Funktionelle Rolle Medial Septaler Projektionen zum Parasubiculum

Oscillations are a hallmark of brain activity and can be generated by local synchronisation mechanisms. They have been implicated in the communication between brain areas. An important type of oscillations are θ oscillations (4-12 Hz), which are associated with different behaviours, such as movements and navigation, but they also play a crucial role in memory formation and retrieval. One of the major θ rhythm generators in the brain is the medial septum (MS), which with its different types of projecting neurons, innervates many cortical areas and synchronises their activity. I investigated two major projection types of the MS: GABAergic (γ-aminobutyric acid – GABA) and cholinergic (acetylcholine – ACh) projections. Both projections are known to target the medial entorhinal cortex (MEC) and hippocampus. Parvalbumin positive (PV+) projections of the MS, which are GABAergic, are known to synchronise cortical networks via disinhibition often by inhibiting interneurons. In contrast, cholinergic projections of the MS project to a wide range of cell types in the MEC and hippocampus and can have substantially different effects on the target cell (e.g. activation or inhibition). Thus, their function on a network can range from increasing activity through depolarising excitatory cells, to more inhibition of the network by activating interneurons, or even modulating synaptic integration. Previous studies have focussed on identifying projections to the hippocampus and the MEC but did not consider the parasubiculum (PaS), a major input of the MEC. In this study, we electrophysiologically characterised cells in the PaS and demonstrated layer I interneurons to be distinctly different from putative layer II interneurons. The PaS, with its strong θ rhythmic firing cells, was shown to have the highest density of MS PV+ fibres in the parahippocampal formation, suggesting that it is an important target of MS projections and yet MS inputs to the PaS are unknown. Using channelrhodopsin (ChR2), a light sensitive ion channel, expressed in the MS of PV-Cre and ChAT-Cre (choline acetyltransferase) mice in-vivo, I identified GABAergic and cholinergic MS connections to the PaS in-vitro and demonstrated cell type specific projection patterns. I found that PV+ MS projections mainly inhibit interneurons in the PaS, including layer I interneurons, representing a novel cortical target of PV+ MS cells. On the other hand, cholinergic projections depolarise layer I interneurons and have multiple effects on deeper cells of the PaS, leading to a depolarisation or hyperpolarisation. To investigate a potential role of GABAergic projections in θ generation, I recorded local field potentials (LFP) in awake head-fixed mice and entrained oscillations in the PaS by stimulating with light in the MS. In contrast, local stimulation of fibres in the PaS could not entrain oscillation, suggesting that increased activity in the PaS might be required for MS PV+ cells to entrain θ. Taken together, stimulation of PV+ cells in the MS is sufficient to drive oscillations in the PaS, likely via disinhibition in line with other areas as the MEC and hippocampus. However, novel targets in layer I could be involved via cholinergic activation and GABAergic entrainment. Whether cholinergic activation by itself can entrain θ remains to be further investigated.Oszillationen sind ein Kennzeichen von Gehirnaktivität und können durch lokale