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Saunders, Arpiar

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Saunders

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Arpiar

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Saunders, Arpiar
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Now showing 1 - 8 of 8
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    Corelease of acetylcholine and GABA from cholinergic forebrain neurons
    (eLife Sciences Publications, Ltd, 2015) Saunders, Arpiar; Granger, Adam; Sabatini, Bernardo
    Neurotransmitter corelease is emerging as a common theme of central neuromodulatory systems. Though corelease of glutamate or GABA with acetylcholine has been reported within the cholinergic system, the full extent is unknown. To explore synaptic signaling of cholinergic forebrain neurons, we activated choline acetyltransferase expressing neurons using channelrhodopsin while recording post-synaptic currents (PSCs) in layer 1 interneurons. Surprisingly, we observed PSCs mediated by GABAA receptors in addition to nicotinic acetylcholine receptors. Based on PSC latency and pharmacological sensitivity, our results suggest monosynaptic release of both GABA and ACh. Anatomical analysis showed that forebrain cholinergic neurons express the GABA synthetic enzyme Gad2 and the vesicular GABA transporter (Slc32a1). We confirmed the direct release of GABA by knocking out Slc32a1 from cholinergic neurons. Our results identify GABA as an overlooked fast neurotransmitter utilized throughout the forebrain cholinergic system. GABA/ACh corelease may have major implications for modulation of cortical function by cholinergic neurons. DOI: http://dx.doi.org/10.7554/eLife.06412.001
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    Circuit interactions between the cortex and basal ganglia
    (2014-10-23) Saunders, Arpiar; Sabatini, Bernardo Luis; Uchida, Naoshige; Stevens, Beth; Higley, Mike; Datta, Sandeep Robert
    All animals must adapt their behaviors by experience to survive. In mammals, this adaptive process is thought occur through a synaptic loop involving the cortex, basal ganglia (BG) and thalamus. Here we use transgenic mice and novel recombinant viruses (Chapter 1) to explore the brain circuits that underlie this interaction. Our focus is on how cell types within the BG affect cortical feedback during development and in adulthood. Accepted models postulate that the BG modulate cerebral cortex 1) indirectly via an inhibitory output to thalamus and that this thalamic output is 2) bi-directionally controlled from within the BG by striatal direct (dSPNs) and indirect (iSPNs) pathway spiny neurons. In Chapter 2, we show that activity in iSPNs and dSPNs plays a complementary role in the post-natal synaptic wiring of the BG. Inhibiting iSPNs or dSPNs results in opposite changes in the number of excitatory synapses made onto SPNs from cortical and thalamic inputs. Our results suggest that the cortex-BG-thalamus function in a closed-loop and balanced iSPN/dSPN activity is required for proper synaptic wiring during development. In Chapter 3, we describe a non-thalamic output of the BG to the frontal cortex (FC) emanating from globus pallidus externus (GP). The GP-FC projection consists of two cell types that release GABA and GABA/Acetylcholine, mostly onto cortical interneurons, with the net effect of increasing cortical firing rate. These results suggest that iSPNs and dSPNs can affect cortical output through GP-based disinhibition in addition to thalamus-based excitation. Moreover, GP-FC cells provide a pathway by which drugs that target dopamine receptors for the treatment of neuropsychiatric disorders can act in the BG yet modulate activity in FC. The presence of a direct BG output to cortex extends the looped architecture through which the cortex-BG-thalamus control adaptive behavior and can become dysregulated to cause disease. Together our thesis results support the phenomenology of the BG pathway model, but suggest a major revision to the underlying circuitry.
