Medial prefrontal cortex endocannabinoid system modulates baroreflex activity through CB1 receptors

Ferreira-Junior NC, Fedoce AG, Alves FHF, Correa FMA, Resstel LBM. Medial prefrontal cortex endocannabinoid system modulates baroreflex activity through CB1 receptors. Am J Physiol Regul Integr Comp Physiol 302: R876-R885, 2012. First published December 28, 2011; doi: 10.1152/ajpregu.00330.2011.-Neural reflex mechanisms, such as the baroreflex, are involved in the regulation of cardiovascular system activity. Previous results from our group (Resstel LB, Correa FM. Medial prefrontal cortex NMDA receptors and nitric oxide modulate the parasympathetic component of the baroreflex. Eur J Neurosci 23: 481-488, 2006) have shown that glutamatergic synapses in the ventral portion of the medial prefrontal cortex (vMPFC) modulate baroreflex activity. Moreover, glutamatergic neurotransmission in the vMPFC can be modulated by the endocannabinoids system (eCBs), particularly the endocannabinoid anandamide, through presynaptic CB1 receptor activation. Therefore, in the present study, we investigated eCBs receptors that are present in the vMPFC, and more specifically whether CB1 receptors modulate baroreflex activity. We found that bilateral microinjection of the CB1 receptor antagonist AM251 (100 or 300 pmol/200 nl) into the vMPFC increased baroreflex activity in unanesthetized rats. Moreover, bilateral microinjection of either the anandamide transporter inhibitor AM404 (100 pmol/200 nl) or the inhibitor of the enzyme fatty acid amide hydrolase that degrades anandamide, URB597 (100 pmol/200 nl), into the MPFC decreased baroreflex activity. Finally, pretreatment of the vMPFC with an ineffective dose of AM251 (10 pmol/200 nl) was able to block baroreflex effects of both AM404 and URB597. Taken together, our results support the view that the eCBs in the vMPFC is involved in the modulation of baroreflex activity through the activation of CB1 receptors, which modulate local glutamate release.

Effects of 3 weeks GMP oral administration on glutamatergic parameters in mice neocortex

Overstimulation of the glutamatergic system (excitotoxicity) is involved in various acute and chronic brain diseases. Several studies support the hypothesis that guanosine-5'-monophosphate (GMP) can modulate glutamatergic neurotransmission. The aim of this study was to evaluate the effects of chronically administered GMP on brain cortical glutamatergic parameters in mice. Additionally, we investigated the neuroprotective potential of the GMP treatment submitting cortical brain slices to oxygen and glucose deprivation (OGD). Moreover, measurements of the cerebrospinal fluid (CSF) purine levels were performed after the treatment. Mice received an oral administration of saline or GMP during 3 weeks. GMP significantly decreases the cortical brain glutamate binding and uptake. Accordingly, GMP reduced the immunocontent of the glutamate receptors subunits, NR2A/B and GluR1 (NMDA and AMPA receptors, respectively) and glutamate transporters EAAC1 and GLT1. GMP treatment significantly reduced the immunocontent of PSD-95 while did not affect the content of Snap 25, GLAST and GFAP. Moreover, GMP treatment increased the resistance of neocortex to OGD insult. The chronic GMP administration increased the CSF levels of GMP and its metabolites. Altogether, these findings suggest a potential modulatory role of GMP on neocortex glutamatergic system by promoting functional and plastic changes associated to more resistance of mice neocortex against an in vitro excitotoxicity event.