Synchronisationsmechanismen generiert werden. Sie spielen eine wichtige Rolle bei der Kommunikation zwischen Gehirnarealen. Ein wichtiger Typ von Oszillationen sind θ Oszillationen (4 − 12 Hz), welche mit verschiedenen Verhalten wie Bewegung und Navigation assoziiert sind und eine wichtige Rolle in der Gedächtnisbildung und -abrufung spielen. Einer der wichtigen θ Generatoren im Gehirn ist das Mediale Septum (MS), welches mit seinen verschiedenen projizierenden Neuronen viele kortikale Regionen innerviert. Ich habe zwei Typen von Projektionen des MS untersucht: GABAerge (γ-Aminobuttersäure – GABA) und cholinerge (Acetylcholin – ACh) Projektionen. Beide Typen projizieren zum Medialen Entohinalen Kortex (MEC) und zum Hippocampus. Parvalbumin positive (PV+) Projektionen des MS können kortikale Netzwerke via Disinhibition, durch inhibieren von Interneuronen, synchronisieren. Im Gegensatz dazu projizieren cholinerge Projektionen des MS zu verschiedensten Zelltypen des MEC und des Hippocampus und können unterschiedliche weitreichende Effekte auf Zellen haben (z.B. Aktivierung und Inhibierung). Folglich können die Konsequenzen von Aktivierung des Netzwerkes via Depolarisation von exzitatorischen Zellen, über Inhibierung des Netzwerkes via Aktivierung von Interneuronen bis hin zur Modulation von synaptischer Integration reichen. In der Vergangenheit haben Studien sich auf die Identifizierung von Projektionen zum Hippocampus und MECs fokussiert, jedoch nicht zum Parasubiculum (PaS), eines der bedeutendsten Eingänge des MEC. In dieser Studie haben wir elektrophysiologisch Zellen im PaS charakterisiert und konnten herausstellen, dass Schicht I Zellen sich von anderen vermeintlichen Interneuronen in Schicht II unterscheiden. Das PaS, mit seinen im θ Rhythmus feuernden Zellen, hat die höchste Dichte von MS PV+ Fasern im parahippocampalen Netzwerk, was es als besonderes Ziel für MS Projektionen herausstellt. Dennoch sind Projektionen vom MS zum PaS nicht untersucht worden. Mit Hilfe von Channelrhodopsin (ChR2), einem lichtsensitivem Ionenkanal, welcher im MS von PV-Cre und ChAT-Cre Mäusen exprimiert wurde, konnte ich GABAerge und cholinerge MS Verbindungen zum PaS in-vitro detektieren und Zelltyp-speziefische Projektionen identifizieren. Ich konnte herausstellen, dass PV+ MS Projektionen hauptsächlich Interneurone im PaS inhibieren. Insbesondere Schicht I Interneurone stellen ein neues kortikales Ziel von PV+ MS Zellen dar. Im Gegensatz dazu werden Schicht I Interneurone des PaS durch cholinerge MS Projektionen depolarisiert wohingegen Zellen in tieferen Schichten depolarisiert oder hyperpolarisiert werden können. Um zu zeigen, dass man mit GABAergen Projektionen θ generieren kann, nahm ich das lokale Feldpotential (LFP) in Kopffixierten Mäusen auf und fand, dass man Oszillationen mit MS-Stimulation gleichschalten kann, jedoch eine Stimulation der Fasern im PaS nicht ausreichend ist. Das weist darauf hin, dass eine erhöhte PaS-Aktivität notwendig ist, um θ Oszillationen im PaS zu generieren. Zusammenfassend zeigt sich, dass eine Stimulation der PV+ Zellen im MS ausreichend ist, um im PaS Oszillationen zu generieren. Disinhibierung im PaS ist, ähnlich wie auch im MEC und Hippocampus, ein wahrscheinlicher Mechanismus. Weiterhin könnten jedoch neue Ziele von cholinergen und GABAergen Fasern in Schicht I bei der θ Generierung involviert sein. Ob θ Oszillationen durch cholinerge Projektionen gleichgeschaltet werden kann muss jedoch noch durch weitere Studien gezeigt werden

