Erhöhte Anfälligkeit von Creatinkinase-defizienten Mausherzen gegenüber Ischämie und Reperfusionschaden bei veränderter Calcium-Homöostase / Creatine Kinase-Deficient Hearts exhibit Increased Susceptibility to Ischemia/Reperfusion Injury and Impaired Calcium Homeostasis

Meyer, Klaus

January 2008

Durch die Konzeption des Versuchsaufbaus und der Wahl der Komponenten konnte die aktuelle Arbeit an intakten isolierten Mäuseherzen zeigen, dass unter weitgehend physiologischen in-vitro-Bedingungen die Möglichkeit besteht, mit Hilfe des Biolumineszenzproteins Aequorin Messungen der intrazytoplasmatischen Ca2+- Konzentration während eines einzelnen Herzschlages mit einer Frequenz von 420 Schlägen pro Minute zu gewinnen und diese gleichzeitig in die linksventrikuläre Funktion integrieren zu können. Das wesentliche Ergebnis dieser Arbeit ist dabei, dass während moderater Arbeitsbelastung der Verlust eines effizienten CK-Systems transgener CK-defizienter- Herzen (CKM/Mito-/) hinsichtlich des intramyokardialem Calciumstoffwechsels und der linksventrikulären Funktion durch Adaptionsmechanismen offensichtlich gut kompensiert wird. Allerdings wird in Situationen des Ungleichgewichtes zwischen Energieversorgung und Energieverbrauch, ausgelöst durch Ischämie und anschließende Reperfusion, eine signifikante Verschlechterung der linksventrikulären Funktion und gleichzeitig der Ca2+-Homöostase sichtbar, was einen weiteren Beweis für die enge Beziehung zwischen myokardialer Energetik und des Ca2+-Haushaltes insbesondere in CK-defizienten Herzen unter metabolischem Stress darstellt. Schließlich zeigt die simultane Aufzeichnung des Ca2+-Signals und die Druckentwicklung des linken Ventrikels, dass es schon vor der Entwicklung der ischämischen Kontraktur zur intrazytoplasmatischen Veränderung der Ca2+-Homöostase kommt, die durch eine unzureichende Bereitstellung durch ATP ausgelöst wird und maßgeblich durch das Fehlen eines effizienten Energietransportsystem in Form der Kreatinkinase bedingt sein könnte. / In conclusion, the present study demonstrates that, during moderate workload, loss of an efficient CK system in transgenic CK deficient hearts is well compensated by adaptational mechanisms. However, during more pronounced mismatches in energy supply and demand, such as induced by ischemia/reperfusion injury, significant alterations in LV performance and Ca2+ homeostasis become unmasked, providing further evidence for a key function of an intact CK system for maintenance of calcium homeostasis under metabolic stress conditions.

Kreatin Kinase

Calcium

Aequorin

Ischämie

Maus

Herz

ddc:610

DEVELOPMENT OF LUMINESCENT SENSING SYSTEMS WITH CLINICAL APPLICATIONS

Scott, Daniel F.

01 January 2011

As the move towards the miniaturization of many diagnostic and detection systems continues, the need for increasingly versatile yet sensitive labels for use in these systems also grows. Luminescent reporters provide us with a solution to many of the issues at hand through their unique and favorable characteristics. Bioluminescent proteins offer detection at extremely low concentrations and no interference from physiological fluids leading to excellent detection limits, while the vast number of fluorescent proteins and molecules available allows the opportunity to select a tailored reporter for a specific task. Both provide relatively simply instrumentation requirements and have exhibited great promise with many of the miniaturized systems such as lab-on-a-chip and lab-on-a-CD designs. Herein, we describe the novel employment of luminescent reporters for four distinct purposes. First off, by combining both time and wavelength resolution we have expanded the multiplexing capabilities of the photoprotein aequorin beyond duel-analytes, demonstrating the ability to simultaneously detect three separate analytes. Three semi-synthetic aequorin proteins were genetically conjugated to three pro-inflammatory cytokines (interleukins 1, 6, and 8) resulting in aequorin labeled cytokines with differing emission maxima and half lives to allow for the simultaneous detection of all three in a single solution through the elevated physiological concentration range. Secondly a semi-synthetic aequorin variant has been genetically enhanced to serve as an immunolabel and exhibited the ability to sensitively detect the acute myeloid leukemia marker, CD33, down to the attomole level in addition to improving aequorin imaging capabilities. In the third example, the aequorin complex was rationally, genetically split into two parts and attached to the termini of the cAMP selective cAMP receptor protein (CRP) creating a genetically fused molecular switch. The conformational change experienced by CRP upon the binding of cAMP translates into a loss of bioluminescent signal from aequorin and has shown the ability to respond linearly to cAMP over several orders of magnitude. Lastly, through custom design, a reagentless, portable, fluorescent fiber optic detection system has been developed, capable of being integrated into the body through a heart catheter. The system was able to respond to changes in potassium concentration selectively, reproducibly and reversibly with a fast response time of one minute.

