Population Of Boutons Research Articles

Different priming states of synaptic vesicles underlie distinct release probabilities at hippocampal excitatory synapses

A stunning example of synaptic diversity is the postsynaptic target cell-type-dependent difference in synaptic efficacy in cortical networks. Here, we show that CA1 pyramidal cell (PC) to fast spiking interneuron (FSIN) connections have 10-fold larger release probability (Pv) than those on oriens lacunosum-moleculare (O-LM) interneurons. Freeze-fracture immunolabeling revealed that different nano-topologies and coupling distances between Ca2+ channels and release sites (RSs) are not responsible for the distinct Pv. Although [Ca2+] transients are 40% larger in FSINs innervating boutons, when [Ca2+] entry is matched in the two bouton populations, EPSCs in O-LM cells are still 7-fold smaller. However, application of a phorbol ester analog resulted in a ∼2.5-fold larger augmentation at PC - O-LM compared to PC - FSIN synapses, suggesting incomplete docking or priming of vesicles. Similar densities of docked vesicles rule out distinct RS occupancies and demonstrate that incompletely primed, but docked, vesicles limit the output of PC - O-LM synapses.

Modular Organization of Signal Transmission in Primate Somatosensory Cortex.

Axonal patches are known as the major sites of synaptic connections in the cerebral cortex of higher order mammals. However, the functional role of these patches is highly debated. Patches are formed by populations of nearby neurons in a topographic manner and are recognized as the termination fields of long-distance lateral connections within and between cortical areas. In addition, axons form numerous boutons that lie outside the patches, whose function is also unknown. To better understand the functional roles of these two distinct populations of boutons, we compared individual and collective morphological features of axons within and outside the patches of intra-areal, feedforward, and feedback pathways by way of tract tracing in the somatosensory cortex of New World monkeys. We found that, with the exception of tortuosity, which is an invariant property, bouton spacing and axonal convergence properties differ significantly between axons within patch and no-patch domains. Principal component analyses corroborated the clustering of axons according to patch formation without any additional effect by the type of pathway or laminar distribution. Stepwise logistic regression identified convergence and bouton density as the best predictors of patch formation. These findings support that patches are specific sites of axonal convergence that promote the synchronous activity of neuronal populations. On the other hand, no-patch domains could form a neuroanatomical substrate to diversify the responses of cortical neurons.

Cell type specific cannabinoid CB1 receptor distribution across the human and non-human primate cortex

Alterations in cannabinoid CB1 receptor (CB1R) are implicated in various psychiatric disorders. CB1R participates in both depolarization induced suppression of inhibition (DSI) and depolarization induced suppression of excitation (DSE), suggesting its involvement in regulating excitatory and inhibitory (E/I) balance. Prior studies examining neuronal cell type specific CB1R distribution have been conducted near exclusively within rodents. Identification of these distribution patterns within the human and non-human primate cortex is essential to increase our insight into its function. Using co-labeling immunohistochemistry and fluorescent microscopy, we examined CB1R protein levels within excitatory and inhibitory boutons of male human and non-human primate prefrontal cortex and auditory cortices, regions involved in the behavioral effects of exogenous cannabinoid exposures. We found that CB1R was present in both bouton populations within all brain regions examined in both species. Significantly higher CB1R levels were found within inhibitory than within excitatory boutons across all regions in both species, although the cell type by brain region interactions differed between the two species. Our results support the importance of conducting more in-depth CB1R examinations to understand how cell type and brain region dependent differences contribute to regional E/I balance regulation, and how aberrations in CB1R distribution may contribute to pathology.

The hippocampus converts dynamic entorhinal inputs into stable spatial maps

SummaryThe medial entorhinal cortex (MEC)-hippocampal network plays a key role in the processing, storage, and recall of spatial information. However, how the spatial code provided by MEC inputs relates to spatial representations generated by principal cell assemblies within hippocampal subfields remains enigmatic. To investigate this coding relationship, we employed two-photon calcium imaging in mice navigating through dissimilar virtual environments. Imaging large MEC bouton populations revealed spatially tuned activity patterns. MEC inputs drastically changed their preferred spatial field locations between environments, whereas hippocampal cells showed lower levels of place field reconfiguration. Decoding analysis indicated that higher place field reliability and larger context-dependent activity-rate differences allow low numbers of principal cells, particularly in the DG and CA1, to provide information about location and context more accurately and rapidly than MEC inputs. Thus, conversion of dynamic MEC inputs into stable spatial hippocampal maps may enable fast encoding and efficient recall of spatio-contextual information.