SamuROI, a Python-Based Software Tool for Visualization and Analysis of Dynamic Time Series Imaging at Multiple Spatial Scales

The measurement of activity in vivo and in vitro has shifted from electrical to optical methods. While the indicators for imaging activity have improved significantly over the last decade, tools for analysing optical data have not kept pace. Most available analysis tools are limited in their flexibility and applicability to datasets obtained at different spatial scales. Here, we present SamuROI (Structured analysis of multiple user-defined ROIs), an open source Python-based analysis environment for imaging data. SamuROI simplifies exploratory analysis and visualization of image series of fluorescence changes in complex structures over time and is readily applicable at different spatial scales. In this paper, we show the utility of SamuROI in Ca2+-imaging based applications at three spatial scales: the micro-scale (i.e., sub-cellular compartments including cell bodies, dendrites and spines); the meso-scale, (i.e., whole cell and population imaging with single-cell resolution); and the macro-scale (i.e., imaging of changes in bulk fluorescence in large brain areas, without cellular resolution). The software described here provides a graphical user interface for intuitive data exploration and region of interest (ROI) management that can be used interactively within Jupyter Notebook: a publicly available interactive Python platform that allows simple integration of our software with existing tools for automated ROI generation and post-processing, as well as custom analysis pipelines. SamuROI software, source code and installation instructions are publicly available on GitHub and documentation is available online. SamuROI reduces the energy barrier for manual exploration and semi-automated analysis of spatially complex Ca2+ imaging datasets, particularly when these have been acquired at different spatial scales.Peer Reviewe

GABAergic Projections from the Medial Septum Selectively Inhibit Interneurons in the Medial Entorhinal Cortex

The medial septum (MS) is required for theta rhythmic oscillations and grid cell firing in the medial entorhinal cortex (MEC). While GABAergic, glutamatergic, and cholinergic neurons project from the MS to the MEC, their synaptic targets are unknown. To investigate whether MS neurons innervate specific layers and cell types in the MEC, we expressed channelrhodopsin-2 in mouse MS neurons and used patch-clamp recording in brain slices to determine the response to light activation of identified cells in the MEC. Following activation of MS axons, we observed fast monosynaptic GABAergic IPSPs in the majority (>60%) of fast-spiking (FS) and low-threshold-spiking (LTS) interneurons in all layers of the MEC, but in only 1.5% of nonstellate principal cells (NSPCs) and in no stellate cells. We also observed fast glutamatergic responses to MS activation in a minority (<5%) of NSPCs, FS, and LTS interneurons. During stimulation of MS inputs at theta frequency (10 Hz), the amplitude of GABAergic IPSPs was maintained, and spike output from LTS and FS interneurons was entrained at low (25–60 Hz) and high (60–180 Hz) gamma frequencies, respectively. By demonstrating cell type-specific targeting of the GABAergic projection from the MS to the MEC, our results support the idea that the MS controls theta frequency activity in the MEC through coordination of inhibitory circuits

Discovery of Dual-Action Membrane-Anchored Modulators of Incretin Receptors

The glucose-dependent insulinotropic polypeptide (GIP) and the glucagon-like peptide-1 (GLP-1) receptors are considered complementary therapeutic targets for type 2 diabetes. Using recombinant membrane-tethered ligand (MTL) technology, the present study focused on defining optimized modulators of these receptors, as well as exploring how local anchoring influences soluble peptide function.Serial substitution of residue 7 in membrane-tethered GIP (tGIP) led to a wide range of activities at the GIP receptor, with [G(7)]tGIP showing enhanced efficacy compared to the wild type construct. In contrast, introduction of G(7) into the related ligands, tGLP-1 and tethered exendin-4 (tEXE4), did not affect signaling at the cognate GLP-1 receptor. Both soluble and tethered GIP and GLP-1 were selective activators of their respective receptors. Although soluble EXE4 is highly selective for the GLP-1 receptor, unexpectedly, tethered EXE4 was found to be a potent activator of both the GLP-1 and GIP receptors. Diverging from the pharmacological properties of soluble and tethered GIP, the newly identified GIP-R agonists, (i.e. [G(7)]tGIP and tEXE4) failed to trigger cognate receptor endocytosis. In an attempt to recapitulate the dual agonism observed with tEXE4, we conjugated soluble EXE4 to a lipid moiety. Not only did this soluble peptide activate both the GLP-1 and GIP receptors but, when added to receptor expressing cells, the activity persists despite serial washes.These findings suggest that conversion of a recombinant MTL to a soluble membrane anchored equivalent offers a means to prolong ligand function, as well as to design agonists that can simultaneously act on more than one therapeutic target

Ocular Dominance Plasticity after Stroke Was Preserved in PSD-95 Knockout Mice.