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    Neuromodulation of excitatory synaptogenesis in striatal development
    (eLife Sciences Publications, Ltd, 2015) Kozorovitskiy, Yevgenia; Peixoto, Rui; Wang, Wengang; Saunders, Arpiar; Sabatini, Bernardo
    Dopamine is released in the striatum during development and impacts the activity of Protein Kinase A (PKA) in striatal spiny projection neurons (SPNs). We examined whether dopaminergic neuromodulation regulates activity-dependent glutamatergic synapse formation in the developing striatum. Systemic in vivo treatment with Gαs-coupled G-protein receptors (GPCRs) agonists enhanced excitatory synapses on direct pathway striatal spiny projection neurons (dSPNs), whereas rapid production of excitatory synapses on indirect pathway neurons (iSPNs) required the activation of Gαs GPCRs in SPNs of both pathways. Nevertheless, in vitro Gαs activation was sufficient to enhance spinogenesis induced by glutamate photolysis in both dSPNs and iSPNs, suggesting that iSPNs in intact neural circuits have additional requirements for rapid synaptic development. We evaluated the in vivo effects of enhanced glutamate release from corticostriatal axons and postsynaptic PKA and discovered a mechanism of developmental plasticity wherein rapid synaptogenesis is promoted by the coordinated actions of glutamate and postsynaptic Gαs-coupled receptors. DOI: http://dx.doi.org/10.7554/eLife.10111.001
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    A direct GABAergic output from the basal ganglia to frontal cortex
    (2014) Saunders, Arpiar; Oldenburg, Ian A.; Berezovskii, Vladimir; Johnson, Caroline; Kingery, Nathan D.; Elliott, Hunter; Xie, Tiao; Gerfen, Charles R.; Sabatini, Bernardo
    The basal ganglia (BG) are phylogenetically conserved subcortical nuclei necessary for coordinated motor action and reward learning1. Current models postulate that the BG modulate cerebral cortex indirectly via an inhibitory output to thalamus, bidirectionally controlled by the BG via direct (dSPNs) and indirect (iSPNs) pathway striatal projection neurons2–4. The BG thalamic output sculpts cortical activity by interacting with signals from sensory and motor systems5. Here we describe a direct projection from the globus pallidus externus (GP), a central nucleus of the BG, to frontal regions of the cerebral cortex (FC). Two cell types make up the GP-FC projection, distinguished by their electrophysiological properties, cortical projections and expression of choline acetyltransferase (ChAT), a synthetic enzyme for the neurotransmitter acetylcholine (ACh). Despite these differences, ChAT+ cells, which have been historically identified as an extension of the nucleus basalis (NB), as well as ChAT− cells, release the inhibitory neurotransmitter GABA (γ-aminobutyric acid) and are inhibited by iSPNs and dSPNs of dorsal striatum. Thus GP-FC cells comprise a direct GABAergic/cholinergic projection under the control of striatum that activates frontal cortex in vivo. Furthermore, iSPN inhibition of GP-FC cells is sensitive to dopamine 2 receptor signaling, revealing a pathway by which drugs that target dopamine receptors for the treatment of neuropsychiatric disorders can act in the BG to modulate frontal cortices.
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    Globus Pallidus Externus Neurons Expressing parvalbumin Interconnect the Subthalamic Nucleus and Striatal Interneurons
    (Public Library of Science, 2016) Saunders, Arpiar; Huang, Kee Wui; Sabatini, Bernardo
    The globus pallidus externus (GP) is a nucleus of the basal ganglia (BG), containing GABAergic projection neurons that arborize widely throughout the BG, thalamus and cortex. Ongoing work seeks to map axonal projection patterns from GP cell types, as defined by their electrophysiological and molecular properties. Here we use transgenic mice and recombinant viruses to characterize parvalbumin expressing (PV+) GP neurons within the BG circuit. We confirm that PV+ neurons 1) make up ~40% of the GP neurons 2) exhibit fast-firing spontaneous activity and 3) provide the major axonal arborization to the STN and substantia nigra reticulata/compacta (SNr/c). PV+ neurons also innervate the striatum. Retrograde labeling identifies ~17% of pallidostriatal neurons as PV+, at least a subset of which also innervate the STN and SNr. Optogenetic experiments in acute brain slices demonstrate that the PV+ pallidostriatal axons make potent inhibitory synapses on low threshold spiking (LTS) and fast-spiking interneurons (FS) in the striatum, but rarely on spiny projection neurons (SPNs). Thus PV+ GP neurons are synaptically positioned to directly coordinate activity between BG input nuclei, the striatum and STN, and thalamic-output from the SNr.