bioluminescent

fluorescent

aequorin

assay

bioanalytical

Physical Sciences and Mathematics

Radiochemical and luminescence-based binding and functional assays for human histamine receptors using genetically engineered cells

Mosandl, Johannes

January 2009

Regensburg, Univ., Diss., 2009.

Sensorimotor integration in the moving spinal cord / Intégration sensorimotrice dans la moelle épinière en mouvement

Knafo, Steven

29 September 2015

Certaines observations suggèrent que les afférences méchano-sensorielles peuvent moduler l’activité des générateurs centraux du rythme locomoteur (ou Central Pattern Generators, CPGs). Cependant, il est impossible d’explorer les circuits neuronaux sous-jacents chez l’animal en mouvement à l’aide d’enregistrements électrophysiologiques lors d’expériences de locomotion dite « fictive ». Dans cette étude, nous avons enregistré de façon sélective et non-invasive les neurones moteurs et sensoriels dans la moelle épinière pendant la locomotion active en ciblant génétiquement le senseur bioluminescent GFP-Aequorin chez la larve de poisson zèbre. En utilisant l’imagerie calcique à l’échelle des neurones individuels, nous confirmons que les signaux de bioluminescence reflètent bien le recrutement différentiel des groupes de motoneurones spinaux durant la locomotion active. La diminution importante de ces signaux chez des animaux paralysés ou des mutants immobiles démontre que le retour méchano-sensoriel augmente le recrutement des motoneurones spinaux pendant la locomotion active. En accord avec cette observation, nous montrons que les neurones méchano-sensoriels spinaux sont en effet recrutés chez les animaux en mouvement, et que leur inhibition affecte les réflexes d’échappement chez des larves nageant librement. L’ensemble de ces résultats met en lumière la contribution du retour méchano-sensoriel sur la production locomotrice et les différences qui en résultent entre les locomotions active et fictive. / There is converging evidence that mechanosensory feedback modulates the activity of spinal central pattern generators underlying vertebrate locomotion. However, probing the underlying circuits in behaving animals is not possible in “fictive” locomotion electrophysiological recordings. Here, we achieve selective and non-invasive monitoring of spinal motor and sensory neurons during active locomotion by genetically targeting the bioluminescent sensor GFP-Aequorin in larval zebrafish. Using GCaMP imaging of individual neurons, we confirm that bioluminescence signals reflect the differential recruitment of motor pools during motion. Their significant reduction in paralyzed animals and immotile mutants demonstrates that mechanosensory feedback enhances the recruitment of spinal motor neurons during active locomotion. Accordingly, we show that spinal mechanosensory neurons are recruited in moving animals and that their silencing impairs escapes in freely behaving larvae. Altogether, these results shed light on the contribution of mechanosensory feedback to motor output and the resulting differences between active and fictive locomotion.

GFP-Aequorin

Bioluminescence

Intégration sensori-Motrice

Locomotion

Moelle épinière

Poisson-Zèbre

Zebrafish

Bioluminescence

Spinal cord

612.8

De nouveaux senseurs bioluminescents pour l'observation de l'activité cérébrale in toto chez la souris / New bioluminescent sensors for murine brain activity imaging in toto

