Elektrophysiologische, molekularbiologische und verhaltensbiologische Untersuchungen zur Funktion von N-Methyl-D-Aspartat-Rezeptoren bei Gehirnentwicklung und Lernvorgängen

Im Zentralnervensystem der Säuger steuern N-Methyl-D-Aspartat-(NMDA)-Rezeptoren viele neuronale Prozesse, insbesondere während der Ontogenese sowie bei Lern- und Gedächtnisvorgängen. In der vorliegenden Arbeit wurde die Bedeutung dieser Rezeptoren während der Kortexentwicklung und bei Lernvorgängen mittels elektrophysiologischer, molekularbiologischer, pharmakologischer, histologischer, genetischer und verhaltensbiologischer Methoden an der Maus untersucht. Oszillatorische Netzwerkaktivität ist für die gesunde Entwicklung des Kortex essentiell. Mittels gepaarter patch-clamp Experimente an neonatalen Subplattenzellen wurde festgestellt, dass diese Neurone elektrisch gekoppelt sind. Damit könnten sie einen wichtigen Beitrag zur Entstehung bzw. Verstärkung von Netzwerkoszillationen leisten. Subplattenzellen erhalten afferenten Eingang aus dem Thalamus sowie von benachbarten Subplattenzellen. Die funktionellen und molekularen Eigenschaften dieser Synapsen differierten in eingangsspezifischer Weise. Subplatteninterne Verbindungen besaßen Integrations- und Summationsfähigkeiten, wenig synaptische Ermüdung, Paarpulsfazilitierung und einen erhöhten NR2D-Anteil in ihren NMDA-Rezeptoren. CA1-Pyramidenzellen des adulten Hippocampus zeigten eine den Subplattenzellen vergleichbare eingangsspezifische Verteilung der NMDA-Rezeptor-Untereinheiten. Synapsen von Schaffer-Kollateralen besaßen einen höheren NR2B-Anteil als temporo-ammonische Verbindungen. Die Aktivierung von Dopamin-Rezeptoren potenzierte NR2B-vermittelte synaptische Ströme in CA1-Neuronen. Bei komplexen Lernvorgängen, wie der Extinktion einer traumatischen Erinnerung, spielten NMDA-Rezeptoren von hippocampalen CA1-Zellen eine entscheidende Rolle. CA1-NMDA-Rezeptor-ko-Mäuse zeigten erhebliche Extinktionsdefizite nach Angstkonditionierung. Zudem entwickelten diese Mäuse erhöhte Ängstlichkeit und Hyperaktivität. Das sind beim Menschen Symptome für psychiatrische Angststörungen. Daher könnten CA1-NMDA-Rezeptor-ko-Mäuse als neues Tiermodell für solche Störungen dienen, die durch ein traumatisches Erlebnis ausgelöst werden, wie beim Posttraumatischen Stresssyndrom (PTSD).

Mechanismen und funktionelle Konsequenzen der Chlorid-Homöostase in unreifen Neuronen des Neocortex

GABA, der wichtigste inhibitorische Neurotransmitter im adulten Gehirn, bewirkt im unreifen Nervensystem eine Membrandepolarisation, vermutlich aufgrund der erhöhten intrazellulären Chloridkonzentration ([Cl-]i) in unreifen Nervenzellen. GABAerge Membrandepolarisationen sind essentiell für die korrekte Entwicklung des zentralen Nervensystems und die Entstehung kortikaler Netzwerkaktivität. Im Rahmen der vorliegenden Arbeit wurde mit Hilfe elektrophysiologischer und immunohistochemischer Methoden die Regulation der Chlorid-Homöostase in unreifen Neuronen des Neokortex untersucht. Die Experimente wurden an Cajal-Retzius (CR) Zellen, einem transienten Zelltyp der Marginalzone, in akuten Hirnschnittpräparaten neonataler Ratten (P0-P3) durchgeführt. Es konnte gezeigt werden, dass CR Zellen eine hohe native [Cl-]i von ~30 mM aufweisen. Die hohe [Cl-]i wurde ausschließlich durch Bumetanid sensitiven und Na+-abhängigen aktiven Cl--Transport aufrechterhalten, was auf eine Cl--Akkumulation durch den Kationen-Chlorid-Cotransporter NKCC1 schließen lässt. Diese pharmakologischen Hinweise konnten durch den Nachweis der Expression von NKCC1 in der gesamten Marginalzone, speziell in CR Zellen, bestätigt werden. Die Transportgeschwindigkeit der NKCC1-abhängigen Cl--Akkumulation war gering, was auf eine limitierte Transportkapazität schließen lässt. In Übereinstimmung mit diesem Befund konnte gezeigt werden, dass die Cl--Leitfähigkeit in CR Zellen äußerst klein ist, so dass die NKCC1-abhängige Cl--Akkumulation ausreichend war, um unter Ruhebedingungen eine hohe [Cl-]i zu gewährleisten. Aufgrund dieser hohen [Cl-]i waren GABAA-Rezeptor vermittelte Antworten in CR Zellen exzitatorisch. Die Kapazität des NKCC1-vermittelten Cl--Transportes in CR Zellen konnte durch höherfrequente Stimulation überschritten werden, was dazu führte, dass die [Cl-]i abnahm und GABAerge Antworten unter diesen Bedingungen inhibitorisch wurden. Die inhibitorische Wirkung von GABA in CR Zellen wurde überwiegend durch die Reduktion des Eingangswiderstandes der Zelle vermittelt und beruhte nicht auf einer Verschiebung der Aktionspotentialschwelle.

