FTIR-spektroskopische Untersuchungen zum Aktivierungsmechanismus von bovinem und humanem Rhodopsin

Kazmin, Roman

13 August 2015

Das aus dem Apoprotein Opsin und dem kovalent gebundenen Liganden bestehende Rhodopsin dient als Modellsystem für den Aktivierungsmechanismus der größten Klasse von G-Protein-gekoppelten Rezeptoren (GPCR). Infolge einer photochemischen Reaktion vollführt Rhodopsin eine Bewegungsabfolge von Sekundärstrukturelementen, wodurch es aktiviert wird, das G-Protein bindet und den Stimulus auf zellinterne Signalwege überträgt. Mithilfe der ortsspezifischen Mutagenese wurden Mutanten des bovinen Rhodopsins erzeugt, in eine künstliche Lipidumgebung eingelagert und hauptsächlich mittels FTIR-Spektroskopie untersucht. Anhand der Y191F- und Y192F-Mutanten konnte die Translokation des transienten Gegenions der Schiffschen Base Glu181 während der Aktivierung bestimmt werden. Die Interaktionen des Tyr206 sind für die gekoppelte Bewegung von EL2 und TM5 mitbestimmend, was mittels Y206F-Mutante gezeigt wurde. Eine Anhäufung von Methioninen auf der cytoplasmatischen Seite des Rezeptors ist u.a. für das Ausklappen der TM6 zuständig. Diese Bewegung ist wichtige Determinante der Rezeptoraktivierung. Hierfür wurden insgesamt fünf Mutanten verwendet. Im zweiten, hauptsächlichen Teil der Arbeit wird das bislang kaum untersuchte humane Rhodopsin mit dem bovinen Rezeptor verglichen. Ausgehend von verschiedenen Dunkelzuständen, konnte gezeigt werden, dass die Aktivierungsmechanismen beider Rezeptoren voneinander divergieren, um letztlich bei der Bildung der aktiven Spezies wieder zu konvergieren. Über die Analyse der Aminosäuresequenzen der Mammalia-Rhodopsine wurden zwei Bereiche hoher Variabilität identifiziert, die u.a. die molekulare Ursache für diese Diskrepanzen liefern. Diese Feststellung wurde mit human-bovinen-Rhodopsinchimären bewiesen. Ergänzend zu dieser Studie wurde Schafsrhodopsin einem Vergleich sowohl mit bovinem als auch mit humanem Rezeptor unterzogen. Es zeigte, als eine weitere natürlich vorkommende Variante des Lichtrezeptors, einen eigenständigen Weg der Aktivierung. / Rhodopsin, which consists of the apoprotein opsin and its covalently bound ligand, is used as a model system to understand the activation mechanism of the large family of G protein coupled receptors (GPCRs). As a result of a photochemical reaction, rhodopsin undergoes activating structural changes, enabling it to bind the G protein and transmitting the stimulus to intracellular signaling pathways. In the first part of this work, site-directed mutants of bovine rhodopsin were produced, incorporated into an artificial lipid environment, and studied mainly by FTIR spectroscopy. The translocation of the transient Schiff base counterion (Glu181) during the activation process was determined using the Y191F- and Y192F-mutants. The interactions of Tyr206 contributed to the coupled movement of EL2 and TM5, which was shown by Y206F-mutant. A striking accumulation of methionines on the cytoplasmic side of the receptor was observed to be a key-player for the activating outward motion of TM6. In the second and primary part of this work, human rhodopsin, which has been rarely studied, was compared with the bovine receptor. Starting from various dark states, it was shown that the activation mechanisms of both receptors diverge from each other and yet ultimately converge in the formation of the active species. By analyzing the amino acid sequences of mammalian rhodopsins, two regions of high variability were identified, which provide the molecular basis for these discrepancies. This finding was verified by the investigation of human/bovine rhodopsin chimeras. In addition to this study, ovine rhodopsin was compared with both the bovine and human forms. It showed, as another naturally occurring variant of the light receptor, an independent pathway of activation.

