Your search keyword '"Schmitz, Dietmar"' showing total 16 results

1. Generation of Sharp Wave-Ripple Events by Disinhibition.

Author

Evangelista, Roberta, Cano, Gaspar, Cooper, Claire, Schmitz, Dietmar, Maier, Nikolaus, and Kempter, Richard

Subjects

PYRAMIDAL neurons, ACTION potentials, INTERNEURONS, GENERATIONS, HIPPOCAMPUS (Brain)

Abstract

Sharp wave-ripple complexes (SWRs) are hippocampal network phenomena involved in memory consolidation. To date, the mechanisms underlying their occurrence remain obscure. Here, we show how the interactions between pyramidal cells, parvalbumin- positive (PV+) basket cells, and an unidentified class of anti-SWR interneurons can contribute to the initiation and termination of SWRs. Using a biophysically constrained model of a network of spiking neurons and a rate-model approximation, we demonstrate that SWRs emerge as a result of the competition between two interneuron populations and the resulting disinhibition of pyramidal cells. Our models explain how the activation of pyramidal cells or PVT cells can trigger SWRs, as shown in vitro, and suggests that PV+ cell-mediated short-term synaptic depression influences the experimentally reported dynamics of SWR events. Furthermore, we predict that the silencing of anti-SWR interneurons can trigger SWRs. These results broaden our understanding of the microcircuits supporting the generation of memory-related network dynamics. [ABSTRACT FROM AUTHOR]

Published

2020

2. Loss of Piccolo Function in Rats Induces Cerebellar Network Dysfunction and Pontocerebellar Hypoplasia Type 3-like Phenotypes.

Author

Falck, Joanne, Bruns, Christine, Hoffmann-Conaway, Sheila, Straub, Isabelle, Plautz, Erik J., Orlando, Marta, Munawar, Humaira, Rivalan, Marion, Winter, York, Izsvak, Zsuzsanna, Schmitz, Dietmar, Hamra, Kent, Hallermann, Stefan, Garner, Craig Curtis, and Ackermann, Frauke

Subjects

SYNAPTIC vesicles, GRANULE cells, COST functions, NEURAL transmission, PURKINJE cells, SYNAPSES, GLUCOSE-regulated proteins

Abstract

Piccolo, a presynaptic active zone protein, is best known for its role in the regulated assembly and function of vertebrate synapses. Genetic studies suggest a further link to several psychiatric disorders as well as Pontocerebellar Hypoplasia type 3 (PCH3). We have characterized recently generated Piccolo KO (PcloP/gt) rats. Analysis of rats of both sexes revealed a dramatic reduction in brain size compared with WT (Pclowtlwt) animals, attributed to a decrease in the size of the cerebral cortical, cerebellar, and pontine regions. Analysis of the cerebellum and brainstem revealed a reduced granule cell layer and a reduction in size of pontine nuclei. Moreover, the maturation of mossy fiber afferents from pontine neurons and the expression of the a6 GABAa receptor subunit at the mossy fiber-granule cell synapse are perturbed, as well as the innervation of Purkinje cells by cerebellar climbing fibers. Ultrastructural and functional studies revealed a reduced size of mossy fiber boutons, with fewer synaptic vesicles and altered synaptic transmission. These data imply that Piccolo is required for the normal development, maturation, and function of neuronal networks formed between the brainstem and cerebellum. Consistently, behavioral studies demonstrated that adult PcloP'gt rats display impaired motor coordination, despite adequate performance in tasks that reflect muscle strength and locomotion. Together, these data suggest that loss of Piccolo function in patients with PCH3 could be involved in many of the observed anatomical and behavioral symptoms, and that the further analysis of these animals could provide fundamental mechanistic insights into this devastating disorder. [ABSTRACT FROM AUTHOR]

