David N. Furness scite author profile

The relative distribution of the excitatory amino acid transporter 2 (EAAT2) between synaptic terminals and astroglia, and the importance of EAAT2 for the uptake into terminals is still unresolved. Here we have used antibodies to glutaraldehyde-fixed D-aspartate to identify electron microscopically the sites of D-aspartate accumulation in hippocampal slices. About 3/4 of all terminals in the stratum radiatum CA1 accumulated D-aspartate-immunoreactivity by an active dihydrokainate-sensitive mechanism which was absent in EAAT2 glutamate transporter knockout mice. These terminals were responsible for more than half of all D-aspartate uptake of external substrate in the slices. This is unexpected as EAAT2-immunoreactivity observed in intact brain tissue is mainly associated with astroglia. However, when examining synaptosomes and slice preparations where the extracellular space is larger than in perfusion fixed tissue, it was confirmed that most EAAT2 is in astroglia (about 80%). Neither D-aspartate uptake nor EAAT2 protein was detected in dendritic spines. About 6% of the EAAT2-immunoreactivity was detected in the plasma membrane of synaptic terminals (both within and outside of the synaptic cleft). Most of the remaining immunoreactivity (8%) was found in axons where it was distributed in a plasma membrane surface area several times larger than that of astroglia. This explains why the densities of neuronal EAAT2 are low despite high levels of mRNA in CA3 pyramidal cell bodies, but not why EAAT2 in terminals account for more than half of the uptake of exogenous substrate by hippocampal slice preparations. This and the relative amount of terminal versus glial uptake in the intact brain remain to be discovered. NIH Public Access Author ManuscriptNeuroscience. Author manuscript; available in PMC 2009 November 11. Published in final edited form as:Neuroscience. Glutamate uptake into glia and neurons is essential for controlling the excitatory action of glutamate (for reviews see: Danbolt, 2001;Beart and O'Shea, 2007). It has been much debated whether the uptake activity of glutamatergic nerve terminals represents a major proportion of the total brain tissue uptake activity. The prevailing view is that most brain glutamate uptake is performed by astroglia, because (a) most of the glutamate uptake in forebrain tissue slices and synaptosome preparations is both dihydrokainate sensitive and dependent on the excitatory amino acid transporter (EAAT) 2 (GLT1; slc1a2) gene and protein, and (b) the highest numbers of dihydrokainate sensitive EAAT2 glutamate transporters are found in glial cells (for review see: Danbolt, 2001). This view, however, does not take account of a substantial amount of data showing a significant uptake into glutamatergic nerve terminals (e.g. Beart, 1976; StormMathisen, 1977;Gundersen et al., 1993Gundersen et al., , 1996Suchak et al., 2003;Xu et al., 2003;Waagepetersen et al., 2005; for a detailed discussion about the existence of nerve terminal glutamate up-take, see section 4.2 in Danbolt, 20...

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The Density of EAAC1 (EAAT3) Glutamate Transporters Expressed by Neurons in the Mammalian CNS

Holmseth

et al. 2012

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The extracellular levels of excitatory amino acids are kept low by the action of the glutamate transporters. Glutamate/aspartate transporter (GLAST) and glutamate transporter-1 (GLT-1) are the most abundant subtypes and are essential for the functioning of the mammalian CNS, but the contribution of the EAAC1 subtype in the clearance of synaptic glutamate has remained controversial, because the density of this transporter in different tissues has not been determined. We used purified EAAC1 protein as a standard during immunoblotting to measure the concentration of EAAC1 in different CNS regions. The highest EAAC1 levels were found in the young adult rat hippocampus. Here, the concentration of EAAC1 was ϳ0.013 mg/g tissue (ϳ130 molecules m Ϫ3 ), 100 times lower than that of GLT-1. Unlike GLT-1 expression, which increases in parallel with circuit formation, only minor changes in the concentration of EAAC1 were observed from E18 to adulthood. In hippocampal slices, photolysis of MNI-D-aspartate (4-methoxy-7-nitroindolinyl-D-aspartate) failed to elicit EAAC1-mediated transporter currents in CA1 pyramidal neurons, and D-aspartate uptake was not detected electron microscopically in spines. Using EAAC1 knock-out mice as negative controls to establish antibody specificity, we show that these relatively small amounts of EAAC1 protein are widely distributed in somata and dendrites of all hippocampal neurons. These findings raise new questions about how so few transporters can influence the activation of NMDA receptors at excitatory synapses.