Neural network activity in the neonatal rat barrel cortex in vivo

Coordinated patterns of electrical activity are important for the early development of sensory systems. The spatiotemporal dynamics of these early activity patterns and the role of the peripheral sensory input for their generation are essentially unknown. There are two projects in this thesis. In project1, we performed extracellular multielectrode recordings in the somatosensory cortex of postnatal day 0 to 7 rats in vivo and observed three distinct patterns of synchronized oscillatory activity. (1) Spontaneous and periphery-driven spindle bursts of 1–2 s in duration and ~10 Hz in frequency occurred approximately every 10 s. (2) Spontaneous and sensory-driven gamma oscillations of 150–300 ms duration and 30–40 Hz in frequency occurred every 10–30 s. (3) Long oscillations appeared only every ~20 min and revealed the largest amplitude (250–750 µV) and longest duration (>40 s). These three distinct patterns of early oscillatory activity differently synchronized the neonatal cortical network. Whereas spindle bursts and gamma oscillations did not propagate and synchronized a local neuronal network of 200–400 µm in diameter, long oscillations propagated with 25–30 µm/s and synchronized 600-800 µm large ensembles. All three activity patterns were triggered by sensory activation. Single electrical stimulation of the whisker pad or tactile whisker activation elicited neocortical spindle bursts and gamma activity. Long oscillations could be only evoked by repetitive sensory stimulation. The neonatal oscillatory patterns in vivo depended on NMDAreceptor-mediated synaptic transmission and gap junctional coupling. Whereas spindle bursts and gamma oscillations may represent an early functional columnar-like pattern, long oscillations may serve as a propagating activation signal consolidating these immature neuronal networks. In project2, Using voltage-sensitive dye imaging and simultaneous multi-channel extracellular recordings in the barrel cortex and somatosensory thalamus of newborn rats in vivo, we found that spontaneous and whisker stimulation induced activity patterns were restricted to functional cortical columns already at the day of birth. Spontaneous and stimulus evoked cortical activity consisted of gamma oscillations followed by spindle bursts. Spontaneous events were mainly generated in the thalamus or by spontaneous whisker movements. Our findings indicate that during early developmental stages cortical networks self-organize in ontogenetic columns via spontaneous gamma oscillations triggered by the thalamus or sensory periphery.

Membrane properties and synaptic integration of identified neuronal populations in the developing rodent neocortex