Neuronal plasticity is essential to enable rehabilitation when the brain suffers from injury, such as following a stroke. One of the most established models to study cortical plasticity is ocular dominance (OD) plasticity in the primary visual cortex (V1) of the mammalian brain induced by monocular deprivation (MD). We have previously shown that OD-plasticity in adult mouse V1 is absent after a photothrombotic (PT) stroke lesion in the adjacent primary somatosensory cortex (S1). Exposing lesioned mice to conditions which reduce the inhibitory tone in V1, such as raising animals in an enriched environment or short-term dark exposure, preserved OD-plasticity after an S1-lesion. Here we tested whether modification of excitatory circuits can also be beneficial for preserving V1-plasticity after stroke. Mice lacking postsynaptic density protein-95 (PSD-95), a signaling scaffold present at mature excitatory synapses, have lifelong juvenile-like OD-plasticity caused by an increased number of AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid) -silent synapses in V1 but unaltered inhibitory tone. In fact, using intrinsic signal optical imaging, we show here that OD-plasticity was preserved in V1 of adult PSD-95 KO mice after an S1-lesion but not in PSD-95 wildtype (WT)-mice. In addition, experience-enabled enhancement of the optomotor reflex of the open eye after MD was compromised in both lesioned PSD-95 KO and PSD-95 WT mice. Basic V1-activation and retinotopic map quality were, however, not different between lesioned PSD-95 KO mice and their WT littermates. The preserved OD-plasticity in the PSD-95 KO mice indicates that V1-plasticity after a distant stroke can be promoted by either changes in excitatory circuitry or by lowering the inhibitory tone in V1 as previously shown. Furthermore, the present data indicate that an increased number of AMPA-silent synapses preserves OD-plasticity not only in the healthy brain, but also in another experimental paradigm of cortical plasticity, namely the long-range influence on V1-plasticity after an S1-lesion

Anoctamin Calcium-Activated Chloride Channels May Modulate Inhibitory Transmission in the Cerebellar Cortex.

Calcium-activated chloride channels of the anoctamin (alias TMEM16) protein family fulfill critical functions in epithelial fluid transport, smooth muscle contraction and sensory signal processing. Little is known, however, about their contribution to information processing in the central nervous system. Here we examined the recent finding that a calcium-dependent chloride conductance impacts on GABAergic synaptic inhibition in Purkinje cells of the cerebellum. We asked whether anoctamin channels may underlie this chloride conductance. We identified two anoctamin channel proteins, ANO1 and ANO2, in the cerebellar cortex. ANO1 was expressed in inhibitory interneurons of the molecular layer and the granule cell layer. Both channels were expressed in Purkinje cells but, while ANO1 appeared to be retained in the cell body, ANO2 was targeted to the dendritic tree. Functional studies confirmed that ANO2 was involved in a calcium-dependent mode of ionic plasticity that reduces the efficacy of GABAergic synapses. ANO2 channels attenuated GABAergic transmission by increasing the postsynaptic chloride concentration, hence reducing the driving force for chloride influx. Our data suggest that ANO2 channels are involved in a Ca2+-dependent regulation of synaptic weight in GABAergic inhibition. Thus, in balance with the chloride extrusion mechanism via the co-transporter KCC2, ANO2 appears to regulate ionic plasticity in the cerebellum

Species-specific differences in synaptic transmission and plasticity

Synaptic transmission and plasticity in the hippocampus are integral factors in learning and memory. While there has been intense investigation of these critical mechanisms in the brain of rodents, we lack a broader understanding of the generality of these processes across species. We investigated one of the smallest animals with conserved hippocampal macroanatomy—the Etruscan shrew, and found that while synaptic properties and plasticity in CA1 Schaffer collateral synapses were similar to mice, CA3 mossy fiber synapses showed striking differences in synaptic plasticity between shrews and mice. Shrew mossy fibers have lower long term plasticity compared to mice. Short term plasticity and the expression of a key protein involved in it, synaptotagmin 7 were also markedly lower at the mossy fibers in shrews than in mice. We also observed similar lower expression of synaptotagmin 7 in the mossy fibers of bats that are evolutionarily closer to shrews than mice. Species specific differences in synaptic plasticity and the key molecules regulating it, highlight the evolutionary divergence of neuronal circuit functions