Published

2020

3. Electrophysiological and Molecular Characterization of the Parasubiculum.

Author

Sammons, Rosanna P., Parthier, Daniel, Stumpf, Alexander, and Schmitz, Dietmar

Subjects

ENTORHINAL cortex, SPATIAL memory, NEURONS

Abstract

The parahippocampal region is thought to be critical for memory and spatial navigation. Within this region lies the parasubiculum, a small structure that exhibits strong theta modulation, contains functionally specialized cells, and projects to layer II of the medial entorhinal cortex (MEC). Thus, it is uniquely positioned to influence firing of spatially modulated cells in the MEC and play a key role in the internal representation of the external environment. However, the basic neuronal composition of the parasubiculum remains largely unknown, and its border with the MEC is often ambiguous. We combine electrophysiology and immunohistochemistry in adult mice (both sexes) to define first, the boundaries of the parasubiculum, and second, the major cell types found in this region. We find distinct differences in the colabeling of molecular markers between the parasubiculum and the MEC, allowing us to clearly separate the two structures. Moreover, we find distinct distribution patterns of different molecular markers within the parasubiculum, across both superficial-deep and DV axes. Using unsupervised cluster analysis, we find that neurons in the parasubiculum can be broadly separated into three clusters based on their electrophysiological properties, and that each cluster corresponds to a different molecular marker. We demonstrate that, while the parasubiculum aligns structurally to some to general cortical principals, it also shows divergent features in particular in contrast to the MEC. This work will form an important basis for future studies working to disentangle the circuitry underlying memory and spatial navigation functions of the parasubiculum. [ABSTRACT FROM AUTHOR]

Published

2019

4. Single Synapse Indicators of Impaired Glutamate Clearance Derived from Fast iGluu Imaging of Cortical Afferents in the Striatum of Normal and Huntington (Q175) Mice.

Author

Dvorzhak, Anton, Helassa, Nordine, Török, Katalin, Schmitz, Dietmar, and Grantyn, Rosemarie

Subjects

AMINO acid transport, SYNAPSES, HUNTINGTON disease, EXCITATORY amino acids, GLUTAMIC acid

Abstract

Changes in the balance between glutamate (Glu) release and uptake may stimulate synaptic reorganization and even synapse loss. In the case of neurodegeneration, a mismatch between astroglial Glu uptake and presynaptic Glu release could be detected if both parameters were assessed independently and at a single-synapse level. This has now become possible due to a new imaging assay with the genetically encoded ultrafast Glu sensor iGluu. We report findings from individual corticostriatal synapses in acute slices prepared from mice of either sex that were > 1 year of age. Contrasting patterns of short-term plasticity and a size criterion identified two classes of terminals, presumably corresponding to the previously defined IT (intratelencephalic) and PT (pyramidal tract) synapses. The latter exhibited a higher degree of frequency potentiation/residual Glu accumulation and were selected for our first iGluu single-synapse study in Q175 mice, a model of Huntington’s disease (HD). In HD mice, the decay time constant of the perisynaptic Glu concentration (TauD), as an indicator of uptake, and the peak iG!u„ amplitude, as an indicator of release, were prolonged and reduced, respectively. Treatment of WT preparations with the astrocytic Glu uptake blocker TFB-TBOA (100 mu) mimicked the TauD changes in homozygotes. Considering the largest TauD values encountered in WT, —40% of PT synapses tested in Q175 heterozygotes can be classified as dysfunctional. Moreover, HD but not WT synapses exhibited a positive correlation between TauD and the peak amplitude of iGluu. Finally, EAAT2 (excitatory amino acid transport protein 2) immunoreactivity was reduced next to corticostriatal terminals. Thus, astrocytic Glu transport remains a promising target for therapeutic intervention. [ABSTRACT FROM AUTHOR]

Published

2019

5. Hippocampal Ripple Oscillations and Inhibition-First Network Models: Frequency Dynamics and Response to GABA Modulators.