Direction selectivity in retinal bipolar cell axon terminals

SummaryThe ability to encode the direction of image motion is fundamental to our sense of vision. Direction selectivity along the four cardinal directions is thought to originate in direction-selective ganglion cells (DSGCs) because of directionally tuned GABAergic suppression by starburst cells. Here, by utilizing two-photon glutamate imaging to measure synaptic release, we reveal that direction selectivity along all four directions arises earlier than expected at bipolar cell outputs. Individual bipolar cells contained four distinct populations of axon terminal boutons with different preferred directions. We further show that this bouton-specific tuning relies on cholinergic excitation from starburst cells and GABAergic inhibition from wide-field amacrine cells. DSGCs received both tuned directionally aligned inputs and untuned inputs from among heterogeneously tuned glutamatergic bouton populations. Thus, directional tuning in the excitatory visual pathway is incrementally refined at the bipolar cell axon terminals and their recipient DSGC dendrites by two different neurotransmitters co-released from starburst cells.

The Hippocampus Converts Volatile Entorhinal Inputs into Stable Spatial Maps

The medial entorhinal cortex (MEC)-hippocampal network plays a key role in the processing, storage and recall of spatial information. However, how the spatial code provided by MEC inputs relates to spatial representations generated by principal cell assemblies within hippocampal subfields remains enigmatic. To investigate this coding relationship, we employed two-photon calcium imaging in mice navigating through dissimilar virtual environments. Imaging large MEC bouton populations revealed spatially tuned activity patterns. MEC inputs drastically changed their preferred spatial field locations between environments, whereas hippocampal cells showed lower levels of place field reconfiguration. Decoding analysis indicated that higher place field reliability and larger context-dependent activity-rate differences allow low numbers of principal cells, particularly in the DG and CA1, to provide a more rapid and accurate information about location and context than MEC inputs. Thus, conversion of volatile MEC inputs into stable spatial hippocampal maps may enable fast encoding and efficient recall of spatio-contextual information.

Cortical Presynaptic Boutons Progressively Engulf Spinules as They Mature.

Despite decades of discussion in the neuroanatomical literature, the role of the synaptic “spinule” in synaptic development and function remains elusive. Canonically, spinules are finger-like projections that emerge from postsynaptic spines and can become enveloped by presynaptic boutons. When a presynaptic bouton encapsulates a spinule in this manner, the membrane apposition between the spinule and surrounding bouton can be significantly larger than the membrane interface at the synaptic active zone. Hence, spinules may represent a mechanism for extrasynaptic neuronal communication and/or may function as structural “anchors” that increase the stability of cortical synapses. Yet despite their potential to impact synaptic function, we have little information on the percentages of developing and adult cortical bouton populations that contain spinules, the percentages of these cortical spinule-bearing boutons (SBBs) that contain spinules from distinct neuronal/glial origins, or whether the onset of activity or cortical plasticity are correlated with increased prevalence of cortical SBBs. Here, we employed 2D and 3D electron microscopy to determine the prevalence of spinules in excitatory presynaptic boutons at key developmental time points in the primary visual cortex (V1) of female and male ferrets. We find that the prevalence of SBBs in V1 increases across postnatal development, such that ∼25% of excitatory boutons in late adolescent ferret V1 contain spinules. In addition, we find that a majority of spinules within SBBs at later developmental time points emerge from postsynaptic spines and adjacent boutons/axons, suggesting that synaptic spinules may enhance synaptic stability and allow for axo-axonal communication in mature sensory cortex.

Activity-Dependence of Synaptic Vesicle Dynamics.