The periaqueductal gray as a critical site to mediate reward seeking during predatory hunting

Previous studies using morphine-treated dams reported a role for the rostral lateral periaqueductal gray (rIPAG) in the behavioral switching between nursing and insect hunting, likely to depend on an enhanced seeking response to the presence of an appetitive rewarding cue (i.e., the roach). To elucidate the neural mechanisms mediating such responses, in the present study, we first observed how the rIPAG influences predatory hunting in male rats. Our behavioral observations indicated that bilateral rIPAG NMDA lesions dramatically interfere with prey hunting, leaving the animal without chasing or attacking the prey, but do not seem to affect the general levels of arousal, locomotor activity and regular feeding. Next, using Phaseolus vulgaris-leucoagglutinin (PHA-L), we have reviewed the rIPAG connection pattern, and pointed out a particularly dense projection to the hypothalamic orexinergic cell group. Double labeled PHA-L and orexin sections showed an extensive overlap between PHA-L labeled fibers and orexin cells, revealing that both the medial/perifornical and lateral hypothalamic orexinergic cell groups receive a substantial innervation from the rIPAG. We have further observed that both the medial/perifornical and lateral hypothalamic orexinergic cell groups up-regulate Fos expression during prey hunting, and that rIPAG lesions blunted this Fos increase only in the lateral hypothalamic, but not in the medial/perifornical, orexinergic group, a finding supposedly associated with the lack of motivational drive to actively pursue the prey. Overall, the present results suggest that the rIPAG should exert a critical influence on reward seeking by activating the lateral hypothalamic orexinergic cell group. (C) 2011 Elsevier B.V. All rights reserved.

Erysothrine, an alkaloid extracted from flowers of Erythrina mulungu Mart. ex Benth: Evaluating its anticonvulsant and anxiolytic potential

In this study, we isolated the alkaloid erysothrine from the hydroalcoholic extract of flowers from E. mulungu and screened for its anticonvulsant and anxiolytic actions based on neuroethological and neurochemical experiments. Our results showed that the administration of erysothrine inhibited seizures evoked by bicuculline, PTZ, NMDA and most remarkably, kainic acid. Also, erysothrine induced an increase in the number of entries but not in the time spent in the open arms of the EPM. However, we did not notice any alterations in the light-dark choice or in the open-field tests. In preliminary neurochemistry tests, we also showed that erysothrine (0.001-10 mu g/mL) did not alter the GABA or glutamate synaptossomal uptake and binding. Altogether, our results describe an alkaloid with anticonvulsant activity and mild anxiolytic activity that might be considered well tolerated as it does not alter the general behavior of the animals in the used doses. (C) 2012 Elsevier Inc. All rights reserved.

The role of the ventrolateral caudoputamen in predatory hunting

The ventrolateral caudoputamen (VLCP) is well known to participate in the control of orofacial movements and forepaw usage accompanying feeding behavior. Previous studies from our laboratory have shown that insect hunting is associated with a distinct Fos up-regulation in the VLCP at intermediate rostro-caudal levels. Moreover, using the reversible blockade with lidocaine, we have previously suggested that the VLCP implements the stereotyped actions seen during prey capture and handling, and may influence the motivational drive to start attacking the roaches, as well. However, considering that (1) lidocaine suppresses action potentials not only in neurons, but also in fibers-of-passage, rendering the observed behavioral effect not specific to the ventrolateral caudoputamen; (2) the short lidocaine-induced inactivation period had left a relatively narrow window to observe the behavioral changes; and (3) that the restriction stress to inject the drug could have also disturbed hunting behavior, in the present study, we have examined the role of the VLCP in predatory hunting by placing bilateral NMDA lesions three weeks previous to the behavior testing. We were able to confirm that the VLCP serves to implement the stereotyped sequence of actions seen during prey capture and handling, but the study did not confirm its role in influencing the motivational drive to hunt. Together with other studies from our group, the present work serves as an important piece of information that helps to reveal the neural systems underlying predatory hunting. (C) 2011 Elsevier Inc. All rights reserved.