Author

Donoso, José R., Kempter, Richard, Schmitz, Dietmar, and Maieiy, Nikolaus

Subjects

HIPPOCAMPUS (Brain), OSCILLATIONS, MEMORY, NEURONS, HYSTERESIS

Abstract

Hippocampal ripples are involved in memory consolidation, but the mechanisms underlying their generation remain unclear. Models relying on interneuron networks in the CA1 region disagree on the predominant source of excitation to interneurons; either "direct," via the Schaffer collaterals that provide feedforward input from CA3 to CA1, or "indirect," via the local pyramidal cells in CA1, which are embedded in a recurrent excitatory-inhibitory network. Here, we used physiologically constrained computational models of basket-cell networks to investigate how they respond to different conditions of transient, noisy excitation. We found that direct excitation of interneurons could evoke ripples (140-220 Hz) that exhibited intraripple frequency accommodation and were frequency-insensitive to GABA modulators, as previously shown in in vitro experiments. In addition, the indirect excitation of the basket-cell network enabled the expression of intraripple frequency accommodation in the fast-gamma range (90-140 Hz), as in vivo. In our model, intraripple frequency accommodation results from a hysteresis phenomenon in which the frequency responds differentially to the rising and descending phases of the transient excitation. Such a phenomenon predicts a maximum oscillation frequency occurring several milliseconds before the peak of excitation. We confirmed this prediction for ripples in brain slices from male mice. These results suggest that ripple and fast-gamma episodes are produced by the same interneuron network that is recruited via different excitatory input pathways, which could be supported by the previously reported intralaminar connectivity bias between basket cells and functionally distinct subpopulations of pyramidal cells in CA1. Together, our findings unify competing inhibition-first models of rhythm generation in the hippocampus. [ABSTRACT FROM AUTHOR]

Published

2018

6. Functional Architecture of the Rat Parasubiculum.

Author

Qiusong Tang, Burgalossi, Andrea, Ebbesen, Christian Laut, Sanguinetti-Scheck, Juan Ignacio, Schmidt, Helene, Tukker, John J., Naumann, Robert, Ray, Saikat, Preston-Ferrer, Patricia, Schmitz, Dietmar, and Brecht, Michael

Subjects

ENTORHINAL cortex, PYRAMIDAL neurons, GRID cells, CALBINDIN, LABORATORY rats

Abstract

The parasubiculum is a major input structure of layer 2 of medial entorhinal cortex, where most grid cells are found. Here we investigated parasubicular circuits of the rat by anatomical analysis combined with juxtacellular recording/Iabeling and tetrode recordings during spatial exploration. In tangential sections, the parasubiculum appears as a linear structure flanking the medial entorhinal cortex mediodorsally. With a length of --5.2 mm and a width of only --0.3 mm (approximately one dendritic tree diameter), the parasubiculum is both one of the longest and narrowest cortical structures. Parasubicular neurons span the height of cortical layers 2 and 3, and we observed no obvious association of deep layers to this structure. The "superficial parasubiculum" (layers 2 and 1) divides into - 1 5 patches, whereas deeper parasubicular sections (layer 3) form a continuous band of neurons. Anterograde tracing experiments show that parasubicular neurons extend long "circumcurrent" axons establishing a "global" internal connectivity. The parasubiculum is a prime target of GABAergic and cholinergic medial septal inputs. Other input structures include the subiculum, presubiculum, and anterior thalamus. Functional analysis of identified and unidentified parasubicular neurons shows strong theta rhythmicity of spiking, a large fraction of head-direction selectivity (50%, 34 of 68), and spatial responses (grid, border and irregular spatial cells, 57%, 39 of 68). Parasubicular output preferentially targets patches of calbindin-positive pyramidal neurons in layer 2 of medial entorhinal cortex, which might be relevant for grid cell function. These findings suggest the parasubiculum might shape entorhinal theta rhythmicity and the (dorsoventral) integration of information across grid scales. [ABSTRACT FROM AUTHOR]

Published

2016

7. Functional Diversity of Subicular Principal Cells during Hippocampal Ripples.

Author

Böhm, Claudia, Yangfan Peng, Maier, Nikolaus, Winterer, Jochen, Poulet, James F. A., Geiger, Jörg R. P., and Schmitz, Dietmar

Subjects

MEMORY, NEOCORTEX, SPREADING cortical depression, NEURAL development, REGENERATION (Biology), GENETICS

