision through photoreceptor replacement therapy. As such, research on mouse-to-mouse photoreceptor transplantations has been carried out for many years, though with mixed results. In the last decade, it has however also become possible to generate large quantities of human photoreceptors through retinal organoid technology, allowing to instead transplant human cells. While promising, this field is still in development and principal conditions for successful photoreceptor transplantation have yet to be defined. Here, human-to-mouse photoreceptor transplantations were performed and assessed with the aim to receive insights into retinal cell replacement technology with specific focus on photoreceptor maturation, polarization and functional integration. Using a cone-degeneration host line, large-scale incorporation of human photoreceptor grafts into the murine retina was shown for the first time. It was found that for human photoreceptors, the choice of developmental stage strongly affects incorporation and maturation capacity. Furthermore, the results demonstrate the necessity of adequate graft-host interaction for successful transplant maturation and function, suggesting that photoreceptor replacement strategies might benefit from transplantation in earlier rather than late stages of retinal degeneration. Taken together, this thesis lays important groundwork for the further development of human photoreceptor replacement strategies to treat retinal degenerative disease.:ACKNOWLEDGEMENTS I ABSTRACT III ZUSAMMENFASSUNG V PUBLICATIONS VII TABLE OF CONTENTS IX LIST OF FIGURES XIII LIST OF TABLES XIV GENERAL ABBREVIATIONS XV GENE AND PROTEIN ABBREVIATIONS XVII 1 INTRODUCTION 1 1.1 THE RETINA AND LIGHT PERCEPTION 1 1.1.1 General structure of the eye 1 1.1.2 General structure of the retina 1 1.1.3 General photoreceptor structure 3 1.1.4 Phototransduction 4 1.1.5 Signal transmission to the brain 6 1.1.6 Major differences between rods and cones 7 1.1.7 The role of Müller glia in photoreceptor support and light perception 9 1.2 RETINAL DEGENERATION DISEASES AND TREATMENT OPTIONS 11 1.2.1 Retinal degeneration diseases 11 1.2.2 Therapeutic approaches to treat retinal degeneration diseases 12 1.3 CELL REPLACEMENT AS TREATMENT APPROACH FOR RETINOPATHIES 14 1.3.1 Transplantations of rodent retinal tissue and cells 14 1.3.2 Transplantations of human retinal tissue and cells 17 1.4 AIM OF THIS THESIS 22 2 CHARACTERIZATION OF CRX-MCHERRY HUMAN RETINAL ORGANOIDS AS PHOTORECEPTOR CELL SOURCE 23 2.1 AIMS 23 2.2 CHARACTERIZATION OF CRX-MCHERRY REPORTER-EXPRESSING CELLS 23 2.2.1 Crx-mCherry expression overlaps with endogenous CRX expression and increases over time 23 2.2.2 Crx-mCherry organoids contain an outer and an inner nuclear layer 24 2.2.3 Crx-mCherry+ cells express early and mature rod and cone markers 25 2.2.4 Crx-mCherry+ cells do not express proliferation markers 27 2.3 ENRICHMENT AND CHARACTERIZATION OF CRX-MCHERRY+ DONOR CELLS 28 2.3.1 Enrichment of Crx-mCherry+ cells by FACS 28 2.3.2 Characterization of Crx-mCherry enriched cells by single cell sequencing 29 2.3.3 Characterization of D200 Crx-mCherry-enriched cells by immunocytochemistry 30 2.4 SUMMARY 31 3 TRANSPLANTATION OF HUMAN CRX-MCHERRY+ GRAFTS AGED D100, D200 AND D300 INTO CPFL1 MICE 33 3.1 AIMS 33 3.2 CRX-MCHERRY+ CELLS OF ALL AGES CAN BE TRANSPLANTED AND SURVIVE IN THE MURINE RETINA 33 3.2.1 Human grafts can be identified by RCVRN staining 34 3.2.2 D100 Crx-mCherry+ transplants are larger than D200 and D300 grafts 34 3.2.3 Graft volume increase over time is not due to in vivo proliferation 36 3.3 GRAFT MORPHOLOGY DIFFERS WITH DONOR AGES 37 3.3.1 Human grafts can adopt an intraretinal position 37 3.3.2 Graft positioning changes over time 37 3.3.3 Qualitative differences in graft morphology between donor ages 38 3.4 GRAFT MATURATION 41 3.4.1 D200 but not D100 or D300 grafts develop large quantities of inner segments 41 3.4.2 Inner segment development is associated with close proximity to the host retina 42 3.5 HUMAN IDENTITY OF INTRARETINAL GRAFTS 43 3.5.1 Intraretinal Crx-mCherry+ grafts are largely a result of true morphological incorporation 43 3.5.2 Rare indications of potential human-to-mouse material transfer 45 3.6 SUMMARY 47 4 IN DEPTH CHARACTERIZATION OF TRANSPLANTED D200 CRX-MCHERRY+ CELLS 49 4.1 AIMS 49 4.2 EARLY POST TRANSPLANTATION DYNAMICS IN GRAFT POSITIONING AND GRAFT-HOST INTERACTIONS 49 4.2.1 Intraretinal and proximal D200 grafts interact with the host retina while isolated and distal clusters show only little interaction 49 4.2.2 Incorporation of D200 grafts is first evident at 8 weeks