Purinergic and glutamatergic interactions in the hypothalamic paraventricular nucleus modulate sympathetic outflow

P2X receptors are expressed on ventrolateral medulla projecting paraventricular nucleus (PVN) neurons. Here, we investigate the role of adenosine 5′-triphosphate (ATP) in modulating sympathetic nerve activity (SNA) at the level of the PVN. We used an in situ arterially perfused rat preparation to determine the effect of P2 receptor activation and the putative interaction between purinergic and glutamatergic neurotransmitter systems within the PVN on lumbar SNA (LSNA). Unilateral microinjection of ATP into the PVN induced a dose-related increase in the LSNA (1 nmol: 38 ± 6 %, 2.5 nmol: 72 ± 7 %, 5 nmol: 96 ± 13 %). This increase was significantly attenuated by blockade of P2 receptors (pyridoxalphosphate-6-azophenyl-20,40-disulphonic acid, PPADS) and glutamate receptors (kynurenic acid, KYN) or a combination of both. The increase in LSNA elicited by L-glutamate microinjection into the PVN was not affected by a previous injection of PPADS. Selective blockade of non-N-methyl-D-aspartate receptors (6-cyano-7-nitroquinoxaline-2,3-dione disodium salt, CNQX), but not N-methyl-D-aspartate receptors (NMDA) receptors (DL-2-amino-5-phosphonopentanoic acid, AP5), attenuated the ATP-induced sympathoexcitatory effects at the PVN level. Taken together, our data show that purinergic neurotransmission within the PVN is involved in the control of SNA via P2 receptor activation. Moreover, we show an interaction between P2 receptors and non-NMDA glutamate receptors in the PVN suggesting that these functional interactions might be important in the regulation of sympathetic outflow

Effects of MK-801 and amphetamine treatments on allergic lung inflammatory response in mice

Glutamate acts as a neurotransmitter within the Central Nervous System (CNS) and modifies immune cell activity. In lymphocytes, NMDA glutamate receptors regulate intracellular calcium, the production of reactive oxygen species and cytokine synthesis. MK-801, a NMDA receptor open-channel blocker, inhibits calcium entry into mast cells, thereby preventing mast cell degranulation. Several lines of evidence have shown the involvement of NMDA glutamate receptors in amphetamine (AMPH)-induced effects. AMPH treatment has been reported to modify allergic lung inflammation. This study evaluated the effects of MK-801 (0.25mg/kg) and AMPH (2.0mg/kg), given alone or in combination, on allergic lung inflammation in mice and the possible involvement of NMDA receptors in this process. In OVA-sensitized and challenged mice, AMPH and MK-801 given alone decreased cellular migration into the lung, reduced IL-13 and IL10 levels in BAL supernatant, reduced ICAM-1 and L-selectin expression in granulocytes in the BAL and decreased mast cell degranulation. AMPH treatment also decreased IL-5 levels. When both drugs were administered, treatment with MK-801 reversed the decrease in the number of eosinophils and neutrophils induced by AMPH in the BAL of OVA-sensitized and challenged mice as well as the effects on the expression of L-selectin and ICAM-1 in granulocytes, the IL-10, IL-5 and IL-13 levels in BAL supernatants and increased mast cell degranulation. At the same time, treatment with MK-801, AMPH or with MK-801+AMPH increased corticosterone serum levels in allergic mice. These results are discussed in light of possible indirect effects of AMPH and MK-801 via endocrine outflow from the CNS (i.e., HPA-axis activity) to the periphery and/or as a consequence of the direct action of these drugs on immune cell activity, with emphasis given to mast cell participation in the allergic lung response of mice.