GPCR

FTIR-Spektroskopie

Rezeptoraktivierung humanes Rhodopsin

UV/Vis-Spektroskopie

ortsspezische Mutagenese

Tyrosin

GPCR

FTIR-spectroscopy

receptor activation

human rhodopsin

UV/Vis-spectroscopy

site-directed mutagenesis

tyrosine

570 Biologie

32 Biologie

WE 5240

ddc:570

Der Einfluss des Cholesterolgehaltes der Diskmembranen des Stäbchenaußensegmentes auf die ersten Schritte der visuellen Signaltransduktion

Waterstradt, Katja

17 July 2009

Das Außensegment der Stäbchenzelle ist aus einem Stapel von flachen Membransäckchen, den Diskmembranen, aufgebaut. Entlang dessen existiert ein Cholesterolgradient mit 24 mol% Cholesterol in den basalen Diskmembranen und 5 mol% in den apikalen. Das Außensegment enthält alle Proteine der Signaltransduktion. Der Photorezeptor Rhodopsin ist als integrales Membranprotein in die Diskmembran eingebettet. Das G-Protein Transducin und das Effektorprotein, die Phosphodiesterase (PDE), sind periphere Proteine mit Lipidankern und somit reversibel mit der Membranoberfläche assoziiert. Um den Einfluss des Cholesterolgehaltes der Diskmembranen auf diese drei Proteine zu untersuchen, wurden Diskmembranen mit unterschiedlichem Cholesterolgehalt präpariert (Simulation des Cholesterolgradienten). Die Untersuchungen zur transversalen Verteilung des Cholesterols in der Diskmembran ergaben eine schnelle Transmembranbewegung mit einer Halbwertzeit von weniger als einer Minute bei 35 °C. Desweiteren konnte gezeigt werden, dass es zu kopfgruppenspezifischen Wechselwirkungen von Cholesterol mit dem Phospholipid Phosphatidylcholin kommt. Cholesterol verschiebt das Meta I-Meta II-Gleichgewicht (nach Lichtaktivierung von Rhodopsin) auf die Seite von Meta I (inaktiv). In dieser Arbeit konnte jedoch gezeigt werden, dass durch die Anwesenheit des Transducins das Gleichgewicht vollständig auf die Seite von Meta II (aktiv) verschoben wird, da Transducin spezifisch die Meta-II-Form stabilisiert. Somit kann die verminderte Meta II-Bildung des Rezeptors in Diskmembranen mit hohem Cholesterolgehalt durch Transducin ausgeglichen werden. Lediglich die Geschwindigkeit der Transducinaktivierung ist verlangsamt. Durch den erhöhten Cholesterolgehalt werden die Membraneigenschaften für eine Bindung der beiden peripheren Proteine Transducin und PDE über deren Lipidanker optimiert. Somit kann die Signaltransduktion auch in den basalen Diskmembranen des Stäbchenaußensegmentes stattfinden. / The rod outer segment consists of a stack of flat membrane saccules called disc membranes. Along this stack a cholesterol gradient exists with 24 mol% cholesterol in the basal and only 5 mol% in the apical disc membranes. The outer segment contains all the proteins necessary for signal transduction. The photoreceptor rhodopsin as integral membrane protein is embedded in the disc membrane. The G protein transducin and the effector protein phosphodiesterase (PDE) are soluble proteins with lipid modifications, which are associated reversibly to the membrane surface. Disc membranes with different cholesterol contents were prepared to simulate the cholesterol gradient along the rod outer segment and to investigate the influence of disc membrane cholesterol content of these three proteins. Investigations of the transversal distribution of cholesterol in the disc membrane revealed a fast transmembrane movement with a half life of less than one minute at 35 °C. Further, head group specific interactions between cholesterol and phosphatidylcholine could be shown. The Meta I Meta II equilibrium after light activation of rhodopsin was shifted to the Meta I (inactive) site in membranes with high cholesterol. In this work it was shown that in the presence of transducin this equilibrium is shifted completely to the Meta II (active) site because transducin stabilizes specifically the Meta II form of the receptor. Hence the reduced Meta II formation in disc membranes with high cholesterol could be compensated by transducin. The speed of transducin activation is decelerated. By the increased cholesterol content membrane properties are optimized to the binding of transducin and PDE via their lipid modifications. Thus the signal transduction can take place also in disc membranes with high cholesterol.