Picaud, Sandrine

24 September 2014

Le suivi des flux calciques dans le cerveau de l’animal en mouvement nécessite de nouvellessondes. Nous utilisons la bioluminescence observée chez la méduse Aequorea victoria etimpliquant la protéine aequorine. Une fusion entre l’aequorine et la protéine fluorescente GFP(GA) permet d’obtenir un senseur calcique bioluminescent dont la stabilité et les propriétésspectrales sont adéquates pour de nombreuses applications. L’émission de bioluminescencepermet de suivre la propagation de l’information nerveuse de cellule en cellule, en temps réeldans des réseaux de neurones.Nous avons tout d’abord montré au moyen de construction de lignées transgéniques murinesque la protéine chimère GA peut être exprimée dans des microdomaines cellulaires pouranalyser l’activité neuronale. Nos résultats montrent pour la première fois qu’il est possibled’enregistrer in vivo et de manière non invasive dans l’animal en mouvement deschangements dans la concentration de calcium mitochondrial. Nous avons ensuite réalisé unciblage post synaptique du senseur par fusion à la protéine PSD95. Ce ciblage permet dedétecter l'entrée de calcium au niveau du récepteur NMDA.Parallèlement, nous avons cherché à améliorer les propriétés du senseur GA pour détécterl’activité calcique dans l’animal in toto. Nous identifié un nouvel analogue de lacoelenterazine conduisant à un décalage du spectre de bioluminescence de l’aequorine vers lerouge. Et par ailleurs, nous avons testé l’activité de l’aequorine en fusion avec diversesprotéines fluorescentes. Nous disposons avec ce travail de nouveaux senseurs bioluminescentspour le suivi de l’activité cérébrales dans des études comportementales. / Monitoring calcium fluxes in the brain of freely moving animals requires the development ofnew probes. We use the bioluminescence of the protein aequorin observed in the jellyfishAequorea victoria. A fusion between aequorin and GFP fluorescent protein (GA) provides abioluminescent calcium sensor whose stability and spectral properties are adequate for manyapplications. The emission of bioluminescence is suitable to track in real-time the propagationof nervous impulses from cell to cell in neural networks.We first showed by transgenic murine lines construction that the chimeric protein GA can beexpressed in cell microdomains to analyze neuronal activity. Our results show for the firsttime it is possible to record in vivo and non-invasively in the moving animal, changes in theconcentration of mitochondrial calcium. We then performed a post synaptic targeting of thesensor by fusion with the protein PSD95. This permits to detect the entry of calcium next tothe NMDA receptor.Meanwhile, we tried to improve the properties of the GA sensor to detect calcium activity inthe animal in toto and mor specifically through the skull. We identified a new analogue ofcoelenterazine leading to a shift in the spectrum of aequorin bioluminescence to red. We thentested the activity of aequorin fused with different fluorescent proteins. This leads to newbioluminescent sensors for monitoring the brain activity in behavioral studies.

Bioluminescence

FP-Aequorine

Coelentérazine

Imagerie calcique

Souris transgénique

Bioluminescence

FP-Aequorin

573.8

Phosphate starvation alters calcium signalling in roots of Arabidopsis thaliana

Matthus, Elsa

January 2019

Low bioavailability of phosphate (P) due to low concentration and high immobility in soils is a key limiting factor in crop production. Application of excess amounts of P fertilizer is costly and by no means sustainable, as world-wide P resources are finite and running out. To facilitate the breeding of crops adapted to low-input soils, it is essential to understand the consequences of P deficiency. The second messenger calcium (Ca2+) is known to signal in plant development and stress perception, and most recently its direct role in signalling nutrient availability and deficiency has been partially elucidated. The use of Ca2+ as a signal has to be tightly controlled, as Ca2+ easily complexes with P groups and therefore is highly toxic to cellular P metabolism. It is unknown whether Ca2+ signals P availability or whether signalling is altered under P starvation conditions. The aim of this PhD project was to characterise the use of Ca2+ ions, particularly cytosolic free Ca2+ ([Ca2+]cyt), in stress signalling by P-starved roots of the model plant Arabidopsis thaliana. The hypothesis was that under P starvation and a resulting decreased cellular P pool, the use of [Ca2+]cyt may have to be restricted to avoid cytotoxic complexation of Ca2+ with limited P groups. Employing a range of genetically encoded Ca2+ reporters in Arabidopsis, P starvation but not nitrogen starvation was found to strongly dampen the root [Ca2+]cyt increases evoked by mechanical, salt, osmotic, and oxidative stress as well as by extracellular nucleotides. The strongly altered root [Ca2+]cyt response to extracellular nucleotides was shown to manifest itself during seedling development under chronic P deprivation, but could be reversed by P resupply. Fluorescent imaging elucidated that P-starved roots showed a normal [Ca2+]cyt response to extracellular nucleotides at the apex, but a strongly dampened [Ca2+]cyt response in distal parts of the root tip, correlating with high reactive oxygen species (ROS) levels induced by P starvation. Excluding iron, as well as P, rescued the altered [Ca2+]cyt response, and restored ROS levels to those seen under nutrient-replete conditions. P availability was not signalled through [Ca2+]cyt. In another part of this PhD project, a library of 77 putative Ca2+ channel mutants was compiled and screened for aberrant root hair growth under P starvation conditions. No mutant line showed aberrant root hair growth. These results indicate that P starvation strongly affects stress-induced [Ca2+]cyt modulations. The data generated in this thesis further understanding of how plants can integrate nutritional and environmental cues, adding another layer of complexity to the use of Ca2+ as a signal transducer.