Mathematical models of cognitive processes

The research activity carried out during the PhD course was focused on the development of mathematical models of some cognitive processes and their validation by means of data present in literature, with a double aim: i) to achieve a better interpretation and explanation of the great amount of data obtained on these processes from different methodologies (electrophysiological recordings on animals, neuropsychological, psychophysical and neuroimaging studies in humans), ii) to exploit model predictions and results to guide future research and experiments. In particular, the research activity has been focused on two different projects: 1) the first one concerns the development of neural oscillators networks, in order to investigate the mechanisms of synchronization of the neural oscillatory activity during cognitive processes, such as object recognition, memory, language, attention; 2) the second one concerns the mathematical modelling of multisensory integration processes (e.g. visual-acoustic), which occur in several cortical and subcortical regions (in particular in a subcortical structure named Superior Colliculus (SC)), and which are fundamental for orienting motor and attentive responses to external world stimuli. This activity has been realized in collaboration with the Center for Studies and Researches in Cognitive Neuroscience of the University of Bologna (in Cesena) and the Department of Neurobiology and Anatomy of the Wake Forest University School of Medicine (NC, USA). PART 1. Objects representation in a number of cognitive functions, like perception and recognition, foresees distribute processes in different cortical areas. One of the main neurophysiological question concerns how the correlation between these disparate areas is realized, in order to succeed in grouping together the characteristics of the same object (binding problem) and in maintaining segregated the properties belonging to different objects simultaneously present (segmentation problem). Different theories have been proposed to address these questions (Barlow, 1972). One of the most influential theory is the so called “assembly coding”, postulated by Singer (2003), according to which 1) an object is well described by a few fundamental properties, processing in different and distributed cortical areas; 2) the recognition of the object would be realized by means of the simultaneously activation of the cortical areas representing its different features; 3) groups of properties belonging to different objects would be kept separated in the time domain. In Chapter 1.1 and in Chapter 1.2 we present two neural network models for object recognition, based on the “assembly coding” hypothesis. These models are networks of Wilson-Cowan oscillators which exploit: i) two high-level “Gestalt Rules” (the similarity and previous knowledge rules), to realize the functional link between elements of different cortical areas representing properties of the same object (binding problem); 2) the synchronization of the neural oscillatory activity in the γ-band (30-100Hz), to segregate in time the representations of different objects simultaneously present (segmentation problem). These models are able to recognize and reconstruct multiple simultaneous external objects, even in difficult case (some wrong or lacking features, shared features, superimposed noise). In Chapter 1.3 the previous models are extended to realize a semantic memory, in which sensory-motor representations of objects are linked with words. To this aim, the network, previously developed, devoted to the representation of objects as a collection of sensory-motor features, is reciprocally linked with a second network devoted to the representation of words (lexical network) Synapses linking the two networks are trained via a time-dependent Hebbian rule, during a training period in which individual objects are presented together with the corresponding words. Simulation results demonstrate that, during the retrieval phase, the network can deal with the simultaneous presence of objects (from sensory-motor inputs) and words (from linguistic inputs), can correctly associate objects with words and segment objects even in the presence of incomplete information. Moreover, the network can realize some semantic links among words representing objects with some shared features. These results support the idea that semantic memory can be described as an integrated process, whose content is retrieved by the co-activation of different multimodal regions. In perspective, extended versions of this model may be used to test conceptual theories, and to provide a quantitative assessment of existing data (for instance concerning patients with neural deficits). PART 2. The ability of the brain to integrate information from different sensory channels is fundamental to perception of the external world (Stein et al, 1993). It is well documented that a number of extraprimary areas have neurons capable of such a task; one of the best known of these is the superior colliculus (SC). This midbrain structure receives auditory, visual and somatosensory inputs from different subcortical and cortical areas, and is involved in the control of orientation to external events (Wallace et al, 1993). SC neurons respond to each of these sensory inputs separately, but is also capable of integrating them (Stein et al, 1993) so that the response to the combined multisensory stimuli is greater than that to the individual component stimuli (enhancement). This enhancement is proportionately greater if the modality-specific paired stimuli are weaker (the principle of inverse effectiveness). Several studies have shown that the capability of SC neurons to engage in multisensory integration requires inputs from cortex; primarily the anterior ectosylvian sulcus (AES), but also the rostral lateral suprasylvian sulcus (rLS). If these cortical inputs are deactivated the response of SC neurons to cross-modal stimulation is no different from that evoked by the most effective of its individual component stimuli (Jiang et al 2001). This phenomenon can be better understood through mathematical models. The use of mathematical models and neural networks can place the mass of data that has been accumulated about this phenomenon and its underlying circuitry into a coherent theoretical structure. In Chapter 2.1 a simple neural network model of this structure is presented; this model is able to reproduce a large number of SC behaviours like multisensory enhancement, multisensory and unisensory depression, inverse effectiveness. In Chapter 2.2 this model was improved by incorporating more neurophysiological knowledge about the neural circuitry underlying SC multisensory integration, in order to suggest possible physiological mechanisms through which it is effected. This endeavour was realized in collaboration with Professor B.E. Stein and Doctor B. Rowland during the 6 months-period spent at the Department of Neurobiology and Anatomy of the Wake Forest University School of Medicine (NC, USA), within the Marco Polo Project. The model includes four distinct unisensory areas that are devoted to a topological representation of external stimuli. Two of them represent subregions of the AES (i.e., FAES, an auditory area, and AEV, a visual area) and send descending inputs to the ipsilateral SC; the other two represent subcortical areas (one auditory and one visual) projecting ascending inputs to the same SC. Different competitive mechanisms, realized by means of population of interneurons, are used in the model to reproduce the different behaviour of SC neurons in conditions of cortical activation and deactivation. The model, with a single set of parameters, is able to mimic the behaviour of SC multisensory neurons in response to very different stimulus conditions (multisensory enhancement, inverse effectiveness, within- and cross-modal suppression of spatially disparate stimuli), with cortex functional and cortex deactivated, and with a particular type of membrane receptors (NMDA receptors) active or inhibited. All these results agree with the data reported in Jiang et al. (2001) and in Binns and Salt (1996). The model suggests that non-linearities in neural responses and synaptic (excitatory and inhibitory) connections can explain the fundamental aspects of multisensory integration, and provides a biologically plausible hypothesis about the underlying circuitry.