Cholesterol

Signaltransduktion

Diskmembranen

Lipid-Protein-Wechselwirkung

Stäbchenaußensegment

Transducin

Rhodopsin

cholesterol

signal transduction

disc membrane

protein lipid interaction

rod outer segment

transducin rhodopsin

570 Biologie

32 Biologie

WE 5320

WW 1820

ddc:570

Efeito de α-MSH sobre a expressão gênica de rodopsina, tirosinase e do receptor de α-MSH, subtipo MC1R, em melanócito B16 de Mus musculus / α-MSH effects on rhodopsin, tyrosinase and MC1R genes in B16 Mus musculus melanocytes

Glória, Thiago Henrique Ribeiro

03 September 2012

A coloração dos vertebrados deve-se a presença de pigmentos, sintetizados e/ou armazenados em células denominadas células pigmentares cutâneas. A mudança de cor nos vertebrados é principalmente regulada por α-MSH e uma família de enzimas melanossômicas, que incluem tirosinase e as proteínas relacionadas à tirosinase 1 e 2 (TRP-1 e TRP-2, respectivamente). Sua ação está ligada à dispersão dos melanossomos ou síntese de melanina, processos que resultam em escurecimento do animal, enquanto a agregação ou inibição de síntese leva ao seu empalidecimento. Opsinas, como a melanopsina e a rodopsina, além de presentes na retina, podem ser expressas em células pigmentares cutâneas, intermediando foto-respostas de proliferação e de dispersão de melanossomos. O objetivo deste trabalho foi investigar a expressão temporal da rodopsina, tirosinase e do receptor MC1R, bem como os efeitos do tratamento com α-MSH 10-7 M, 10-8 M e 10-9 M por 24 horas sobre esses parâmetros, em melanócitos B16 de Mus musculus, mantidos em escuro constante. Através de PCR em tempo real (quantitativo) demonstrou-se que α-MSH 10-7 M não modula os níveis de mRNA para o receptor MC1R quando comparado com o grupo controle, contudo há uma evidente tendência de redução dos níveis do transcrito. Todavia, na concentração de 10-8 M, observou-se um aumento estatisticamente significativo no nível do transcrito na hora 20 quando comparado ao grupo controle e na concentração de 10-9 M o tratamento mostrou uma diminuição estatisticamente significativa no nível do transcrito entre o grupo controle e o tratado para cada ponto temporal analisado. Para a rodopsina, foi demonstrado que &alpha-MSH 10-7 M modula os níveis do mRNA quando comparado ao grupo controle, mostrando uma diminuição estatisticamente significativa na hora 0 e 16. Na concentração de 10-8 M houve um aumento estatisticamente significativo nos níveis do transcrito na hora 4 quando comparado ao grupo controle. Já, na concentração de 10-9 M, o hormônio induziu um robusto aumento no nível do transcrito quando comparado ao grupo controle para cada ponto temporal analisado. Nossos resultados são pioneiros em demonstrar a modulação de rodopsina por α-MSH, pois não há dados na literatura, seja em retina ou em outros tecidos, que tenham investigado essa ação do hormônio melanotrópico. O mesmo padrão foi observado para a tirosinase, demonstrando uma diminuição estatisticamente significativa na concentração de 10-7 M na hora 0 e um aumento significativo na concentração de 10-8 M na hora 8 e na concentração de 10-9 M na hora 12 e 8. Através de PCR em tempo real (quantitavo) nós demonstramos que α-MSH apresenta uma modulação dose-dependente para o transcrito do mRNA do receptor MC1R, tirosinase e rodopsina, mas não sincronizou a expressão desses genes, que permaneceram arrítmicos / In vertebrates, skin color is given by pigments, synthesized and/or stored in cutaneous pigment cells. The vertebrate color change is mainly regulated by α-MSH and a family of melanosome enzymes, which includes tyrosinase and tyrosinaserelated proteins 1 and 2 (TRP-1 and TRP-2, respectively). α-MSH action is associated with melanosome dispersion or melanin synthesis, processes which lead to skin darkening, whereas melanin aggregation or synthesis inhibition results in skin lightening. Opsins, such as melanopsin and rhodopsin, may be expressed in skin pigment cells, besides being present in the retina, and mediate non visual photoresponses such as cell proliferation and melanosome dispersion. The aim of this study was to investigate the temporal expression of rhodopsin, tyrosinase and the receptor MC1R, as well as the effects of 10-7 M, 10-8 M and 10-9 M α-MSH for 24 hours in Mus musculus B16 melanocytes, kept in constant darkness. Using real time PCR (quantitative) we demonstrated that 10-7 M α-MSH does not modulate MC1R mRNA levels, as compared to the control group, although a tendency to reduction was evident. On the other hand, at the concentration of 10-8 M, we observed a statistically significant increase of the transcript level at the hour 20, as compared to the control group and at the concentration of 10-9 M the treatment showed a statistically significant decrease of the transcript level for each temporal point analyzed. For rhodopsin, we showed that 10-7 M α-MSH modulates mRNA levels, as compared to the control group, demonstrating a statistically significant decrease at the hour 0 and 16. At the concentration of 10-8 M there was a statistically significant increase of transcript levels at the hour 4, as compared to the control group. The hormone at 10-9 M induced a robust increase of the transcript levels, as compared to the control group, for each time point analyzed. Our results are pioneering in demonstrating the regulation of rhodopsin by α-MSH, since there are no data in the literature which report the action of melanotropic hormone on rhodopsin in either the retina or other tissues. Similar pattern was observed for the tyrosinase gene, demonstrating a statistically significant decrease in the concentration of 10-7 M at the hour 0 and a significant increase in the concentration of 10-8 M at the hour 8 and in the concentration of the 10-9 M at the hour 12 and 8. Using real time PCR (quantitative) we demonstrated that α-MSH shows a dose-dependent modulation for mRNA transcripts of the MC1R receptor, tyrosinase and rhodopsin, but the hormone was not able to synchronize the expression of these genes, which remained arhythmic

