Christopher N. Connolly

Adjacent phosphorylation sites on GABA A receptor β subunitsdetermine regulation by cAMP-dependent protein kinase

Activation of cAMP-dependent protein kinase (PKA) can enhance or reduce the function of neuronal GABAA receptors, the major sites of fast synaptic inhibition in the brain. This differential regulation depends on PKA-induced phosphorylation of adjacent conserved sites in the receptor β subunits. Phosphorylation of β3 subunit-containing receptors at S408 and S409 enhanced the GABA-activated response, whereas selectively mutating S408 to alanine converted the potentiation into an inhibition, comparable to that of β1 subunits, which are phosphorylated solely on S409. These distinct modes of regulation were interconvertible between β1 and β3 subunits and depended upon the presence of S408 in either subunit. In contrast, β2 subunit-containing receptors were not phosphorylated or affected by PKA. Differential regulation by PKA of postsynaptic GABAA receptors containing different β subunits may have profound effects on neuronal excitability.

Cell surface stability of gamma-aminobutyric acid type A receptors. Dependence on protein kinase C activity and subunit composition.

Type A γ-aminobutyric acid receptors (GABAA), the major sites of fast synaptic inhibition in the brain, are believed to be composed predominantly of α, β, and γ subunits. Although cell surface expression is essential for GABAA receptor function, little is known regarding its regulation. To address this issue, the membrane stability of recombinant α1β2 or α1β2γ2 receptors was analyzed in human embryonic kidney cells. α1β2γ2 but not α1β2 receptors were found to recycle constitutively between the cell surface and a microtubule-dependent, perinuclear endosomal compartment. Similar GABAA receptor endocytosis was also seen in cultured hippocampal and cortical neurons. GABAA receptor surface levels were reduced upon protein kinase C (PKC) activation. Like basal endocytosis, this response required the γ2subunit but not receptor phosphorylation. Although inhibiting PKC activity did not block α1β2γ2receptor endocytosis, it did prevent receptor down-regulation, suggesting that PKC activity may block α1β2γ2 receptor recycling to the cell surface. In agreement with this observation, blocking recycling from endosomes with wortmannin selectively reduced surface levels of γ2-containing receptors. Together, our results demonstrate that the surface stability of GABAA receptors can be dynamically and specifically regulated, enabling neurons to modulate cell surface receptor number upon the appropriate cues.

The Cys-loop superfamily of ligand-gated ion channels: the impact of receptor structure on function.

The Cys-loop receptors constitute an important superfamily of LGICs (ligand-gated ion channels) comprising receptors for acetylcholine, 5-HT3 (5-hydroxytryptamine; 5-HT3 receptors), glycine and GABA (gamma-aminobutyric acid; GABAA receptors). A vast knowledge of the structure of the Cys-loop superfamily and its impact on channel function have been accrued over the last few years, leading to exciting new proposals on how ion channels open and close in response to agonist binding. Channel opening is initiated by the extracellular association of agonists to discrete binding pockets, leading to dramatic conformational changes, culminating in the opening of a central ion pore. The importance of channel structure is exemplified in the allosteric modulation of channel function by the binding of other molecules to distinct sites on the channel, which exerts an additional level of control on their function. The subsequent conformational changes (gating) lead to channel opening and ion transport. Following channel pore opening, ion selectivity is determined by receptor structure in, and around, the ion pore. As a final level of control, cytoplasmic determinants control the magnitude (conductance) of ion flow into the cell. Thus the Cys-loop receptors are complex molecular motors, with moving parts, which can transduce extracellular signals across the plasma membrane. Once the full mechanical motions involved are understood, it may be possible to design sophisticated therapeutic agents to modulate their activity, or at least be able to throw a molecular spanner into the works!

Leptin promotes rapid dynamic changes in hippocampal dendritic morphology

Recent studies have implicated the hormone leptin in synaptic plasticity associated with neuronal development and learning and memory. Indeed, leptin facilitates hippocampal long-term potentiation and leptin-insensitive rodents display impaired hippocampal synaptic plasticity suggesting a role for endogenous leptin. Structural changes are also thought to underlie activity-dependent synaptic plasticity and this may be regulated by specific growth factors. As leptin is reported to have neurotrophic actions, we have examined the effects of leptin on the morphology and filopodial outgrowth in hippocampal neurons. Here, we demonstrate that leptin rapidly enhances the motility and density of dendritic filopodia and subsequently increases the density of hippocampal synapses. This process is dependent on the synaptic activation of NR2A-containing NMDA receptors and is mediated by the MAPK (ERK) signaling pathway. As dendritic morphogenesis is associated with activity-dependent changes in synaptic strength, the rapid structural remodeling of dendrites by leptin has important implications for its role in regulating hippocampal synaptic plasticity and neuronal development.