Abstract

Cortical and hippocampal oscillations play a crucial role in the encoding, consolidation, and retrieval of memory. Sharp-wave associated ripples have been shown to be necessary for the consolidation of memory. During consolidation, information is transferred from the hippocampus to the neocortex. One of the structures at the interface between hippocampus and neocortex is the subiculum. It is therefore well suited to mediate the transfer and distribution of information from the hippocampus to other areas. By juxtacellular and whole-cell-recordings in awake mice, we show here that in the subiculum a subset of pyramidal cells is activated, whereas another subset is inhibited during ripples. We demonstrate that these functionally different subgroups are predetermined by their cell subtype. Bursting cells are selectively used to transmit information during ripples, whereas the firing probability in regular firing cells is reduced. With multiple patch-clamp recordings in vitro, we show that the cell subtype-specific differences extend into the local network topology. This is reflected in an asymmetric wiring scheme where bursting cells and regular firing cells are recurrently connected among themselves but connections between subtypes exclusively exist from regular to bursting cells. Furthermore, inhibitory connections are more numerous onto regular firing cells than onto bursting cells. We conclude that the network topology contributes to the observed functional diversity of subicular pyramidal cells during sharp-wave associated ripples. [ABSTRACT FROM AUTHOR]

Published

2015

8. Anatomical Organization and Spatiotemporal Firing Patterns of Layer 3 Neurons in the Rat Medial Entorhinal Cortex.

Author

Qiusong Tang, Ebbesen, Christian Laut, Sanguinetti-Scheck, Juan Ignacio, Preston-Ferrer, Patricia, Gundlfinger, Anja, Winterer, Jochen, Beed, Prateep, Ray, Saikat, Naumann, Robert, Schmitz, Dietmar, Brecht, Michael, and Burgalossi, Andrea

Subjects

ENTORHINAL cortex, NEURAL physiology, HIPPOCAMPUS (Brain), ELECTROPHYSIOLOGY, CALBINDIN, THETA rhythm, SPATIOTEMPORAL processes, LABORATORY rats

Abstract

Layer 3 of the medial entorhinal cortex is a major gateway from the neocortex to the hippocampus. Here we addressed structureâ€"function relationships in medial entorhinal cortex layer 3 by combining anatomical analysis with juxtacellular identification of single neurons in freely behaving rats. Anatomically, layer 3 appears as a relatively homogeneous cell sheet. Dual-retrograde neuronal tracing experiments indicate a large overlap between layer 3 pyramidal populations, which project to ipsilateral hippocampus, and the contralateral medial entorhinal cortex. These cells were intermingled within layer 3, and had similar morphological and intrinsic electrophysiological properties. Dendritic trees of layer 3 neurons largely avoided the calbindin-positive patches in layer 2. Identification of layer 3 neurons during spatial exploration (n = 17) and extracellular recordings (n = 52) pointed to homogeneous spatial discharge patterns. Layer 3 neurons showed only weak spiking theta rhythmicity and sparse head-direction selectivity. A majority of cells (50 of 69) showed no significant spatial modulation. All of the ~28% of neurons that carried significant amounts of spatial information (19 of 69) discharged in irregular spatial patterns. Thus, layer 3 spatiotemporal firing properties are remarkably different from those of layer 2, where theta rhythmicity is prominent and spatially modulated cells often discharge in grid or border patterns. [ABSTRACT FROM AUTHOR]

Published

2015

9. Complementary Sensory and Associative Microcircuitry in Primary Olfactory Cortex.

Author

Wiegand, Hauke F., Beed, Prateep, Bendels, Michael H. K., Leibold, Christian, Schmitz, Dietmar, and Johenning, Friedrich W.

Subjects

LABORATORY rats, SENSORY neurons, COGNITIVE ability, OLFACTORY cortex, NEURAL circuitry

Abstract

The three-layered primary olfactory (piriform) cortex is the largest component of the olfactory cortex. Sensory and intracortical inputs converge on principal cells in the anterior piriform cortex (aPC).Wecharacterize organization principles of the sensory and intracortical microcircuitry of layer II and III principal cells in acute slices of rat aPC using laser-scanning photostimulation and fast two-photon population Ca2+ imaging. Layer II and III principal cells are set up on a superficial-to-deep vertical axis. We found that the position on this axis correlates with input resistance and bursting behavior. These parameters scale with distinct patterns of incorporation into sensory and associative microcircuits, resulting in a converse gradient of sensory and intracortical inputs. In layer II, sensory circuits dominate superficial cells, whereas incorporation in intracortical circuits increases with depth. Layer III pyramidal cells receive more intracortical inputs than layer II pyramidal cells, but with an asymmetric dorsal offset. This microcircuit organization results in a diverse hybrid feedforward/recurrent network of neurons integrating varying ratios of intracortical and sensory input depending on a cell's position on the superficial-to-deep vertical axis. Since burstiness of spiking correlates with both the cell's location on this axis and its incorporation in intracortical microcircuitry, the neuronal output mode may encode a given cell's involvement in sensory versus associative processing. [ABSTRACT FROM AUTHOR]