Quantitative Untersuchungen zur mRNA-Expression verschiedener Neurotransmitterrezeptoren im Verlauf der neuronalen Entwicklung der Zellinie PCC7-Mz1

Die murine embryonale Karzinomazellinie PCC7-Mz1 stellt ein Modell neuronaler Entwicklung dar, da nach RA-Gabe eine Differenzierung in neuronale, gliale und fibroblastoide Phänotypen erfolgt. Um die Expression von Neurotransmitterrezeptoren während der neuronalen Entwicklung zu untersuchen, wurde in dieser Arbeit eine quantitative Analyse der Expression verschiedener Neurotransmitterrezeptoren im Verlauf der RA-induzierten Differenzierung der PCC7-Mz1 Zellen durchgeführt. Zu diesem Zweck wurde eine kompetitive RT-PCR eingesetzt. Als Kompetitor wurde ein synthetisches Gen ( SG) konstruiert, das sich aus den Antisense- und Sense-Primersequenzen zur spezifischen Amplifikation des Dopaminrezeptors D2, des Serotoninrezeptors 5HT3, der GABAA-Untereinheiten ß1 und ß3, der metabotropen Glutamatrezeptoren mGluR1 und mGluR5, der 5 NMDA-Rezeptoruntereinheiten 1,2a,2b,2c und 2d, der Markerproteine Synaptophysin und GFAP, und der Untereinheiten a3, a4 und a7 des nikotinischen Acetylcholinrezeptors zusammensetzt. Mit diesem SG erfolgten die Quantifizierungen der Rezeptor-mRNA im Sättigungsbereich der PCR. Die erhaltenen Transkriptmengen wurden auf ein Neuron bezogen, wodurch eine Korrelation zur neuronalen Entwicklung erfolgen konnte.