post transplantation 50 4.2.3 Host Müller glia extend processes into the graft before host bipolar cells 51 4.2.4 MG staining in D200 grafts originates from host MG 51 4.3 INCORPORATING D200 GRAFTS POLARIZE AND FORM STRUCTURES OF MATURE PHOTORECEPTORS 53 4.3.1 Grafts and host form an outer limiting membrane (OLM)-like structure 53 4.3.2 Inner segment formation occurs where an OLM is formed 54 4.3.3 Incorporating grafts form outer segment-like structures 55 4.3.4 Incorporating grafts form synaptic structures 57 4.3.5 Transplanted Crx-mCherry+ cells become enriched for cones 58 4.3.6 Higher levels of mature photoreceptor markers in ex vivo compared to in vitro cones 60 4.4 INCORPORATION AND MATURATION CAPACITY DEPEND ON THE HOST ENVIRONMENT 63 4.4.1 Graft morphology and maturation in C57BL/6JRj recipients resembles that in Cpfl1 hosts 63 4.4.2 Graft morphology and maturation in highly degenerated rd1 and tgCR host lines differs strongly from the outcome in models with an ONL 63 4.5 SUMMARY 67 5 FUNCTIONAL ASSESSMENT OF TRANSPLANTED CRX-MCHERRY+ CELLS 69 5.1 AIMS 69 5.2 HIGH-LEVEL FUNCTION 69 5.2.1 Light-Dark Box 69 5.3 TISSUE-LEVEL FUNCTION 71 5.3.1 Multi-electrode array assessment of D200+26w grafts in Cpfl1 mice 71 5.3.2 Isolation of cone-mediated RGC response through photopic light stimulation and L-AP4 addition 71 5.3.3 Graft-containing retinal portions exhibit cone-mediated light responses 72 5.4 SUMMARY 74 6 DISCUSSION AND FUTURE PERSPECTIVES 75 6.1 HUMAN GRAFTS CAN MORPHOLOGICALLY INCORPORATE INTO THE MODERATELY DEGENERATED MOUSE RETINA 75 6.2 INTRARETINAL GRAFTS MOSTLY REPRESENT TRUE INCORPORATION EVENTS, NOT MATERIAL TRANSFER 76 6.3 GRAFT MATURATION DEPENDS ON GRAFT-HOST INTERACTION 77 6.4 ESTABLISHMENT OF GRAFT-HOST INTERACTION AND GRAFT INCORPORATION 78 6.5 D200 CRX-MCHERRY+ CELLS ARE THE PREFERABLE DONOR POPULATION COMPARED TO D100 AND D300 80 6.6 CONES SHOW PREFERENTIAL SURVIVAL POST GRAFTING 81 6.7 FUNCTIONAL ANALYSES OF TRANSPLANTED ANIMALS 82 6.8 FUTURE CLINICAL TRANSLATION 85 6.9 MAJOR CONTRIBUTION TO OTHER WORK 88 7 FINAL CONCLUSION 89 8 MATERIALS AND METHODS 91 8.1 STUDY APPROVAL 91 8.2 MATERIALS 91 8.2.1 Materials and Chemicals 91 8.2.2 Cell Line 92 8.2.3 Mouse Lines 92 8.2.4 Antibodies 93 8.3 METHODS 95 8.3.1 Cell culture 95 8.3.2 Transplantations 96 8.3.3 Functional analyses 98 8.3.4 Immunohistochemistry and Immunocytochemistry 100 8.3.5 Imaging and image processing 103 8.3.6 Statistics 106 8.3.7 Single cell sequencing 107 8.3.8 Bioinformatic analysis 108 9 BIBLIOGRAPHY 111 10 APPENDIX 128 10.1 APPENDIX 1: ERKLÄRUNGEN ZUR ERÖFFNUNG DES PROMOTIONSVERFAHRENS 128 10.2 APPENDIX 2: BESTÄTIGUNG ÜBER EINHALTUNG DER AKTUELLEN GESETZLICHEN VORGABEN 129 info:eu-repo/classification/ddc/610 ddc:610
73	CIRCADIAN PROTEOME CHANGES IN PHOTORECEPTOR OUTER SEGMENTS Leary, Dagmar Hajkova 30 July 2010 (has links) No description available. Biomedical Research Ophthalmology 18 O labeling photoreceptor outer segments membrane proteins proteomics light induced apoptosis cirdadian changes
74	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
75	Signal transformation at the input and output of the Drosophila visual system Morimoto, Mai January 2017 (has links) A key function of the nervous system is to sample data from the external world, generate internal signals, and transform them into meaningful information that can be used to trigger behaviour. In order to gain insight into the underlying mechanism for signal transformation, the visual system has been extensively studied: partly owing to the stimulus being reliably presentable, and the anatomy being well described. The Drosophila visual system is one such system, with the added advantage of genetic tractability. In this thesis, I studied the filtering property of visual neurons at two levels, biophysical and circuit levels. The first study looks at signal transformation at the biophysical level, at the input of the visual system, in photoreceptors. Voltage-gated potassium channels counteract the depolarization caused by opening of light sensitive channels, and the heterogeneous properties of their kinetics can fine-tune the photoreceptor’s frequency response to fulfill the animal’s ecological requirements. Shaker (Kv1) and Shab (Kv2) have been identified as fast and slow inactivating components of the photoreceptor’s outward currents, however a current with intermediate kinetics (IKf) has not been molecularly identified, but had been postulated to be Shal (Kv4). I focused on characterizing this current using whole-cell patch clamp in wild type and mutants, and using antibodies for Shal. My results from