The proper function of synapses relies on efficient recycling of synaptic vesicles. The small size of synaptic boutons has hampered efforts to define the dynamical states of vesicles during recycling. Moreover, whether vesicle motion during recycling is regulated by neural activity remains largely unknown. We combined nanoscale-resolution tracking of individual synaptic vesicles in cultured hippocampal neurons from rats of both sexes with advanced motion analyses to demonstrate that the majority of recently endocytosed vesicles undergo sequences of transient dynamical states including epochs of directed, diffusional, and stalled motion. We observed that vesicle motion is modulated in an activity-dependent manner, with dynamical changes apparent in ∼20% of observed boutons. Within this subpopulation of boutons, 35% of observed vesicles exhibited acceleration and 65% exhibited deceleration, accompanied by corresponding changes in directed motion. Individual vesicles observed in the remaining ∼80% of boutons did not exhibit apparent dynamical changes in response to stimulation. More quantitative transient motion analyses revealed that the overall reduction of vesicle mobility, and specifically of the directed motion component, is the predominant activity-evoked change across the entire bouton population. Activity-dependent modulation of vesicle mobility may represent an important mechanism controlling vesicle availability and neurotransmitter release.SIGNIFICANCE STATEMENT Mechanisms governing synaptic vesicle dynamics during recycling remain poorly understood. Using nanoscale resolution tracking of individual synaptic vesicles in hippocampal synapses and advanced motion analysis tools we demonstrate that synaptic vesicles undergo complex sets of dynamical states that include epochs of directed, diffusive, and stalled motion. Most importantly, our analyses revealed that vesicle motion is modulated in an activity-dependent manner apparent as the reduction in overall vesicle mobility in response to stimulation. These results define the vesicle dynamical states during recycling and reveal their activity-dependent modulation. Our study thus provides fundamental new insights into the principles governing synaptic function.

Issue Cover (June 2017)

Front cover: Electron micrograph of a synapse between cerebellar granule cells in culture. Image taken at 80000 magnification. Scale 0.72pixel / nm. In cerebellar granule cells, and using FM1-43 dye to follow SV recycling, two main populations of boutons that differ in their membrane recycling efficiency are observed. We have used Brefeldin A (BFA) to inhibit AP3/AP1-mediated recycling and to test whether the contribution of this pathway could account for such heterogeneous responses. Combining imaging techniques (FM1-43 and vGluT1-pH) and ultrastructural analyses, we found that the AP3/AP1 pathway regulates membrane retrieval and vesicle reformation, albeit exerting a distinct weight on the different populations of boutons depending on their functional maturation. Read the full article ‘Brefeldin A sensitive mechanisms contribute to endocytotic membrane retrieval and vesicle recycling in cerebellar granule cells’ by A. Rampérez, J. Sánchez-Prieto and M. Torres (J. Neurochem. 2017, vol. 141 (5), pp. 662–675) on doi: 10.1111/jnc.14017

Septo-hippocampal GABAergic signaling across multiple modalities in awake mice

Hippocampal interneurons receive GABAergic input from the medial septum. Using two-photon Ca(2+) imaging of axonal boutons in hippocampal CA1 of behaving mice, we found that populations of septo-hippocampal GABAergic boutons were activated during locomotion and salient sensory events; sensory responses scaled with stimulus intensity and were abolished by anesthesia. We found similar activity patterns among boutons with common putative postsynaptic targets, with low-dimensional bouton population dynamics being driven primarily by presynaptic spiking.

Calcium Influx Measured at Single Presynaptic Boutons of Cerebellar Granule Cell Ascending Axons and Parallel Fibers

Action potential-evoked calcium influx into presynaptic boutons is a key determinant of synaptic strength and function. Here, we have examined the calcium dynamics at individual presynaptic boutons of the cerebellar granule cells in the molecular layer of cerebellar slices and investigated whether different subpopulations of granule cell boutons exhibit different calcium dynamics. We found that a population of boutons with low basal calcium clearance rates may activate a second clearance mechanism and exhibit biphasic calcium decay on high calcium influx induced by bursts of action potentials. We also found that boutons on ascending axons and parallel fibers show similar calcium influx amplitudes and calcium clearance rates in response to action potentials. Lastly, we found that parallel fiber boutons located in the inner molecular layer have a higher calcium clearance rate than boutons located in the outer molecular layer. These results suggest that cerebellar granule cell boutons should not be regarded as a homogeneous population, but rather that different subpopulations of boutons may exhibit different properties. The heterogeneity of presynaptic boutons may allow different learned behaviors to be encoded in the same circuit without mutual interference and may be a general mechanism for increasing the computational capacity of the brain.