In my PhD work I concentrated on three elementary questions that are essential to understand the interactions between the different neuronal cell populations in the developing neocortex. The questions regarded the identity of Cajal-Retzius (CR) cells, the ubiquitous expression of glycine receptors in all major cell populations of the immature neocortex, and the role of taurine in the modulation of immature neocortical network activity.rnTo unravel whether CR cells of different ontogenetic origin have divergent functions I investigated the electrophysiological properties of YFP+ (derived from the septum and borders of the pallium) and YFP− CR cells (derived from other neocortical origins). This study demonstrated that the passive and active electrophysiological properties as well as features of GABAergic PSCs and glutamatergic currents are similar between both CR cell populations. These findings suggest that CR cells of different origins most probably support similar functions within the neuronal networks of the early postnatal cerebral cortex.rnTo elucidate whether glycine receptors are expressed in all major cell populations of the developing neocortex I analyzed the functional expression of glycine receptors on subplate (SP) cells. Activation of glycine receptors by glycine, -alanine and taurine elicited membrane responses that could be blocked by the selective glycinergic antagonist strychnine. Pharmacological experiments suggest that SP cells express functional heteromeric glycine receptors that do not contain 1 subunits. The activation of glycine receptors by glycine and taurine induced a membrane depolarization, which mediated excitatory effects. Considering the key role of SP cells in immature cortical networks and the development of thalamocortical connections, this glycinergic excitation may influence the properties of early cortical networks and the formation of cortical circuits.rnIn the third part of my project I demonstrated that tonic taurine application induced a massive increase in the frequency of PSCs. Based on their reversal potential and their pharmacological properties these taurine-induced PSCs are exclusively transmitted via GABAA receptors to the pyramidal neurons, while both GABAA and glycine receptors were implicated in the generation of the presynaptic activity. Accordingly, whole-cell and cell-attached recordings from genetically labeled interneurons revealed the expression of glycine and GABAA receptors, which mediated an excitatory action on these cells. These findings suggest that low taurine concentrations can tonically activate exclusively GABAergic networks. The activity level maintained by this GABAergic activity in the immature nervous system may contribute to network properties and can facilitate the activity dependent formation of adequate synaptic projections.rnIn summary, the results of my studies complemented the knowledge about neuronal interactions in the immature neocortex and improve our understanding of cellular processes that guide neuronal development and thus shape the brain.rn

Untersuchung der physiologischen Rolle des Wilms-Tumorgens 1 (WT1) im Rahmen der Generierung muriner in-vivo-Modelle für die Wilms-Tumorerkrankung