whole-cell patch clamp indicated that IKf in adult R1-6 cells are not Shal, from their voltage dependence and insensitivity to a Kv4 blocker. This calls for alternative molecular basis for IKf, which is likely to be a slow inactivating component of Shaker, or a combination of its many splice variants. The second study looks at signal transformation at the circuit level, at the output end, in the third optic neuropil, lobula. Visual projection neurons project from the lobula to the central brain, and have been proposed to carry behaviourally relevant visual features to higher brain regions. It was recently shown that optogenetic activation of individual visual projection neuron types could induce distinct behaviours such as takeoff and backward walking, linking these visual neurons to specific behavioural programs downstream. Using in vivo two-photon calcium imaging, I recorded visually evoked calcium responses from three of these cell types. Cell types that showed induced takeoff and backward walking preferentially responded to dark looming stimuli or fragmented expanding local features, suggesting their role in behaviours triggered by object approach. To explore how this visual information is transformed in the downstream circuit, we identified several candidate neurons that receive input from this cell type by anatomical overlap, and then validated their connections using optogenetic activation and calcium imaging. One downstream cell-type that projects bilaterally had very similar response properties to its upstream partner, whereas another cell-type that projects ipsilaterally seemed to filter out some information from its upstream partner. This is one of the first studies that functionally characterizes lobula visual projection neurons and their downstream partners in Drosophila, and their response properties agree with the general idea that visual information becomes increasingly selective as it is sent to higher brain regions. 612.8
76	Genetic and biochemical analysis of zebrafish with visual function defects / Taylor, Michael Robert. January 2002 (has links) Thesis (Ph. D.)--University of Washington, 2002. / Vita. Includes bibliographical references (leaves 74-81).
77	Caractérisation des propriétés antiprolifératives d'une substance naturelle et rôle de la signalisation calcique dans la différenciation des photorécepteurs / Characterization of the anti-proliferative properties of a natural substance and role of calcium signaling in photoreceptor differentiation Dejos, Camille 14 October 2014 (has links) 1/ Évaluation de l'activité anti-proliférative de la canthin-6-oneLa canthin-6-one est un alcaloïde d'origine végétale dont les propriétés antipyrétique et antiparasitaire sont utilisées en médecine traditionnelle. Une meilleure connaissance de ses propriétés anti-prolifératives et de son mode d'action sont nécessaires. Nous avons observé une inhibition complète de la prolifération de lignées cancéreuses en présence de canthin-6-one ayant pour origine une accumulation des cellules dans la phase G2/M du cycle cellulaire. La conservation phylogénétique des mécanismes du cycle cellulaire nous a permis d'utiliser la levure Saccharomyces cerevisiae pour rechercher des gènes cibles de la canthin-6-one. Nous avons identifié deux gènes de résistance correspondants à une pompe d'efflux et à une enzyme impliquée dans le contrôle qualité de la réplication à la transition G2-M.2/ Rôle de la signalisation calcique dans la différenciation des photorécepteursUne meilleure connaissance des mécanismes de différenciation des photorécepteurs est importante pour la lutte contre les dégénérescences rétiniennes. Un délai d'une semaine, entre la détermination des précurseurs de photorécepteurs et l'activation transcriptionnelle de gènes de fonction, suggère l'attente d'un signal important pour cette étape de la différenciation. Par une approche pharmacologique in vitro, nous avons pu montrer que l'activation du gène de la rhodopsine dépend d'une voie de signalisation impliquant un canal activé en hyperpolarisation (HCN), des canaux calciques de type T ou R et de l'activité de la kinase calmoduline-dépendante. Le profil d'expression du canal HCN1 dans la rétine embryonnaire suggère qu'il pourrait jouer un rôle limitant dans ce mécanisme. / 1/ Evaluation of canthin-6-one anti-proliferative properties Canthin-6-one is an alkaloid molecule produced by tropical plants used in traditional medicine for its antipyretic and antiparasitic properties. Evidence-based medicine requires better knowledge of canthin-6-one's anti-proliferative effects and mode of action. In the