Expression, crystallization and structure elucidation of γ-terpinene synthase from Thymus vulgaris

The biosynthesis of $\gamma$-terpinene, a precursor of the phenolic isomers thymol and carvacrol found in the essential oil from Thymus sp., is attributed to the activitiy of $\gamma$-terpinene synthase (TPS). Purified $\gamma$-terpinene synthase from T. vulgaris (TvTPS), the Thymus species that is the most widely spread and of the greatest economical importance, is able to catalyze the enzymatic conversion of geranyl diphosphate (GPP) to $\gamma$-terpinene. The crystal structure of recombinantly expressed and purified TvTPS is reported at 1.65 Å resolution, confirming the dimeric structure of the enzyme. The putative active site of TvTPS is deduced from its pronounced structural similarity to enzymes from other species of the Lamiaceae family involved in terpenoid biosynthesis: to (+)-bornyl diphosphate synthase and 1,8-cineole synthase from Salvia sp. and to (4S)-limonene synthase from Mentha spicata

Reversal of GABAergic postsynaptic currents by the ANO2 inhibitor.

<p><b>(A)</b> At a Cl^- concentration of 12 mM in the recording pipette, GABAergic postsynaptic currents were negative (Cl^- efflux), indicating that postsynaptic E_Cl is less negative than V_hold. <b>(B)</b> Shortly after applying 5 μM ANO2 inhibitor, positive currents appear <i>(circles)</i> as some synapses experience a decline of postsynaptic [Cl^-]_i, while others still have high Cl^-<i>(asterisks)</i>. <b>(C)</b> During the continued presence of the ANO2 inhibitor, virtually all postsynaptic currents reverse to positive polarity (Cl^- influx) indicating that GABAergic synapses experience an E_Cl more negative than V_hold. <b>(D)</b> The collected data from 12 Purkinje cells at [Cl^-]_i = 12 mM and V_hold = -60 mV demonstrate the polarity reversal of postsynaptic currents (PSCs) actuated by the ANO2 inhibitor. <b>(E)</b> Schematic representation of an hypothesis for the 12 mM [Cl^-]_i experiment. In the absence of the ANO2 inhibitor <i>(upper scheme)</i>, the basal activity of ANO2 channels <i>(green)</i> provides a Cl^- conductance in the dendritic membrane. ANO2 contributes to the Cl^—transport machinery, whose various pathways are represented by the K⁺/Cl^—cotransporter KCC2 <i>(blue)</i>. Together the Cl^- pathways stabilize a slightly elevated level of [Cl^-]_i which results in a negative driving force (V_m—E_Cl < 0) for Cl^- currents through GABA_A receptors in GABAergic synapses <i>(red)</i>. In this situation, Cl^- currents are outwardly directed and cause negative postsynaptic currents. Application of the ANO2 inhibitor <i>(lower scheme)</i> reduces the Cl^- conductance. This causes a polarity reversal of the Cl^- driving force, as the balance shifts towards Cl^- extrusion, causing local [Cl^-]_i to decrease. This hypothesis provides a qualitative concept for the role of ANO2 channels in the inversion of postsynaptic currents that is depicted in panels A to C. The proximity of Cl^—transport pathways and GABAergic synapses, as well as the occurrence of local Cl^-.gradients within dendritic segments, are inspired by the model for GABA_A-receptor-mediated Cl^- gradients in extended dendritic trees proposed by Jedlicka et al. (2011) [<a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0142160#pone.0142160.ref088" target="_blank">88</a>].</p