α-MSH

α-MSH

Células pigmentares

Mamíferos

Mammals

MC1R

MCIR

Melanin

Melanina

Pigment Cells

Rhodopsin

Rodopsina

Tirosinae

Tyrosinase

Characterization and Evolution of Transmembrane Proteins with Focus on G-protein coupled receptors in Pre-vertebrate Species

Nordström, Karl J. V.

January 2010

G protein-coupled receptors (GPCRs) are one of the largest protein families in mammals. GPCRs are instrumental for hormonal and neurotransmitter signalling and are important in all major physiological systems of the body. Paper I describes the repertoire of GPCRs in Branchiostoma floridae, which is one of the species most closely related species to vertebrates. Mining and phylogenetic analysis of the amphioxus genome showed the presence of at least 664 distinct GPCRs distributed among all the main families of GPCRs; Glutamate (18), Rhodopsin (570), Adhesion (37), Frizzled (6) and Secretin (16). Paper II contains studies of the Adhesion, Methuselah and Secretin GPCR families in nine genomes. The Adhesion GPCRs are the most complex gene family among GPCRs with large genomic size, multiple introns and a fascinating flora of functional domains. Phylogenetic analysis showed Adhesion group V (that contains GPR133 and GPR144) to be the closest relative to the Secretin family among the groups in the Adhesion family, which was also supported by splice site setup and conserved motifs. Paper III examines the repertoire of human transmembrane proteins. These form key nodes in mediating the cell’s interaction with the surroundings, which is one of the main reasons why the majority of drug targets are membrane proteins. We identified 6,718 human membrane proteins and classified the majority of them into 234 families of which 151 belong to the three major functional groups; Receptors (63 groups, 1,352 members), Transporters (89 groups, 817 members) or Enzymes (7 groups, 533 members). In addition, 74 Miscellaneous groups were shown to include 697 members. Paper IV clarifies the hierarchy of the main families and evolutionary origin of majority of the metazoan GPCR families. Overall, it suggests common decent of at least 97% of the GPCRs sequences found in humans, including all the main families.

G protein-coupled receptors

GPCR

Membrane protein

Rhodopsin

Adhesion

Secretin

Evolution

Bioinformatics

Phylogeny

Pharmacological research

Farmakologisk forskning

Bioinformatics

Bioinformatik

Photoreceptor cell fate determination and rhodopsin expression in the developing eye of Drosophila /

Birkholz, Denise A.

January 2005

Thesis (Ph.D. in Cell and Developmental Biology) -- University of Colorado at Denver and Health Sciences Center, 2005. / Typescript. Includes bibliographical references (leaves 139-155).

Efeito de α-MSH sobre a expressão gênica de rodopsina, tirosinase e do receptor de α-MSH, subtipo MC1R, em melanócito B16 de Mus musculus / α-MSH effects on rhodopsin, tyrosinase and MC1R genes in B16 Mus musculus melanocytes