presence of canthin-6-one, we demonstrated a complete growth inhibition of human cancer cells due to the accumulation of cells in the G2/M phases of the cell cycle. Cell cycle pathways being evolutionarily conserved in eukaryotes, we used the yeast Saccharomyces cerevisiae as a model system to further analyze the mode of action of canthin-6-one. A yeast genomic library was screened for suppressors of canthin-6-one toxicity and two resistance genes were identified. One encodes a transporter, probably involved in canthin-6-one efflux. The other one encodes an enzyme involved in DNA quality control.2/ Role of calcium signaling in photoreceptor differentiationThe design of new treatments for retinal degenerations should benefit from better knowledge of photoreceptor differentiation. During retinal differentiation in chicken embryos there is a long time lag between commitment to the photoreceptor fate and transcriptional activation of rhodopsin gene, suggesting committed precursors are in a standby state waiting for a signal to activate opsin gene expression. We demonstrate by a pharmacological approach in vitro that rhodopsin gene activation depends on a signaling pathway involving hyperpolarisation-activated channels (HCN), T- or R-type calcium channels and calmodulin-dependent protein kinase. The expression profile of HCN1 in the embryonic retina suggests it may be a limiting factor for rhodopsin gene activation. Canthin-6-One Cancer Cycle cellulaire Levure Résistance Différenciation Photorécepteur Opsine Calcium Hcn Canthin-6-One Cancer Cell cycle Yeast Résistance Differentiation Photoreceptor Opsin Calcium Hcn 571.6
78	Světelný zdroj s nastavitelnou intenzitou osvětlení / A light source with variable intensity Koždoň, Jakub January 2014 (has links) This work is focused on description how the light impact human live, description of light sources and finally design and construction of light source with adjustable colour temperature and luminous flux. In introduction is mentioned the process of vision and how the light impact humans. In next part is characterization of currently used light sources, their construction, properties, benefits and drawback with their main parameters. Important part of this chapter is more extensive description of light emitting diodes with their operational parameters. The last two parts is focused on design and measuring the parameters of created light source with adjustable colour temperature and luminous flux and evaluating the results.
79	Genetic Signatures of the Retina in Health and Disease Mustafi, Debarshi 23 August 2013 (has links) No description available. Pharmacology Genetics Biogeochemistry Cellular Biology Health Sciences Medicine Retina Vision Photoreceptor LincRNA RNA-Seq Non-coding Enhanced S-cone syndrome Complex diseases Systems biology Genetics Inflammation
80	MAS NMR on a Red/Far-Red Photochromic Cyanobacteriochrome All2699 from Nostoc Xu, Qian-Zhao, Bielytskyi, Pavlo, Otis, James, Lang, Christina, Hughes, Jon, Zhao, Kai-Hong, Losi, Aba, Gärtner, Wolfgang, Song, Chen 10 January 2024 (has links) Unlike canonical phytochromes, the GAF domain of cyanobacteriochromes (CBCRs) can bind bilins autonomously and is sufficient for functional photocycles. Despite the astonishing spectral diversity of CBCRs, the GAF1 domain of the three-GAF-domain photoreceptor all2699 from the cyanobacterium Nostoc 7120 is the only CBCR-GAF known that converts from a red-absorbing (Pr) dark state to a far-red-absorbing (Pfr) photoproduct, analogous to the more conservative phytochromes. Here we report a solid-state NMR spectroscopic study of all2699g1 in its Pr state. Conclusive NMR evidence unveils a particular stereochemical heterogeneity at the tetrahedral C31 atom, whereas the crystal structure shows exclusively the R-stereochemistry at this chiral center. Additional NMR experiments were performed on a construct comprising the GAF1 and GAF2 domains of all2699, showing a greater precision in the chromophore–protein interactions in the GAF1-2 construct. A 3D Pr structural model of the all2699g1-2 construct predicts a tongue-like region extending from the GAF2 domain (akin to canonical phytochromes) in the direction of the chromophore, shielding it from the solvent. In addition, this stabilizing element allows exclusively the R-stereochemistry for the chromophore-protein linkage. Site-directed mutagenesis performed on three conserved motifs in the hairpin-like tip confirms the interaction of the tongue region with the GAF1-bound chromophor info:eu-repo/classification/ddc/570 ddc:570

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