Charakterisierung synapsenassoziierter Proteine des Haushuhns (Gallus gallus domesticus)

Charakterisierung synapsenassoziierter Proteine des Haushuhns(Gallus gallus domesticus) Die Familie der synapsenassoziierten Proteine (SAP) umfaßt bei Säugern vier Proteine: SAP90 (=PSD-95), SAP97, SAP102 (=PSD-93) und Chapsyn110. Die Proteine enthalten charakteristischerweise drei PDZ-Domänen, eine SH3-Domäne und eine GK-Domäne über die sie mit anderen Proteinen interagieren können. SAP können so Verbindungen zwischen Neurotransmitterrezeptoren und Signaltransduktionsmolekülen sowie dem Zytoskelett herstellen.In dieser Arbeit wurden die synapsenassoziierten Proteine des Huhns charakterisiert. Die cDNAs von SAP90, SAP97 und Chapsyn110 wurden sequenziert. Die cDNA von SAP102 wurde teilweise sequenziert. Die Analyse genomischer DNA durch PCR ergab, daß die SAP90- und SAP97-mRNA von einem Gen transkribiert werden. Die mRNA-Verteilung von SAP90, SAP97 und Chapsyn110 im Gehirn einen Tag alter Küken wurde mit in situ Hybridisierung untersucht. Die Verteilung der SAP90-mRNA und von NMDA-Rezeptoren im Gehirn des Huhns ist sehr ähnlich. Weiterhin wurde bei Küken untersucht, inwieweit SAP bei der Prägung eine Rolle spielen. Der relative mRNA-Gehalt von SAP90, SAP97 und Chapsyn110 wurde 30 Minuten, 5 Stunden und 10 Stunden nach einer akustische Prägung der Küken gemessen. Fünf Stunden nach akustischer Prägung war der Gehalt der SAP90-mRNA, im anterioren lateralen Hyperstriatum ventrale um 13% erhöht. Der mRNA-Gehalt in anderen Regionen und der anderen SAP-Gene war unverändert.

Synthese, n.c.a. 18F-Markierung und Evaluierung von Antagonisten der Strychnin-unempfindlichen-Glycinbindungsstelle auf Basis der 4-Amino-5,7-Dichlor-1,2,3,4-Tetrahydro-Chinolin-2-Carbonsäure

ZUSAMMENFASSUNGDer glutamaterge N-Methyl-D-aspartat-Rezeptor (NMDA) ist ein wichtiger ionotroper Rezeptor, der die exzitatorische synaptische Transmission im zentralen Nervensystem von Säugetieren vermittelt. Der NMDA-Rezeptor nimmt unter den Glutamatrezeptoren dabei eine Sonderstellung ein, da er mit einer Reihe von neurodegenerativen Erkrankungen wie dem Morbus Parkinson, dem Morbus Huntington, dem Morbus Alzheimer, der Schizophrenie und der Epilepsie in Zusammenhang gebracht wird. Daher besteht ein großes Interesse an der Entwicklung geeigneter 18F-markierter NMDA-Rezeptorliganden zur nicht-invasiven Visualisierung des NMDA-Rezeptorkomplexes mittels der Positronenemissionstomographie.Die 19F-Analoga ADTC1, tADTC1 und tADTC3 - 5 und das nicht-fluorierte 12C-Analogon tADTC2 wurden synthetisiert und ihre in-vitro Affinität und Lipophilie bestimmt. Mit Ausnahme von ADTC1 und tADTC5 die mikromolare Affinitäten besitzen, haben die Liganden in [H-3]MDL-105,519 Rezeptorbindungsassays niedrige nanomolare Affinitäten für die Glycinbindungsstelle. Die Lipophilie der Verbindungen wurde mit drei verschiedenen Verfahren untersucht und ergab logD7,4-Werte von ungefähr 1 für cADTC1 und tADTC1 – 4, während tADTC5 mit einem logD7,4 von –1,15 eine sehr niedrige Lipophilie aufwies. Die Radiosynthesen der 18F-Liganden wurden hinsichtlich der Umsetzung der Markierungsvorläufer mit 2-[F-18]Fluorethyltosylat oder [F-18]Fluorid untersucht und optimiert. Die höchsten radiochemischen Ausbeuten von ungefähr 90% wurden, unter Verwendung von NaOH als Hilfsbase, bei der 18F-Fluorethylierung von t[F-18]ADTC4 und t[F-18]ADTC5 mit 2-[F-18]Fluorethyltosylat erzielt.