Calcium dynamics associated with action potentials in single nerve terminals

Event Abstract Back to Event Calcium dynamics associated with action potentials in single nerve terminals Noémi Holderith1* and Zoltán Nusser1 1 Hungarian Academy of Sciences, Laboratory of Cellular Neurophysiology, Institute of Experimental Medicine, Hungary Phasic transmitter release at synapses in the mammalian CNS is regulated by local [Ca2+] transients, which control the fusion of readily releasable vesicles docked at presynaptic active zones. The time course and amplitude of these transients critically determine the properties of the release and consequently the postsynaptic responses. However the spatiotemporal nature of the [Ca2+] transients as well as the precise number and location of the release controlling Ca-channels have remained mostly elusive. Here we used an approach combining two-photon laser-scanning Ca2+ imaging and subsequent electron microscopy to address whether differences in the release probability of individual axon terminals of rat CA3 pyramidal cells (PC) are the direct consequences of variability in presynaptic [Ca2+] transients. We measured volume-averaged Ca2+ signals in many axon terminals of single PCs individually in acute slice preparations. Using an intermediate-affinity Ca2+ indicator Fluo5F and determining the fluorescence signal at a saturating [Ca2+] allowed us to conclude that variability in fluorescent transients in boutons reliably and linearly report variations in [Ca2+]. The largest single action potential-evoked fluorescent transients were less than 0.25 dG/Gsat. Our results demonstrate that at least 120 minutes of whole-cell recording is required to achieve dye equilibration in boutons at a distance of no more than 300 um. We also established that dye saturation (Gsat) can be achieved using long trains of action potentials (100 APs) with high frequency. Single action potential evoked [Ca2+] transients varied up to ~3-fold across different boutons with a coefficient of variation of ~0.4. The release probability of the same bouton population will be determined using optical quantal analysis. Direct measurement of the volume and the active zone of the same boutons using EM 3D reconstruction will enable the direct comparison of the [Ca2+] transients and release probability. Conference: IBRO International Workshop 2010, Pécs, Hungary, 21 Jan - 23 Jan, 2010. Presentation Type: Poster Presentation Topic: Cellular neuroscience Citation: Holderith N and Nusser Z (2010). Calcium dynamics associated with action potentials in single nerve terminals. Front. Neurosci. Conference Abstract: IBRO International Workshop 2010. doi: 10.3389/conf.fnins.2010.10.00047 Copyright: The abstracts in this collection have not been subject to any Frontiers peer review or checks, and are not endorsed by Frontiers. They are made available through the Frontiers publishing platform as a service to conference organizers and presenters. The copyright in the individual abstracts is owned by the author of each abstract or his/her employer unless otherwise stated. Each abstract, as well as the collection of abstracts, are published under a Creative Commons CC-BY 4.0 (attribution) licence (https://creativecommons.org/licenses/by/4.0/) and may thus be reproduced, translated, adapted and be the subject of derivative works provided the authors and Frontiers are attributed. For Frontiers’ terms and conditions please see https://www.frontiersin.org/legal/terms-and-conditions. Received: 20 Apr 2010; Published Online: 20 Apr 2010. * Correspondence: Noémi Holderith, Hungarian Academy of Sciences, Laboratory of Cellular Neurophysiology, Institute of Experimental Medicine, Budapest, Hungary, noemi.holderith@koki.hu Login Required This action requires you to be registered with Frontiers and logged in. To register or login click here. Abstract Info Abstract The Authors in Frontiers Noémi Holderith Zoltán Nusser Google Noémi Holderith Zoltán Nusser Google Scholar Noémi Holderith Zoltán Nusser PubMed Noémi Holderith Zoltán Nusser Related Article in Frontiers Google Scholar PubMed Abstract Close Back to top Javascript is disabled. Please enable Javascript in your browser settings in order to see all the content on this page.