Thiago Henrique Ribeiro Glória

03 September 2012

A coloração dos vertebrados deve-se a presença de pigmentos, sintetizados e/ou armazenados em células denominadas células pigmentares cutâneas. A mudança de cor nos vertebrados é principalmente regulada por α-MSH e uma família de enzimas melanossômicas, que incluem tirosinase e as proteínas relacionadas à tirosinase 1 e 2 (TRP-1 e TRP-2, respectivamente). Sua ação está ligada à dispersão dos melanossomos ou síntese de melanina, processos que resultam em escurecimento do animal, enquanto a agregação ou inibição de síntese leva ao seu empalidecimento. Opsinas, como a melanopsina e a rodopsina, além de presentes na retina, podem ser expressas em células pigmentares cutâneas, intermediando foto-respostas de proliferação e de dispersão de melanossomos. O objetivo deste trabalho foi investigar a expressão temporal da rodopsina, tirosinase e do receptor MC1R, bem como os efeitos do tratamento com α-MSH 10-7 M, 10-8 M e 10-9 M por 24 horas sobre esses parâmetros, em melanócitos B16 de Mus musculus, mantidos em escuro constante. Através de PCR em tempo real (quantitativo) demonstrou-se que α-MSH 10-7 M não modula os níveis de mRNA para o receptor MC1R quando comparado com o grupo controle, contudo há uma evidente tendência de redução dos níveis do transcrito. Todavia, na concentração de 10-8 M, observou-se um aumento estatisticamente significativo no nível do transcrito na hora 20 quando comparado ao grupo controle e na concentração de 10-9 M o tratamento mostrou uma diminuição estatisticamente significativa no nível do transcrito entre o grupo controle e o tratado para cada ponto temporal analisado. Para a rodopsina, foi demonstrado que &alpha-MSH 10-7 M modula os níveis do mRNA quando comparado ao grupo controle, mostrando uma diminuição estatisticamente significativa na hora 0 e 16. Na concentração de 10-8 M houve um aumento estatisticamente significativo nos níveis do transcrito na hora 4 quando comparado ao grupo controle. Já, na concentração de 10-9 M, o hormônio induziu um robusto aumento no nível do transcrito quando comparado ao grupo controle para cada ponto temporal analisado. Nossos resultados são pioneiros em demonstrar a modulação de rodopsina por α-MSH, pois não há dados na literatura, seja em retina ou em outros tecidos, que tenham investigado essa ação do hormônio melanotrópico. O mesmo padrão foi observado para a tirosinase, demonstrando uma diminuição estatisticamente significativa na concentração de 10-7 M na hora 0 e um aumento significativo na concentração de 10-8 M na hora 8 e na concentração de 10-9 M na hora 12 e 8. Através de PCR em tempo real (quantitavo) nós demonstramos que α-MSH apresenta uma modulação dose-dependente para o transcrito do mRNA do receptor MC1R, tirosinase e rodopsina, mas não sincronizou a expressão desses genes, que permaneceram arrítmicos / In vertebrates, skin color is given by pigments, synthesized and/or stored in cutaneous pigment cells. The vertebrate color change is mainly regulated by α-MSH and a family of melanosome enzymes, which includes tyrosinase and tyrosinaserelated proteins 1 and 2 (TRP-1 and TRP-2, respectively). α-MSH action is associated with melanosome dispersion or melanin synthesis, processes which lead to skin darkening, whereas melanin aggregation or synthesis inhibition results in skin lightening. Opsins, such as melanopsin and rhodopsin, may be expressed in skin pigment cells, besides being present in the retina, and mediate non visual photoresponses such as cell proliferation and melanosome dispersion. The aim of this study was to investigate the temporal expression of rhodopsin, tyrosinase and the receptor MC1R, as well as the effects of 10-7 M, 10-8 M and 10-9 M α-MSH for 24 hours in Mus musculus B16 melanocytes, kept in constant darkness. Using real time PCR (quantitative) we demonstrated that 10-7 M α-MSH does not modulate MC1R mRNA levels, as compared to the control group, although a tendency to reduction was evident. On the other hand, at the concentration of 10-8 M, we observed a statistically significant increase of the transcript level at the hour 20, as compared to the control group and at the concentration of 10-9 M the treatment showed a statistically significant decrease of the transcript level for each temporal point analyzed. For rhodopsin, we showed that 10-7 M α-MSH modulates mRNA levels, as compared to the control group, demonstrating a statistically significant decrease at the hour 0 and 16. At the concentration of 10-8 M there was a statistically significant increase of transcript levels at the hour 4, as compared to the control group. The hormone at 10-9 M induced a robust increase of the transcript levels, as compared to the control group, for each time point analyzed. Our results are pioneering in demonstrating the regulation of rhodopsin by α-MSH, since there are no data in the literature which report the action of melanotropic hormone on rhodopsin in either the retina or other tissues. Similar pattern was observed for the tyrosinase gene, demonstrating a statistically significant decrease in the concentration of 10-7 M at the hour 0 and a significant increase in the concentration of 10-8 M at the hour 8 and in the concentration of the 10-9 M at the hour 12 and 8. Using real time PCR (quantitative) we demonstrated that α-MSH shows a dose-dependent modulation for mRNA transcripts of the MC1R receptor, tyrosinase and rhodopsin, but the hormone was not able to synchronize the expression of these genes, which remained arhythmic

α-MSH

Células pigmentares

Mamíferos

MCIR

Melanina

Rodopsina

Tirosinae

α-MSH

Mammals

MC1R

Melanin

Pigment Cells

Rhodopsin

Tyrosinase

Molecular Dynamics Simulation Of Transmembrane Helices And Analysis Of Their Packing In Integral Membrane Proteins

Iyer, Lakshmanan K

09 1900

No description available.