Der Wilms-Tumor ist eine embryonale Tumorerkrankung der Niere, als deren Ursprung Nierenvorläuferzellen des metanephrischen Mesenchyms gelten, deren Differenzierung während der frühen Nephrogenese ausbleibt und aus denen nachfolgend durch eine maligne Transformation Wilms-Tumore entstehen. Zwei Gene, die an der Wilms-Tumorgenese beteiligt zu sein scheinen, sind WT1 (Wilms-Tumorgen 1) und CTNNB1 (Catenin, cadherin-associated protein, beta 1). Während WT1 u.a. die Differenzierung des metanephrischen Mesenchyms steuert, begünstigen aktivierende Mutationen von CTNNB1 und eine dadurch bedingte Akkumulation seines Proteins β-Catenin die Tumorgenese vieler Organe. So verwundert es nicht, dass eine alleinige heterozygote Keimbahnmutation von WT1, die einen dominant-negativen Effekt auf funktionsfähiges WT1 ausübt, häufig zur Entstehung von Wilms-Tumoren in Patienten mit Denys-Drash-Syndrom (DDS) führt, sowie in etwa 15 % aller sporadischen Wilms-Tumore WT1 und CTNNB1 mutiert sind.rnDer Mechanismus der Entstehung von Wilms-Tumoren ist weitgehend unbekannt, was u.a. daran liegt, dass homozygote Wt1-Mutationen in der Maus embryonal (~ Tag 13,5 d.p.c.) letal sind. In der vorliegenden Arbeit sollten daher mit Hilfe einer Wt1 k.o.-Effektormaus (WE2) vier murine konditional reversible Wilms-Tumor-Modelle auf Basis des Tet off-Systems hergestellt werden. Dadurch lag in den zu generierenden Tieren Wt1 durch die Integration des WE2-Transgens zwar nur heterozygot mutiert vor, doch durch den endogenen Wt1-Promotor des Transgens sollte es zur zeitlichen und räumlichen Wt1-analogen Expression eines tetrazyklinabhängigen Transaktivators (tTA) kommen, der ohne die Gabe von Doxycyclin Tet-regulierbare Transgene in Wt1-exprimierenden Zellen aktivieren kann, die einen positiven Einfluss auf die Wilms-Tumorgenese haben könnten. So sollte durch das WE2 DDS-Modell ein DDS simuliert werden und es in Tieren der Modelle WE2 TC bCat∆Ex3, WE2 LC bCat∆Ex3 und WE2 Wnt1 zur Akkumulation von β-Catenin in Wt1-exprimierenden Nierenvorläuferzellen kommen, so dass deren Differenzierung ausbleibt und es durch eine maligne Transformation zur Entstehung eines Wilms-Tumors kommt.rnrnMit Hilfe von histologischen Analysen an entsprechenden Responder-Linien konnte zunächst gezeigt werden, dass die embryonale und adulte Expressionsdomäne des WE2-Effektors mit der von endogenen Wt1 übereinstimmt. Gleichzeitig wurden aber auch neue Expressionsorte von Wt1 nachgewiesen. So konnte die Expression des WE2-Effektors z.B. im Endothel der dorsalen Aorta detektiert werden, der als Entstehungsort von hämatopoetischen Stammzellen gilt. Anschließende hier vorgestellte Experimente zeigten, dass Wt1 direkt an diesem Prozess beteiligt ist und belegten eine noch nicht beschriebene Funktion von Wt1 in der frühen Hämatopoese.rnEs war jedoch mit keinem System möglich, eine Wilms-Tumorerkrankung zu simulieren. Während Tiere des WE2 DDS-Modells trotz nachweisbarer Induktion keinen Phänotyp aufwiesen, war wohl in den anderen Modellen eine konstitutive β-Catenin-Aktivierung in der Frühschwangerschaft nicht mit dem embryonalen Überleben vereinbar. Dabei schienen alle tripeltransgenen bzw. doppeltransgenen Embryonen, in denen durch einen frühen Doxycyclinentzug die Entstehung von Wilms-Tumoren möglich gewesen wäre, intrauterin zu sterben. Wurde dagegen Doxycyclin erst in der dritten Lebenswoche entzogen, so entwickelten die Tiere durch eine Wt1-vermittelte β-Catenin-Aktivierung Granulosazelltumore, polyzystische Nieren und Veränderungen der Hoden. Da alle diese organischen Veränderungen während der prä- bis frühen postnatalen Phase induziert wurden, schien die Doxycyclinmenge nicht auszureichen, um eine β-Catenin-Aktivierung zu verhindern. Es hätte also auch zur Entstehung von Wilms-Tumoren kommen können, so dass diese Ergebnisse darauf hinweisen, dass eine β-Catenin-Aktivierung wahrscheinlich nicht der physiologisch entscheidende Schritt bei der Entstehung eines Wilms-Tumors ist.rnrnDie Charakterisierung der WE2-Effektormaus und die Herstellung und Analysen der Systeme geben damit Einblick in die WT1- bzw. WT1/CTNNB1-assoziierte Wilms-Tumorgenese und ermöglichen die weitere Erforschung von Granulosazelltumoren, polyzystsischen Nieren, Veränderungen von Hoden und der Rolle von WT1 in der frühen Hämatopoese.rn

Long-term potentiation and neural network activity in the neonatal rat cerebral cortex in vivo