Vagal innervation of the aldosterone-sensitive HSD2 neurons in the NTS

The nucleus of the solitary tract (NTS) contains a unique subpopulation of aldosterone-sensitive neurons. These neurons express the enzyme 11-β-hydroxysteroid dehydrogenase type 2 (HSD2) and are activated by sodium deprivation. They are located in the caudal NTS, a region which is densely innervated by the vagus nerve, suggesting that they could receive direct viscerosensory input from the periphery. To test this possibility, we injected the highly sensitive axonal tracer biotinylated dextran amine (BDA) into the left nodose ganglion in rats. Using confocal microscopy, we observed a sparse input from the vagus to most HSD2 neurons. Roughly 80% of the ipsilateral HSD2 neurons exhibited at least one close contact with a BDA-labeled vagal bouton, although most of these cells received only a few total contacts. Most of these contacts were axo-dendritic (∼ 80%), while ∼ 20% were axo-somatic. In contrast, the synaptic vesicular transporters VGLUT2 or GAD7 labeled much larger populations of boutons contacting HSD2-labeled dendrites and somata, suggesting that direct input from the vagus may only account for a minority of the information integrated by these neurons. In summary, the aldosterone-sensitive HSD2 neurons in the NTS appear to receive a small amount of direct viscerosensory input from the vagus nerve. The peripheral sites of origin and functional significance of this projection remain unknown. Combined with previously-identified central sources of input to these cells, the present finding indicates that the HSD2 neurons integrate humoral information with input from a variety of neural afferents.

ADAM-10 over-expression increases cortical synaptogenesis

Cortical cholinergic, glutamatergic and GABAergic terminals become upregulated during early stages of the transgenic amyloid pathology. Abundant evidence suggests that sAPPα, the product of the non-amyloidogenic α-secretase pathway, is neurotrophic both in vitro and when exogenously applied in vivo. The disintegrin metalloprotease ADAM-10 has been shown to have α-secretase activity in vivo. To determine whether sAPPα has an endogenous biological influence on cortical presynaptic boutons in vivo, we quantified cortical cholinergic, glutamatergic and GABAergic presynaptic bouton densities in either ADAM-10 moderate expressing (ADAM-10 mo) transgenic mice, which moderately overexpress ADAM-10, or age-matched non-transgenic controls. Both early and late ontogenic time points were investigated. ADAM-10 mo transgenic mice display significantly elevated cortical cholinergic, glutamatergic and GABAergic presynaptic bouton densities at the early time point (8 months). Only the cholinergic presynaptic bouton density remains significantly elevated in late-staged ADAM-10 mo transgenic animals (18 months). To confirm that the observed elevations were due to increased levels of endogenous murine sAPPα, exogenous human sAPPα was infused into the cortex of non-transgenic control animals for 1 week. Exogenous infusion of sAPPα led to significant elevations in the cholinergic, glutamatergic and GABAergic cortical presynaptic bouton populations. These results are the first to demonstrate an in vivo influence of ADAM-10 on neurotransmitter-specific cortical synaptic plasticity and further confirm the neurotrophic influence of sAPPα on cortical synaptogenesis.

The impact of Aβ-plaques on cortical cholinergic and non-cholinergic presynaptic boutons in alzheimer's disease-like transgenic mice

A previous study in our laboratory, involving early stage, amyloid pathology in 8-month-old transgenic mice, demonstrated a selective loss of cholinergic terminals in the cerebral and hippocampal cortices of doubly transgenic (APP K670N,M671L+PSl M146L) mice, an up-regulation in the single mutant APP K670N,M671L mice and no detectable change in the PSl M146L transgenics [J Neurosci 19 (1999) 2706]. The present study investigates the impact of amyloid plaques on synaptophysin and vesicular acetylcholine transporter (VAChT) immunoreactive bouton numbers in the frontal cortex of the three transgenic mouse models previously described. When compared as a whole, the frontal cortices of transgenic and control mice show no observable differences in the densities of synaptophysin-immunoreactive boutons. An individual comparison of layer V of the frontal cortex, however, shows a significant increase in density in transgenic models. Analysis of the cholinergic system alone shows significant alterations in the VAChT-immunoreactive bouton densities as evidenced by an increased density in the single (APP K670N,M671L) transgenics and a decreased density in the doubly transgenics (APP K670N,M671L+PSl M146L). In investigating the impact of plaque proximity on bouton density at early stages of the amyloid pathology in our doubly (APP K670N,M671L+PSl M146L) transgenic mouse line, we observed that plaque proximity reduced cholinergic pre-synaptic bouton density by 40%, and yet increased synaptophysin-immunoreactive pre-synaptic bouton density by 9.5%. Distance from plaques (up to 60 μm) seemed to have no effect on bouton density; however a significant inverse relationship was visible between plaque size and cholinergic pre-synaptic bouton density. Finally, the number of cholinergic dystrophic neurites surrounding the truly amyloid, Thioflavin-S + plaque core, was disproportionately large with respect to the incidence of cholinergic boutons within the total pre-synaptic bouton population. Confocal and electron microscopic observations confirmed the preferential infiltration of dystrophic cholinergic boutons into fibrillar amyloid aggregates. We therefore hypothesize that extracellular Aβ aggregation preferentially affects cholinergic terminations prior to progression onto other neurotransmitter systems. This is supported by the observable presence of non-cholinergic sprouting, which may be representative of impending neuritic degeneration.