Published

2011

10. Cell-Type-Specific Modulation of Feedback Inhibition by Serotonin in the Hippocampus.

Author

Winterer, Jochen, Stempel, A. Vanessa, Dugladze, Tamar, Földy, Csaba, Maziashvili, Nino, Zivkovic, Aleksandar R., Priller, Josef, Soltesz, Ivan, Gloveli, Tengis, and Schmitz, Dietmar

Subjects

NEUROTRANSMITTERS, NEUROCHEMISTRY, NEURAL transmission, SEROTONIN, GASTROINTESTINAL hormones

Abstract

Midbrain raphe nuclei provide strong serotonergic projections to the hippocampus, in which serotonin (5-HT) exerts differential effects mediated by multiple 5-HT receptor subtypes. The functional relevance of this diversity of information processing is poorly understood. Here we show that serotonin via 5-HT1B heteroreceptors substantially reduces synaptic excitation of cholecystokinin-expressing interneurons in area CA1 of the rat hippocampus, in contrast to parvalbumin-expressing basket cells. The reduction is input specific, affecting only glutamatergic synaptic transmission originating from CA1 pyramidal cells. As a result, serotonin selectively decreases feedback inhibition via 5-HT1B receptor activation and subsequently increases the integration time window for spike generation in CA1 pyramidal cells. Our data imply an important role for serotonergic modulation of GABAergic action in subcortical control of hippocampal output. [ABSTRACT FROM AUTHOR]

Published

2011

11. Neuroligin 1 Is Dynamically Exchanged at Postsynaptic Sites.

Author

Schapitz, Inga U., Behrend, Bardo, Pechmann, Yvonne, Lappe-Siefke, Corinna, Kneussel, Silas J., Wallace, Karen E., Stempel, A. Vanessa, Buck, Fritz, Grant, Seth G. N., Schweizer, Michaela, Schmitz, Dietmar, Schwarz, Jurgen R., Holzbaur, Erika L. F., and Kneussel, Matthias

Subjects

CELL adhesion molecules, NEURAL transmission, MICROTUBULES, MEMBRANE proteins, LABORATORY mice, MUTAGENESIS, CYTOSKELETON

Abstract

Neuroligins are postsynaptic cell adhesion molecules that associate with presynaptic neurexins. Both factors form a transsynaptic connection, mediate signaling across the synapse, specify synaptic functions, and play a role in synapse formation. Neuroligin dysfunction impairs synaptic transmission, disrupts neuronal networks, and is thought to participate in cognitive diseases. Here we report that chemical treatment designed to induce long-term potentiation or long-term depression (LTD) induces neuroligin 1/3 turnover, leading to either increased or decreased surface membrane protein levels, respectively. Despite its structural role at a crucial transsynaptic position, GFP-neuroligin 1 leaves synapses in hippocampal neurons over time with chemical LTD-induced neuroligin internalization depending on an intact microtubule cytoskeleton. Accordingly, neuroligin 1 and its binding partner postsynaptic density protein-95 (PSD-95) associate with components of the dynein motor complex and undergo retrograde cotransport with a dynein subunit. Transgenic depletion of dynein function in mice causes postsynaptic NLG1/3 and PSD-95 enrichment. In parallel, PSD lengths and spine head sizes are significantly increased, a phenotype similar to that observed upon transgenic overexpression ofNLGl (Dahlhaus et al., 2010). Moreover, application of a competitive PSD-95 peptide and neuroligin 1 C-terminal mutagenesis each specifically alter neuroligin I surface membrane expression and interfere with its internalization. Our data suggest the concept that synaptic plasticity regulates neuroligin turnover through active cytoskeleton transport. [ABSTRACT FROM AUTHOR]

Published

2010

12. Dendritic Compartment and Neuronal Output Mode Determine Pathway-Specific Long-Term Potentiation in the Piriform Cortex.