Integral Membrane Proteins (IMPs)

Transmembrane Helices

Bacteriorhodopsin

Rhodopsin

Transmembrane Helix

Proline Helix I1

Proteins - Molecular Dynamics

Biochemistry

Photoentrainment of the Drosophila circadian clock through visual system / Synchronisation de l'horloge circadienne chez la Drosophile par le système visuel

Alejevski, Faredin

25 June 2018

La rotation de la Terre oblige les organismes vivants à s’adapter aux modifications cycliques de l’environnement, et tout particulièrement aux changements de lumière et de température. Des unicellulaires à l’Homme, la plupart des espèces ont développé des horloges circadiennes, qui leur permettent d’anticiper les transitions jour-nuit. La lumière constitue le signal majeur pour la synchronisation de l’horloge. En cycles jour-nuit, les drosophiles présentent un profil d’activité locomotrice bimodal, avec un premier pic autour de l’aube et le deuxième au crépuscule. Chez cet insecte, la perception de la lumière est assurée à la fois par un système complexe, constitué des yeux composés, des ocelles et de l’eyelet d’Hofbauer-Buchner. Ces organes contiennent des photorécepteurs (PRs) exprimant six protéines photosensibles différentes, les rhodopsines (Rh1 à Rh6). Une septième rhodopsine (Rh7) a été décrite dans quelques neurones de l’horloge cérébrale. La lumière est également perçue directement dans la plupart des neurones d’horloge grâce à une protéine photosensible, le cryptochrome (Cry). Les différentes études du rôle de la lumière sur l’entraînement de l’horloge ont essentiellement porté sur la voie cry-dépendante, en utilisant de courts flashs lumineux pour recaler l’horloge cérébrale. Notre étude s’est intéressée à l’entraînement de l’horloge via les rhodopsines. Quels types de photorécepteur sont impliqués ? Après l’activation de la cascade de phototransduction et la libération de l’histamine par les photorécepteurs, quels neurones, exprimant les récepteurs à l’histamine Ort et Hiscl1, participent à l’entraînement de l’horloge circadienne ? Une première partie présente l’étude de l’implication des 6 rhodopsines dans l’entraînement circadien. Tout d’abord, nous avons mis en évidence la fonction de photorécepteurs spécifiques (exprimant Rh1 ou Rh6) dans la voie NorpA-dépendante (Saint-Charles et al. J Comp Neurol 2016). Nous avons ensuite généré des lignées de drosophiles n’exprimant aucune ou qu’une seule rhodopsine. Sans rhodopsine ni Cry les mouches sont incapables de se synchroniser sur les cycles jour-nuit, quelle que soit l’intensité lumineuse. En lumière faible, l’input pour l’entraînement vient principalement des photorécepteurs exprimant Rh1 et Rh6. En forte lumière, chacune des 6 rhodopsines des différents photorécepteurs est capable d’entrainer l’horloge, Rh1, Rh5 et Rh6 étant les plus efficaces ( Alejevski et al., in prep). Une deuxième partie présente la caractérisation des voies neuronales connectant directement ou indirectement les PRs à l’horloge cérébrale. L’horloge circadienne de mouches mutantes, à la fois pour le cryptochrome et les 2 récepteurs à l’histamine, est « aveugle » alors que les mutantes pour Cry mais possédant l’un ou l’autre récepteur à l’histamine sont capables de se synchroniser sur les cycles de lumière. La ré-expression chez les mutants de Ort ou Hiscl1 dans les neurones d’horloge ne restaure pas l’entraînement, suggérant ainsi l’absence de connexions directes entre les PRs histaminergiques et les neurones d’horloge. Nos expériences de sauvetage comportemental mettent en évidence des connexions fonctionnelles entre certains interneurones Ort des lobes optiques et les neurones d’horloge. En revanche et de façon inattendue, nous n’observons d’entraînement circadien que lorsque nous ré-exprimons Hiscl1 dans les seuls PRs Rh6. Nos résultats révèlent que les photorécepteurs interviennent dans l’entraînement à la fois comme photorécepteurs et comme interneurones, cibles