Aging causes a preferential loss of cholinergic innervation of characterized neocortical pyramidal neurons.

Aging is known to markedly affect the number and structural characteristics of both pre- and post-synaptic sites in the cerebral cortex. There is evidence that lamina V pyramidal neurons, and their basilar dendrites in particular, are affected by age-related decline. Furthermore, layer V is the area where the greatest overall age- related losses in the total population of synaptic boutons and of cholinergic boutons are observed. Since both pyramidal neurons and cortical cholinergic input are characteristically compromised in aging, we investigated whether aging altered the pattern of cholinergic boutons in apposition to the soma, proximal and distal basal dendrites of intracellularly labeled lamina V large pyramidal neurons in the parietal cortex of young and aged rats. We observed a significant age-related decrease in the population of both total and cholinergic boutons apposed to proximal and distal dendrites of layer V large pyramidal neurons. However, the age-related decreases of cholinergic presynaptic boutons were higher than those in the total bouton population apposed to the pyramidal neurons. The average decrease in cholinergic boutons in aged rats was 3.7-fold more pronounced than the diminution in the overall number of presynaptic boutons. Our results add important new evidence in support of the concept that the age-related learning and memory deficits are attributable, at least partially, to a decline in the functional integrity of the forebrain cholinergic systems.

Stability and Plasticity of Developing Synapses in Hippocampal Neuronal Cultures

To explore mechanisms governing the formation, stability, and elimination of synapses during neuronal development, we used FM 1-43 fluorescence imaging to track vesicle turnover at >7000 individually identified developing synapses between embryonic rat hippocampal neurons in culture. The majority of presynaptic boutons were stable in efficacy and position over a period of 1.5 hr. Activity, evoked by burst-patterned field stimulation, decreased presynaptic function across the population of boutons, an effect that required NMDA receptor activation. Decreased FM 1-43 staining correlated with low synapsin-I and synaptophysin immunoreactivities, suggesting that decreased presynaptic function was commensurate with synaptic disassembly. These observations provide new information on the stability of developing presynaptic function and suggest that NMDA receptor activation may regulate the stability of developing synapses.

Synaptic localization of GABAA receptor subunits in the striatum of the rat

The inhibitory amino acid γ-aminobutyric acid (GABA) is widely distributed in the basal ganglia. It plays a critical role in the functioning of the striatum as it is the transmitter of projection neurons and sub-populations of interneurons, as well as afferents from the globus pallidus. Some of the factors controlling GABA transmission are the type(s) of GABA receptor expressed at the site of transmission, their subunit composition, and their location in relation to GABA release sites. To address these issues, we examined the sub-cellular localization of subunits of the GABAA receptor in the striatum of the rat. Sections of freeze-substituted, Lowicryl-embedded striatum were immunolabelled by the post-embedding immunogold technique with antibodies specific for subunits of the GABAA receptor. Immunolabelling for α1, β2/3, and γ2 GABAA receptor subunits was primarily located at symmetrical synapses on perikarya, dendrites, and spines. Quantitative analysis of the distribution of immunolabelling for the β2/3 subunits revealed that the majority of membrane associated immunogold particles were at synapses and that, on average for the whole population, they were evenly distributed across the synapse. Double labelling for the β2/3 subunits and for GABA itself revealed that receptor-positive synapses were formed by at least two populations of terminals. One population (59.3%) of terminals forming receptor-positive synapses was positive for GABA, whereas the other (40.7%) had low or undetectable levels of GABA. Furthermore, the post-synaptic neurons were characterised on neurochemical and morphological grounds as both medium spiny neurons and GABA interneurons. Triple immunolabelling revealed the co-localization of α1, β2/3, and γ2 subunits at some symmetrical axodendritic synapse. It is concluded that fast GABAA-mediated transmission occurs primarily at symmetrical synapses within the striatum, that the populations of boutons giving rise to receptor-positive synapses are heterogeneous, and that previously reported co-existence of different subunits of the GABAA receptor at the cellular level also occurs at the level of individual synapses. J. Comp. Neurol. 416:158–172, 2000. © 2000 Wiley-Liss, Inc.