Author

Johenning, Friedrich W., Beed, Prateep S., Trimbuch, Thorsten, Bendels, Michael H. K., Winterer, Jochen, and Schmitz, Dietmar

Subjects

NEURAL circuitry, DENDRITES, NEURONS, NEURAL transmission, SYNAPSES

Abstract

The apical dendrite of layer 2/3 pyramidal cells in the piriform cortex receives two spatially distinct inputs: one projecting onto the distal apical dendrite in sensory layer 1a, the other targeting the proximal apical dendrite in layer 1b. We observe an expression gradient of A-type K+ channels that weakens the backpropagating action potential-mediated depolarization in layer 1a compared with layer 1b. We find that the pairing of presynaptic and postsynaptic firing leads to significantly smaller Ca2+ signals in the distal dendritic spines in layer 1a compared with the proximal spines in layer 1b. The consequence is a selective failure to induce long-term potentiation (LTP) in layer 1a, which can be rescued by pharmacological enhancement of action potential backpropagation. In contrast, LTP induction by pairing presynaptic and postsynaptic firing is possible in layer 1b but requires bursting of the postsynaptic cell. This output mode strongly depends on the balance of excitation and inhibition in the piriform cortex. We show, on the single-spine level, how the plasticity of functionally distinct synapses is gated by the intrinsic electrical properties of piriform cortex layer 2 pyramidal cell dendrites and the cellular output mode. [ABSTRACT FROM AUTHOR]

Published

2009

13. Single-Trial Phase Precession in the Hippocampus.

Author

Schmidt, Robert, Diba, Kamran, Leibold, Christian, Schmitz, Dietmar, Buzsáki, György, and Kempter, Richard

Subjects

HIPPOCAMPUS (Brain), THETA rhythm, STATISTICAL correlation, BIOLOGICAL neural networks, NEUROBIOLOGY, RATS

Abstract

During the crossing of the place field of a pyramidal cell in the rat hippocampus, the firing phase of the cell decreases with respect to the local theta rhythm. This phase precession is usually studied on the basis of data in which many place field traversals are pooled together. Here we study properties of phase precession in single trials. We found that single-trial and pooled-trial phase precession were different with respect to phase-position correlation, phase-time correlation, and phase range. Whereas pooled-trial phase precession may span 360°, the most frequent single-trial phase range was only ~180°. In pooled trials, the correlation between phase and position (r=-0.58) was stronger than the correlation between phase and time (r=-0.27), whereas in single trials these correlations (r=-0.61 for both) were not significantly different. Next, we demonstrated that phase precession exhibited a large trial-to-trial variability. Overall, only a small fraction of the trial-to-trial variability in measures of phase precession (e.g., slope or offset) could be explained by other single-trial properties (such as running speed or firing rate), whereas the larger part of the variability remains to be explained. Finally, we found that surrogate single trials, created by randomly drawing spikes from the pooled data, are not equivalent to experimental single trials: pooling over trials therefore changes basic measures of phase precession. These findings indicate that single trials may be better suited for encoding temporally structured events than is suggested by the pooled data. [ABSTRACT FROM AUTHOR]

Published

2009

14. Role of Amyloid-β Glycine 33 in Oligomerization, Toxicity, and Neuronal Plasticity.

Author

Harmeier, Anja, Wozny, Christian, Rost, Benjamin R., Munter, Lisa-Marie, Haiqing Hua, Georgiev, Oleg, Beyermann, Michael, Hildebrand, Peter W., Weise, Christoph, Schaffner, Walter, Schmitz, Dietmar, and Multhaup, Gerd

Subjects

CELL aggregation, AMYLOID, PEPTIDE antibiotics, ALZHEIMER'S disease, HIPPOCAMPUS (Brain), OLIGOMERS