Long-term potentiation in the neonatal rat rnbarrel cortex in vivo rnLong-term potentiation (LTP) is important for the activity-dependent formation of early cortical circuits. In the neonatal rodent barrel cortex LTP has been so far only studied in vitro. I combined voltage-sensitive dye imaging with extracellular multi-electrode recordings to study whisker stimulation-induced LTP for both the slope of field potential and the number of multi-unit activity in the whisker-to-barrel cortex pathway of the neonatal rat barrel cortex in vivo. Single whisker stimulation at 2 Hz for 10 min induced an age-dependent expression of LTP in postnatal day (P) 0 to P14 rats with the strongest expression of LTP at P3-P5. The magnitude of LTP was largest in the stimulated barrel-related column, smaller in the surrounding septal region and no LTP could be observed in the neighboring barrel. Current source density analyses revealed an LTP-associated increase of synaptic current sinks in layer IV / lower layer II/III at P3-P5 and in the cortical plate / upper layer V at P0-P1. This study demonstrates for the first time an age-dependent and spatially confined LTP in the barrel cortex of the newborn rat in vivo. These activity-dependent modifications during the critical period may play an important role in the development and refinement of the topographic map in the barrel cortex. (An et al., 2012)rnEarly motor activity triggered by gamma and spindle bursts in neonatal rat motor cortexrnSelf-generated neuronal activity generated in subcortical regions drives early spontaneous motor activity, which is a hallmark of the developing sensorimotor system. However, the neuronal activity patterns and functions of neonatal primary motor cortex (M1) in the early movements are still unknown. I combined voltage-sensitive dye imaging with simultaneous extracellular multi-electrode recordings in the neonatal rat S1 and M1 in vivo. At P3-P5, gamma and spindle bursts observed in M1 could trigger early paw movements. Furthermore, the paw movements could be also elicited by the focal electrical stimulation of M1 at layer V. Local inactivation of M1 could significantly attenuate paw movements, suggesting that the neonatal M1 operates in motor mode. In contrast, the neonatal M1 can also operate in sensory mode. Early spontaneous movements and sensory stimulations of paw trigger gamma and spindle bursts in M1. Blockade of peripheral sensory input from the paw completely abolished sensory evoked gamma and spindle bursts. Moreover, both sensory evoked and spontaneously occurring gamma and spindle bursts mediated interactions between S1 and M1. Accordingly, local inactivation of the S1 profoundly reduced paw stimulation-induced and spontaneously occurring gamma and spindle bursts in M1, indicating that S1 plays a critical role in generation of the activity patterns in M1. This study proposes that both self-generated and sensory evoked gamma and spindle bursts in M1 may contribute to the refinement and maturation of corticospinal and sensorimotor networks required for sensorimotor coordination.rn

Resonance properties of different neuronal populations in the immature mouse neocortex

Subthreshold resonance is a characteristic membrane property of different neuronal classes, is critically involved in the generation of network oscillations, and tunes the integration of synaptic inputs to particular frequency ranges. In order to investigate whether resonance properties of distinct neuronal populations in the immature neocortex contribute to these network oscillations, I performed whole-cell patch-clamp recordings from visually identified neurons in tangential and coronal neocortical slices from postnatal day (P) P0-P7 C57Bl/6 and P6-P13 GAD67-GFP knock-in mice. Subthreshold resonance was analyzed by sinusoidal current injection of varying frequency. All Cajal-Retzius cells showed subthreshold resonance with an average frequency of 2.6 ± 0.1 Hz (n=60), which was massively reduced by ZD7288, a blocker of hyperpolarization-activated cation currents. About 65.6% (n=61) of the supragranular pyramidal neurons showed subthreshold resonance with an average frequency of 1.4 ± 0.1 Hz (n=40). Application of 1 mM Ni2+ suppressed subthreshold resonance, suggesting that low-threshold Ca2+ currents contribute to resonance in these neurons. About 63.6% (n=77) of the layer V pyramidal neurons showed subthreshold resonance with an average frequency of 1.4 ± 0.2 Hz (n=49), which was abolished by ZD7288. Only 44.1% (n=59) of the subplate neurons showed subthreshold resonance with an average frequency of 1.3 ± 0.2 Hz (n=26) and a small resonance strength. Finally, 50% of the investigated GABAergic interneurons showed subthreshold resonance with an average frequency of 2.0 ± 0.2 Hz (n=42). Membrane hyperpolarization to –86 mV attenuated the frequency and strength of subthreshold resonance. Subthreshold resonance was virtually abolished in the presence of 1 mM Ni2+, suggesting that t-type Ca2+ currents are critically involved in the generation of resonance, while ZD7288 had no effect. Application of 0.4 µM TTX suppressed subthreshold resonance at depolarized, but not hyperpolarized membrane potential, suggesting that persistent Na+ current contribute to the amplification of membrane resonance. rnIn summary, these results demonstrate that all investigated neuronal subpopulations reveal resonance behavior, with either hyperpolarization-activated cation or low-threshold Ca2+ currents contributing to the subthreshold resonance. GABAergic interneurons also express subthreshold resonance at low frequencies, with t-type Ca2+ and persistent Na+ currents underlying the generation of membrane resonance. The membrane resonance of immature neurons may contribute to the generation of slow oscillatory activity pattern in the immature neocortex and enhance the temporal precision of synaptic integration in developing cortical neurons.rn

A simple and novel method to monitor breathing and heart rate in awake and urethane-anesthetized newborn rodents