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Synaptotagmin IV determines the linear Ca2+ dependence of vesicle fusion at auditory ribbon synapses

et al. 2009

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Mammalian cochlear inner hair cells (IHCs) are specialized for the dynamic coding of continuous and finely graded sound signals. This ability is largely conferred by the linear Ca(2+) dependence of neurotransmitter release at their synapses, which is also a feature of visual and olfactory systems. The prevailing hypothesis is that linearity in IHCs occurs through a developmental change in the Ca(2+) sensitivity of synaptic vesicle fusion from the nonlinear (high order) Ca(2+) dependence of immature spiking cells. However, the nature of the Ca(2+) sensor(s) of vesicle fusion at hair cell synapses is unknown. We found that synaptotagmin IV was essential for establishing the linear exocytotic Ca(2+) dependence in adult rodent IHCs and immature outer hair cells. Moreover, the expression of the hitherto undetected synaptotagmins I and II correlated with a high-order Ca(2+) dependence in IHCs. We propose that the differential expression of synaptotagmins determines the characteristic Ca(2+) sensitivity of vesicle fusion at hair cell synapses.

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The role of transmembrane channel–like proteins in the operation of hair cell mechanotransducer channels

et al. 2013

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Sound stimuli elicit movement of the stereocilia that make up the hair bundle of cochlear hair cells, putting tension on the tip links connecting the stereocilia and thereby opening mechanotransducer (MT) channels. Tmc1 and Tmc2, two members of the transmembrane channel–like family, are necessary for mechanotransduction. To assess their precise role, we recorded MT currents elicited by hair bundle deflections in mice with null mutations of Tmc1, Tmc2, or both. During the first postnatal week, we observed a normal MT current in hair cells lacking Tmc1 or Tmc2; however, in the absence of both isoforms, we recorded a large MT current that was phase-shifted 180°, being evoked by displacements of the hair bundle away from its tallest edge rather than toward it as in wild-type hair cells. The anomalous MT current in hair cells lacking Tmc1 and Tmc2 was blocked by FM1-43, dihydrostreptomycin, and extracellular Ca2+ at concentrations similar to those that blocked wild type. MT channels in the double knockouts carried Ca2+ with a lower permeability than wild-type or single mutants. The MT current in double knockouts persisted during exposure to submicromolar Ca2+, even though this treatment destroyed the tip links. We conclude that the Tmc isoforms do not themselves constitute the MT channel but are essential for targeting and interaction with the tip link. Changes in the MT conductance and Ca2+ permeability observed in the absence of Tmc1 mutants may stem from loss of interaction with protein partners in the transduction complex.

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David N. Furness

Gene disruption of p27 ^Kip1 allows cell proliferation in the postnatal and adult organ of Corti

A quantitative assessment of glutamate uptake into hippocampal synaptic terminals and astrocytes: New insights into a neuronal role for excitatory amino acid transporter 2 (EAAT2)

The Density of EAAC1 (EAAT3) Glutamate Transporters Expressed by Neurons in the Mammalian CNS

Synaptotagmin IV determines the linear Ca2+ dependence of vesicle fusion at auditory ribbon synapses

The role of transmembrane channel–like proteins in the operation of hair cell mechanotransducer channels

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David N. Furness

Gene disruption of p27 Kip1 allows cell proliferation in the postnatal and adult organ of Corti

A quantitative assessment of glutamate uptake into hippocampal synaptic terminals and astrocytes: New insights into a neuronal role for excitatory amino acid transporter 2 (EAAT2)

The Density of EAAC1 (EAAT3) Glutamate Transporters Expressed by Neurons in the Mammalian CNS

Synaptotagmin IV determines the linear Ca2+ dependence of vesicle fusion at auditory ribbon synapses

The role of transmembrane channel–like proteins in the operation of hair cell mechanotransducer channels

Contact Info

Product

Resources

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Gene disruption of p27 ^Kip1 allows cell proliferation in the postnatal and adult organ of Corti