Abstract

The aggregation of the amyloid-β (Aβ) peptide plays a pivotal role in the pathogenesis of Alzheimer's disease, as soluble oligomers are intimately linked to neuronal toxicity and inhibition of hippocampal long-term potentiation (LTP). In the C-terminal region of Aβ there are three consecutive GxxxG dimerization motifs, which we could previously demonstrate to play a critical role in the generation of Aβ. Here, we show that glycine 33 (G33) of the central GxxxG interaction motif within the hydrophobic Aβ sequence is important for the aggregation dynamics of the peptide. Aβ peptides with alanine or isoleucine substitutions of G33 displayed an increased propensity to form higher oligomers, which we could attribute to conformational changes. Importantly, the oligomers of G33 variants were much less toxic than Aβ42 wild type (WT), in vitro and in vivo. Also, whereas Aβ42 WT is known to inhibit LTP, Aβ42 G33 variants had lost the potential to inhibit LTP. Our findings reveal that conformational changes induced by G33 substitutions unlink toxicity and oligomerization of Aβ on the molecular level and suggest that G33 is the key amino acid in the toxic activity of Aβ. Thus, a specific toxic conformation of Aβ exists, which represents a promising target for therapeutic interventions. [ABSTRACT FROM AUTHOR]

Published

2009

15. Differential cAMP Signaling at Hippocampal Output Synapses.

Author

Wozny, Christian, Maier, Nikolaus, Fidzinski, Pawel, Breustedt, Jörg, Behr, Joachim, and Schmitz, Dietmar

Subjects

HIPPOCAMPUS (Brain), FORSKOLIN, SYNAPSES, PROTEIN kinases, NEUROPLASTICITY

Abstract

cAMP is a critical second messenger involved in synaptic transmission and synaptic plasticity. Here, we show that activation of the adenylyl cyclase by forskolin and application of the cAMP-analog Sp-5,6-DCl-cBIMPS both mimicked and occluded tetanusinduced long-term potentiation (LTP) in subicular bursting neurons, but not in subicular regular firing cells. Furthermore, LTP in bursting cells was inhibited by protein kinase A (PKA) inhibitors Rp-8-CPT-cAMP and H-89. Variations in the degree of EPSC blockade by the low-affinity competitive AMPA receptor-antagonist γ-D-glutamyl-glycine (γ-DGG), analysis of the coefficient of variance as well as changes in short-term potentiation suggest an increase of glutamate concentration in the synaptic cleft after expression of LTP. We conclude that presynaptic LTP in bursting cells requires activation of PKA by a calcium-dependent adenylyl cyclase while LTP in regular firing cells is independent of elevated cAMP levels. Our results provide evidence for a differential role of cAMP in LTP at hippocampal output synapses. [ABSTRACT FROM AUTHOR]

Published

2008

16. Assessing the Role of GLUK5 and GLUK6 at Hippocampal Mossy Fiber Synapses.

Author

Breustedt, Jörg and Schmitz, Dietmar

Subjects

*GENETICS, *CARBOXYLIC acids, *METHANOL, *PHARMACOLOGY, *BIOLOGY

Abstract

It has been suggested recently that presynaptic kainate receptors (KARs) are involved in short-term and long-term synaptic plasticity at hippocampal mossy fiber synapses. Using genetic deletion and pharmacology, we here assess the role of GLUK5 and GLUK6 in synaptic plasticity at hippocampal mossy fiber synapses. We found that the kainate-induced facilitation was completely abolished in the GLUK6 -/- mice, whereas it was unaffected in the GLUK5-/-. Consistent with this finding, synaptic facilitation was reduced in the GLUK6-/- and was normal in the GLUK5-/- . In agreement with these results and ruling out any compensatory effects in the genetic deletion models, application of the GLUK5-specific antagonist LY382884 [(3S,4aR,6S,8aR)-6-(4-carboxyphenyl)methyl-l,2,3,4,4a, 5,6,7,8,8a-decahydroisoquinoline-3-carboxylic acid] did not affect short-term and long-term synaptic plasticity at the hippocampal mossy fiber synapses. We therefore conclude that the facilitatory effects of kainate on mossy fiber synaptic transmission are mediated by GLUK6-containing KARs. [ABSTRACT FROM AUTHOR]

Published

2004