Rodents are most useful models to study physiological and pathophysiological processes in early development, because they are born in a relatively immature state. However, only few techniques are available to monitor non-invasively heart frequency and respiratory rate in neonatal rodents without restraining or hindering access to the animal. Here we describe experimental procedures that allow monitoring of heart frequency by electrocardiography (ECG) and breathing rate with a piezoelectric transducer (PZT) element without hindering access to the animal. These techniques can be easily installed and are used in the present study in unrestrained awake and anesthetized neonatal C57/Bl6 mice and Wistar rats between postnatal day 0 and 7. In line with previous reports from awake rodents we demonstrate that heart rate in rats and mice increases during the first postnatal week. Respiratory frequency did not differ between both species, but heart rate was significantly higher in mice than in rats. Further our data indicate that urethane, an agent that is widely used for anesthesia, induces a hypoventilation in neonates whilst heart rate remains unaffected at a dose of 1 g per kg body weight. Of note, hypoventilation induced by urethane was not detected in rats at postnatal 0/1. To verify the detected hypoventilation we performed blood gas analyses. We detected a respiratory acidosis reflected by a lower pH and elevated level in CO2 tension (pCO2) in both species upon urethane treatment. Furthermore we found that metabolism of urethane is different in P0/1 mice and rats and between P0/1 and P6/7 in both species. Our findings underline the usefulness of monitoring basic cardio-respiratory parameters in neonates during anesthesia. In addition our study gives information on developmental changes in heart and breathing frequency in newborn mice and rats and the effects of urethane in both species during the first postnatal week.

Modulation of network excitability and epileptiform activity in the hippocampus of immature rats by the activation of GlyRs

Epileptic seizures are the manifestations of epilepsy, which is a major neurological disorder and occurs with a high incidence during early childhood. A fundamental mechanism underlying epileptic seizures is loss of balance between neural excitation and inhibition toward overexcitation. Glycine receptor (GlyR) is ionotropic neurotransmitter receptor that upon binding of glycine opens an anion pore and mediates in the adult nervous system a consistent inhibitory action. While previously it was assumed that GlyRs mediate inhibition mainly in the brain stem and spinal cord, recent studies reported the abundant expression of GlyRs throughout the brain, in particular during neuronal development. But no information is available regarding whether activation of GlyRs modulates neural network excitability and epileptiform activities in the immature central nervous system (CNS). Therefore the study in this thesis addresses the role of GlyRs in the modulation of neuronal excitability and epileptiform activity in the immature rat brain. By using in vitro intact corticohippocampal formation (CHF) of rats at postnatal days 4-7 and electrophysiological methods, a series of pharmacological examinations reveal that GlyRs are directly implicated in the control of hippocampal excitation levels at this age. In this thesis I am able to show that GlyRs are functionally expressed in the immature hippocampus and exhibit the classical pharmacology of GlyR, which can be activated by both glycine and the presumed endogenous agonist taurine. This study also reveals that high concentration of taurine is anticonvulsive, but lower concentration of taurine is proconvulsive. A substantial fraction of both the pro- and anticonvulsive effects of taurine is mediated via GlyRs, although activation of GABAA receptors also considerably contributes to the taurine effects. Similarly, glycine exerts both pro- and anticonvulsive effects at low and high concentrations, respectively. The proconvulsive effects of taurine and glycine depend on NKCC1-mediated Cl- accumulation, as bath application of NKCC1 inhibitor bumetanide completely abolishes proconvulsive effects of low taurine and glycine concentrations. Inhibition of GlyRs with low concentration of strychnine triggers epileptiform activity in the CA3 region of immature CHF, indicating that intrinsically an inhibitory action of GlyRs overwhelms its depolarizing action in the immature hippocampus. Additionally, my study indicates that blocking taurine transporters to accumulate endogenous taurine reduces epileptiform activity via activation of GABAA receptors, but not GlyRs, while blocking glycine transporters has no observable effect on epileptiform activity. From the main results of this study it can be concluded that in the immature rat hippocampus, activation of GlyRs mediates both pro- and anticonvulsive effects, but that a persistent activation of GlyRs is required to prevent intrinic neuronal overexcitability. In summary, this study uncovers an important role of GlyRs in the modulation of neuronal excitability and epileptiform activity in the immature rat hippocampus, and indicates that glycinergic system can potentially be a new therapeutic target against epileptic seizures of children.