Synaptic localization of GABAA receptor subunits in the striatum of the rat

The inhibitory amino acid gamma-aminobutyric acid (GABA) is widely distributed in the basal ganglia. It plays a critical role in the functioning of the striatum as it is the transmitter of projection neurons and sub-populations of interneurons, as well as afferents from the globus pallidus. Some of the factors controlling GABA transmission are the type(s) of GABA receptor expressed at the site of transmission, their subunit composition, and their location in relation to GABA release sites. To address these issues, we examined the sub-cellular localization of subunits of the GABA(A) receptor in the striatum of the rat. Sections of freeze-substituted, Lowicryl-embedded striatum were immunolabelled by the post-embedding immunogold technique with antibodies specific for subunits of the GABA(A) receptor. Immunolabelling for alpha1, beta2/3, and gamma2 GABA(A) receptor subunits was primarily located at symmetrical synapses on perikarya, dendrites, and spines. Quantitative analysis of the distribution of immunolabelling for the beta2/3 subunits revealed that the majority of membrane associated immunogold particles were at synapses and that, on average for the whole population, they were evenly distributed across the synapse. Double labelling for the beta2/3 subunits and for GABA itself revealed that receptor-positive synapses were formed by at least two populations of terminals. One population (59.3%) of terminals forming receptor-positive synapses was positive for GABA, whereas the other (40.7%) had low or undetectable levels of GABA. Furthermore, the post-synaptic neurons were characterised on neurochemical and morphological grounds as both medium spiny neurons and GABA interneurons. Triple immunolabelling revealed the co-localization of alpha1, beta2/3, and gamma2 subunits at some symmetrical axodendritic synapse. It is concluded that fast GABA(A)-mediated transmission occurs primarily at symmetrical synapses within the striatum, that the populations of boutons giving rise to receptor-positive synapses are heterogeneous, and that previously reported co-existence of different subunits of the GABA(A) receptor at the cellular level also occurs at the level of individual synapses.

Ultrastructural subtypes of glutamate-immunoreactive terminals on rat trigeminal motoneurones and their relationships with GABA-immunoreactive terminals.

Electron-microscopic immunolabelling methods were used to study the relationships between glutamate-immunoreactive and gamma-aminobutyric acid (GABA)-immunoreactive synapses on trigeminal motoneurones labelled by the retrograde transport of horseradish peroxidase. Serial sections were cut through the motor nucleus, alternate sections were incubated with antibodies to glutamate and GABA, and the immunopositive nerve terminal profiles were recognized using a quantitative, post-embedding immunogold method. Boutons exhibiting high levels of glutamate immunoreactivity and GABA-immunoreactive boutons both formed axo-dendritic and axo-somatic synaptic contacts on labelled motoneurones. Boutons strongly immunopositive for glutamate were not immunopositive for GABA, and vice versa. Strongly glutamate immunoreactive boutons received axo-axonic synaptic contacts but did not form such contacts, while GABA-immunoreactive boutons formed axo-axonic synapses but did not receive them. The presynaptic elements at all axo-axonic synapses on to glutamate-immunoreactive boutons sampled were GABA-immunopositive. These data provide ultrastructural evidence in support of the roles of glutamate and GABA as transmitters at synapses on trigeminal motoneurones, and for presynaptic control of transmission at glutamatergic synapses by GABA acting at receptors at axo-axonic synapses. The vast majority (more than 90%) of strongly glutamate immunoreactive boutons contained spherical synaptic vesicles, in contrast to GABA-immunoreactive boutons, which contained pleomorphic vesicles. Most of the glutamate-immunoreactive boutons (67%) formed asymmetrical synaptic active zones, many of which (47% of total) were associated with subsynaptic dense "Taxi" bodies (T-terminals), while a smaller population of boutons (21%) formed symmetrical synapses, and a few (11%) made synapses associated with subsynaptic cisternae (C-terminals). The heterogeneity of active zone ultrastructure of boutons identified as being glutamatergic on the basis of their high levels of immunolabelling is discussed in relation to possible differences in co-transmitters released, origins of the synaptic input or post-synaptic receptor subtypes activated.