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    Recurrent network activity drives striatal synaptogenesis
    (2012) Kozorovitskiy, Yevgenia; Saunders, Arpiar; Johnson, Caroline; Lowell, Bradford; Sabatini, Bernardo
    Neural activity during development critically shapes postnatal wiring of the mammalian brain. This is best illustrated by the sensory systems, in which the patterned feed-forward excitation provided by sensory organs and experience drives the formation of mature topographic circuits capable of extracting specific features of sensory stimuli1,2. In contrast, little is known about the role of early activity in the development of the basal ganglia, a phylogenetically ancient group of nuclei fundamentally important for complex motor action and reward-based learning3,4. These nuclei lack direct sensory input and are only loosely topographically organized5,6, forming interlocking feed-forward and feed-back inhibitory circuits without laminar structure. Here we use transgenic mice and viral gene transfer methods to modulate neurotransmitter release and neuronal activity in vivo in the developing striatum. We find that the balance of activity among the two inhibitory and antagonist pathways in the striatum regulates excitatory innervation of the basal ganglia during development. These effects indicate that the propagation of activity through a multi-stage network regulates the wiring of the basal ganglia, revealing an important role of positive feedback in driving network maturation.
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    Vesicular Stomatitis Virus with the Rabies Virus Glycoprotein Directs Retrograde Transsynaptic Transport Among Neurons In Vivo
    (Frontiers Media S.A., 2013) Beier, Kevin Thomas; Saunders, Arpiar; Oldenburg, Ian Anton; Sabatini, Bernardo; Cepko, Constance
    Defining the connections among neurons is critical to our understanding of the structure and function of the nervous system. Recombinant viruses engineered to transmit across synapses provide a powerful approach for the dissection of neuronal circuitry in vivo. We recently demonstrated that recombinant vesicular stomatitis virus (VSV) can be endowed with anterograde or retrograde transsynaptic tracing ability by providing the virus with different glycoproteins. Here we extend the characterization of the transmission and gene expression of recombinant VSV (rVSV) with the rabies virus glycoprotein (RABV-G), and provide examples of its activity relative to the anterograde transsynaptic tracer form of rVSV. rVSV with RABV-G was found to drive strong expression of transgenes and to spread rapidly from neuron to neuron in only a retrograde manner. Depending upon how the RABV-G was delivered, VSV served as a polysynaptic or monosynaptic tracer, or was able to define projections through axonal uptake and retrograde transport. In animals co-infected with rVSV in its anterograde form, rVSV with RABV-G could be used to begin to characterize the similarities and differences in connections to different areas. rVSV with RABV-G provides a flexible, rapid, and versatile tracing tool that complements the previously described VSV-based anterograde transsynaptic tracer.
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    Novel recombinant adeno-associated viruses for Cre activated and inactivated transgene expression in neurons
    (Frontiers Media S.A., 2012) Saunders, Arpiar; Johnson, Caroline; Sabatini, Bernardo
    Understanding the organization of the nervous system requires methods for dissecting the contributions of each component cell type to circuit function. One widely used approach combines genetic targeting of Cre recombinase to specific cell populations with infection of recombinant adeno-associated viruses (rAAVs) whose transgene expression is activated by Cre (“Cre-On”). Distinguishing how the Cre-expressing neurons differ functionally from neighboring Cre-negative neurons requires rAAVs that are inactivated by Cre (“Cre-Off”) and can be used in tandem with Cre-On viruses. Here we introduce two rAAV vectors that are inactivated by Cre and carry different fluorophore and optogenetic constructs. We demonstrate single and dual rAAV systems to achieve Cre-On and Cre-Off expression in spatially-intermingled cell populations of the striatum. Using these systems, we uncovered cryptic genomic interactions that occur between multiple Cre-sensitive rAAVs or between Cre-sensitive rAAVs and somatic Cre-conditional alleles and devised methods to avoid these interactions. Our data highlight both important experimental caveats associated with Cre-dependent rAAV use as well as opportunities for the development of improved rAAVs for gene delivery.