Multi-target-directed ligands: application to the Alzheimer's disease

The MTDL (multi-target-directed ligand) design strategy is used to develop single chemical entities that are able to simultaneously modulate multiple targets. The development of such compounds might disclose new avenues for the treatment of a variety of pathologies (e.g. cancer, AIDS, neurodegenerative diseases), for which an effective cure is urgently needed. This strategy has been successfully applied to Alzheimer’s disease (AD) due to its multifactorial nature, involving cholinergic dysfunction, amyloid aggregation, and oxidative stress. Despite many biological entities have been recognized as possible AD-relevant, only four achetylcholinesterase inhibitors (AChEIs) and one NMDA receptor antagonist are used in therapy. Unfortunately, such compounds are not disease-modifying agents behaving only as cognition enhancers. Therefore, MTDL strategy is emerging as a powerful drug design paradigm: pharmacophores of different drugs are combined in the same structure to afford hybrid molecules. In principle, each pharmacophore of these new drugs should retain the ability to interact with its specific site(s) on the target and, consequently, to produce specific pharmacological responses that, taken together, should slow or block the neurodegenerative process. To this end, the design and synthesis of several examples of MTDLs for combating neurodegenerative diseases have been published. This seems to be the more appropriate approach for addressing the complexity of AD and may provide new drugs for tackling the multifactorial nature of AD, and hopefully stopping its progression. According to this emerging strategy, in this work thesis different classes of new molecular structures, based on the MTDL approach, have been developed. Moreover, curcumin and its constrained analogs have currently received remarkable interest as they have a unique conjugated structure which shows a pleiotropic profile that we considered a suitable framework in developing MTDLs. In fact, beside the well-known direct antioxidant activity, curcumin displays a wide range of biological properties including anti-inflammatory and anti-amyloidogenic activities and an indirect antioxidant action through activation of the cytoprotective enzyme heme oxygenase (HO-1). Thus, since many lines of evidence suggest that oxidative stess and mitochondria impairment have a cental role in age-related neurodegenerative diseases such as AD, we designed mitochondria-targeted antioxidants by connecting curcumin analogs to different polyamine chains that, with the aid of electrostatic force, might drive the selected antioxidant moiety into mitochondria.

Physiologische Untersuchungen an der Stäbchenbahn der Nagerretina

AII Amakrinzellen sind Interneurone in der Retina und ein wichtiges Element der Stäbchenbahn von Säugetieren. Bei ihren Antworten auf Lichtreize generieren sie Aktionspotentiale, obwohl die ihnen vor- und nachgeschalteten Bipolarzellen graduierte Membranpotentiale aufweisen. Um die Verarbeitung der Lichtsignale in der Stäbchenbahn der Säuger besser zu verstehen wurden in der vorliegenden Arbeit Membranströme von AII Amakrinzellen und Veränderungen der intrazellulären Kalziumkonzentration mittels Indikatorfarbstoffe bei Mäusen simultan gemessen.Die spannungsabhängigen Kalziumkanäle waren durch eine negative Aktivierungsschwelle und eine sehr langsame Inaktivierung gekennzeichnet¸ ausserdem wurden sie von Dihydropyridinen (Agonisten und Antagonisten) moduliert. Sie fanden sich vor allem auf den keulenförmigen Fortsätzen von AII Amakrinzellen. Lokale Applikationen von Glutamat, AMPA oder Kainat lösten einwärtsgerichtete Ströme aus. Diese Ströme gingen einher mit einer Erhöhung der Fluoreszenz und zwar vor allem in den distalen Dendriten. NMDA löste keine Veränderung der Kalziumkonzentration aus und nur in wenigen Fällen Ströme (7 von 23).Diese Befunde deuten darauf hin, dass es sich bei den ionotropen Glutamat-Rezeptoren auf AII Amakrinzellen um solche vom AMPA Typ handelt. Diese befinden sich, sofern sie kalziumpermeabel sind (oder durch andere Mechanismen zu einer Erhöhung der [Ca2+]i führen) auf den distalen Dendriten nahe der Ganglienzellschicht.