d’input histaminergique, rappelant ainsi le double rôle des cellules ganglionnaires de la rétine exprimant la mélanopsine chez les mammifères (Alejevski et al. Nat Commun, in revision). / The rotation of the earth forces living organisms to adapt to its cyclic environment, in particular light and temperature changes. From unicellular organisms to humans, almost all species have evolved circadian clocks, which allow them to anticipate day-night transitions and use light as the most powerful synchronizing cue. In light-dark cycles, D. melanogaster flies display a bimodal locomotor activity with peaks around dawn and dusk. To perceive light, Drosophila has evolved a complex visual system, composed of compound eyes, ocelli and Hofbauer-Buchner eyelet. These organs contain photoreceptors (PRs) expressing six different light receptors named rhodopsins (Rh1 to Rh6). In addition, one rhodopsin (Rh7) is found in some of the clock neurons in the brain. Most of the clock cells also express another type of light receptor, Cryptochrome (Cry). Most studies about clock entrainment by light have focused on the Cry-dependent light input, which allows short light pulses to reset the brain clock. The present thesis focuses on the entrainment of the brain clock through rhodopsins. In photoreceptors, rhodopsins capture photons and activate a transduction cascade, where a key player is the phospholipase C (PLC) encoded by norpA. Mutants deficient for Cry and NorpA do not synchronize at low light intensity but still entrain with high light, indicating that an unknown NorpA-independent pathway is also used by the clock. Light induces a depolarization of the PRs, which release histamine as a neurotransmitter, but their role in circadian entrainment is unknown. Which type of rhodopsine-expressing photoreceptors are implicated? After the phototransduction cascade activation and the release of histamine from the photoreceptors, which downstream neurons expressing the histamine-gated chloride channels Ort and Hiscl1 (whose function has been studied in the visual behavior) are involved in the circadian entrainment? The first part of the thesis was to study the function of the 6 PR rhodopsins in circadian entrainment. I first contributed to studying the function of the specific photoreceptors in the NorpA-dependent pathway (Saint-Charles et al. J Comp Neurol 2016). Then, we generated genotypes having either none or only one of the six PR rhodopsins. Mutants with no Cry and none of the 6 PR rhodopsins could not synchronize with light-dark (LD) cycles (low light or high light). In low light, Rh1 and Rh6 were the main light input for entrainment. In high-light, each one of the 6 PR rhodopsins can provide entrainment, with Rh1, Rh5 and Rh6 being the most efficient (Alejevski et al., in prep).The second part of the work was to identify the neuronal pathways that connect the PRs to the brain circadian clock. Flies deficient for Cry and the two histamine receptors are circadianly blind, whereas Cry mutants having either Ort or Hiscl1 are able to entrain. Thus, each one of the two receptors supports circadian entrainment. Rescuing Ort or Hiscl1 in the clock cells could not restore entrainment, indicating that there is no direct histaminergic connection between PRs and clock neurons. Our rescue experiments revealed several pathways in otic lobes that rely on Ort-expressing interneurons to entrain the clock. In contrast and unexpectedly, we observed that the expression of Hiscl1 in PRs but not in interneurons was involved in circadian entrainment. In fact, only Hiscl1 expression in Rh6 PRs mediates entrainment. Our work thus reveals Rh6-expressing PRs as both photoreceptors and histamine-receiving interneurons in the rhodopsin-dependent entrainment pathway, which recalls the role of melanopsin-expressing retinal ganglion cells in the mammalian retina (Alejevski et al. Nat Commun, in revision).

Horloge circadienne

Système visuel

Drosophile

Rhodopsine

Rythmes

Synchronisation

Lumière

Circadian clock

Visual system

Drosophila

Rhodopsin

Rhythms

Synchronization

Light

Modular Switches in Protein Function: A Spectroscopic Approach

Madathil, Sineej

08 December 2009

Understanding the molecular basis of protein function is a challenging task that lays the foundation for the pharmacological intervention in many diseases originating in altered structural states of the involved proteins. Dissecting a complex functional machinery into modules is a promising approach to protein function. The motivation for this work was to identify minimal requirements for “local” switching processes in the function of multidomain proteins that can adopt a variety of structural substates of different biological activity or representing intermediates of a complex reaction path. For example, modular switches are involved in signal transduction, where receptors respond to ligand-activation by specific conformational changes that are allosterically transmitted to “effector recognition sites” distant from the actual ligand-binding site. Heptahelical receptors have attracted particular attention due to their ubiquitous role in a large variety of pharmacologically relevant processes. Although constituting switches in their own right, it has become clear through mutagenesis and functional studies that receptors exhibit substates of partial active/inactive structure that can explain biological phenotypes of different levels of activity. Here, the notion that microdomains undergo individual switching processes that are integrated in the overall response of structurally regulated proteins is addressed by studies on the molecular basis of proton-dependent (chemical) and force-dependent (mechanical) conformational transitions. A combination of peptide synthesis, biochemical analysis, and secondary structure sensitive spectroscopy (Infrared, Circular dichroism, Fluorescence) was used to prove the switching capability of putative functional modules derived from three selected proteins, in which conformational transitions determine their function in transmembrane signaling (rhodopsin), transmembrane transport (bacteriorhodopsin) and chemical force generation (kinesin-1). The data are then related to the phenotypes of the corresponding full length-systems. In the first two systems the chemical potential of protons is crucial in linking proton exchange reactions to transmembrane protein conformation. This work addresses the hypothesized involvement of lipid protein interactions in this linkage (1). It is shown here that the lipidic phase is a key player in coupling proton uptake at a highly conserved carboxylic acid (DRY motif located at the C-terminus of helix 3) to conformation during activation of class-1 G protein coupled receptors (GPCRs) independently from ligand protein interactions and interhelical contacts. The data rationalize how evolutionary diversity underlying ligand-specifity can be reconciled with the conservation of a cytosolic ‘proton switch’, that is adapted to the general physical constraints of a lipidic bilayer described here for the prototypical class-1 GPCR rhodopsin (2). Whereas the exact sequence of modular switching events is of minor importance for rhodopsin as long as the final overall active conformation is reached, the related heptahelical light-transducing proton pump bacteriorhodopsin (bR), requires the precise relative timing in coupling protonation events to conformationtional switching at the cytosolic, transmembrane, and extracellular domains to guarantee vectorial proton transport. This study has focused on the cytosolic proton uptake site of this retinal protein whose proton exchange reactions at the cytosolic halfchannel resemble that of rhodopsin. It was a prime task in this work to monitor in real time the allosteric coupling between different protein regions. A novel powerful method based on the correlation of simultaneously recorded infrared absorption and fluorescence emission changes during bR function was established here (3), to study the switching kinetics in the cytosolic proton uptake domain relative to internal proton transfer reactions at the retinal and its counter ion. Using an uptake-impaired bR mutant the data proves the modular nature of domain couplings and shows that the energy barrier of the conformational transition in the cytosolic half but not its detailed structure is under the control of proton transfer reactions at the retinal Schiff base and its counter ion Asp85 (4). Despite the different functions of the two studied retinal proteins, the protonation is coupled to local switching mechanisms studied here at two levels of complexity, [a] a single carboxylic acid side chain acting as a lipid-dependent proton switch [b] a full-length system, where concerted modular regions orchestrate the functional coupling of proton translocation reactions. Switching on the level of an individual amino acid is shown to rely on localizable chemical properties (charge state, hydrophobicity, rotamer state). In contrast, switching processes involving longer stretches of amino acids are less understood, less generalizable, and can constitute switches of mechanical, rather than chemical nature. This applies particularly to molecular motors, where local structural switching processes are directly involved in force generation. A controversy exists with respect to the structural requirements for the cooperation of many molecular motors attached to a single cargo. The mechanical properties of the Hinge 1 domain of kinesin-1 linking the “neck” and motor domain to the “tail” were addressed here to complement single molecule data on torsional flexibility with secondary structure analysis and thermal stability of peptides derived from Hinge 1 (5). It is shown that the Hinge 1 exhibits an unexpected helix-forming propensity that resists thermal forces but unfolds under load. The data resolve the paradox that the hinge is required for motor cooperation, whereas it is dispensable for single motor processivity, clearly emphasizing the modular function of the holoprotein. However, the secondary-structural data reveal the functional importance of providing high compliance by force-dependent unfolding, i.e. in a fundamentally different way than disordered domains that are flexible but yet do not support cooperativity.

info:eu-repo/classification/ddc/570

ddc:570

Turning on Fluorescence in Silico: From Radical Cations to 11-cis Locked Rhodopsin Analogues

Laricheva, Elena N.

16 July 2012

No description available.

Chemistry

Wurster's Blue

fluorescence

rhodopsin

11-cis locked

fluorescent proteins

<i>ab initio</i>