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).

Inhibierung des IL-17A vermittelten Blut-Hirnschrankenversagens in experimenteller Autoimmunenzephalomyelitis (EAE) und Mikrogliaaktivierung durch IL-17A

Experimentelle Autoimmunenzephalomyelitis (EAE) ist das Tiermodell für Multiple Sklerose (MS). Es ist bekannt, dass das proinflammatorische Zytokin IL-17A eine wichtige Rolle in MS und EAE spielt. Dieses wird hauptsächlich von einer Subpopulation der T-Helferzellen (Th17 Zellen) exprimiert. Es war bekannt, dass diese am Zusammenbruch der Blut-Hirnschranke (BHS) beteiligt sind. Der Integritätsverlust der BHS ist ein wichtiger und früher Aspekt in der Pathogenese von EAE und MS. Daraufhin können Immunzellen in das zentrale Nervensystem (ZNS) eindringen. Spezifische T-Zellen greifen das Myelin an und führen so zu einer Entzündungsreaktion, Demyelinisierung und axonalem Schaden. In dieser Arbeit konnte ich zeigen, dass durch Hemmung des kontraktilen endothelialen Apparates das BHS Versagen vermindert werden kann und es dadurch zu einem milderen Verlauf der EAE Pathogenese kommt. Wird der Inhibitor der Myosinleichtkettenkinase ML-7 C57/bl6 Mäusen, bei denen EAE induziert wurde, intraperitoneal verabreicht, kommt es zu einem geringeren Phosphorylierungsgrad der leichten Kette des Myosins in Endothelzellen und folglich zu einem verringerten Schrankenversagen. Außerdem konnte ich zeigen, dass weniger reaktive Sauerstoffspezies (ROS) gebildet werden. Folglich kommt es zu einer geringeren Infiltration von Immunzellen aus der Peripherie in das ZNS. Somit werden weniger Zytokine und auch Matrixmetalloproteinasen (MMP) ausgeschüttet, wodurch die Entzündungsreaktion weniger stark ausgeprägt ist. Außerdem werden weniger Mikrogliazellen aktiviert. Ich habe den Zusammenhang zwischen Mikrogliazellaktivierung und IL-17A näher untersucht. Dieses proinflammatorische Zytokin aktiviert Mikrogliazellen auch in vitro. Durch IL-17A Stimulation kommt es zur vermehrten ROS Bildung. Folglich kommt es zu einer vermehrten Proliferation und Migration, sowie einer erhöhten Zytokinproduktion. Außerdem konnte ich zeigen, dass der N-Methyl-D-Aspartat (NMDA)-Rezeptor an der Mikrogliaaktivierung beteiligt ist. Abhängig von IL-17A Stimulation kommt es zu einem Kalziumeinstrom über den NMDA-Rezeptor. Werden Inhibitoren des NMDA-Rezeptors eingesetzt, können IL-17A vermittelte Proliferation, Migration, Zytokin-und ROS-Produktion verhindert werden. Der NMDA-Rezeptor ist sehr gut in Neuronen erforscht, wohingegen bisher sehr wenig über seine Funktion in Gliazellen bekannt war. In dieser Arbeit ist es mir gelungen einen Zusammenhang zwischen IL-17A vermittelter Mikrogliaaktivierung und Kalziumeinstrom über den NMDA-Rezeptor herzustellen.