Cholinergic pesticides cause mushroom body neuronal inactivation in honeybees

Pesticides that target cholinergic neurotransmission are highly effective, but their use has been implicated in insect pollinator population decline. Honeybees are exposed to two widely used classes of cholinergic pesticide: neonicotinoids (nicotinic receptor agonists) and organophosphate miticides (acetylcholinesterase inhibitors). Although sublethal levels of neonicotinoids are known to disrupt honeybee learning and behaviour, the neurophysiological basis of these effects has not been shown. Here, using recordings from mushroom body Kenyon cells in acutely isolated honeybee brain, we show that the neonicotinoids imidacloprid and clothianidin, and the organophosphate miticide coumaphos oxon, cause a depolarization-block of neuronal firing and inhibit nicotinic responses. These effects are observed at concentrations that are encountered by foraging honeybees and within the hive, and are additive with combined application. Our findings demonstrate a neuronal mechanism that may account for the cognitive impairments caused by neonicotinoids, and predict that exposure to multiple pesticides that target cholinergic signalling will cause enhanced toxicity to pollinators.

Proton sensitivity of the GABA(A) receptor is associated with the receptor subunit composition.

1. Modulation of GABA(A) receptors by external H(+) was examined in cultured rat sympathetic neurones, and in Xenopus laevis oocytes and human embryonic kidney (HEK) cells expressing recombinant GABA(A) receptors composed of combinations of alpha 1, beta 1, beta 2, gamma 2S and delta subunits. 2. Changing the external pH from 7.4 reduced GABA‐activated currents in sympathetic neurones. pH titration of the GABA‐induced current was fitted with a pH model which predicted that H(+) interact with two sites (PK(a) values of 6.4 and 7.2). 3. For alpha 1 beta 1 GABA(A) receptors, low external pH (< 7.4) enhanced responses to GABA. pH titration predicted the existence of two sites with PK(a) values of 6.6 and 7.5. The GABA concentration‐response curve was shifted to the left by low pH and non‐competitively inhibited at high pH (> 7.4). 4. alpha 1 beta 1 gamma 2S receptor constructs were not affected by external pH, whereas exchanging the beta 1 subunit for beta 2 conferred a sensitivity to pH, with predicted PK(a) values of 5.16 and 9.44. 5. Low pH enhanced the responses to GABA on alpha 1 beta 1 delta subunits, whilst high pH caused an inhibition (PK(a) values of 6.6 and 9.9). The GABA concentration‐response curves were enhanced (pH 5.4) or reduced (pH 9.4) with no changes in the GABA EC(50). 6. Immunoprecipitation with subunit and epitope‐specific antisera to alpha 1, beta 1 and delta subunits demonstrated that these subunits could co‐assemble in cell membranes. 7. Expression of alpha 1 beta 1 gamma 2S delta constructs resulted in a ‘bell‐shaped’ pH titration relationship. Increasing or decreasing external pH inhibited the responses to GABA. 8. The pH sensitivity of recombinant GABA(A) receptors expressed in HEK cells was generally in accordance with data accrued from Xenopus oocytes. However, rapid application of GABA to alpha 1 beta 1 constructs at high pH (> 7.4) caused an increased peak and reduced steady‐state current, with a correspondingly increased rate of desensitization. 9. Modulation of GABA(A) receptor function was apparently unaffected by the internal pH. Moreover, pH values between 5 and 9.5 did not significantly affect the charge distribution on the zwitterionic GABA molecules. 10. In conclusion, this study demonstrates that external pH can either enhance, have little effect, or reduce GABA‐activated responses, and this is apparently dependent on the receptor subunit composition. The potential importance of H(+) sensitivity of GABA(A) receptors is discussed.

Dendritic and mitochondrial changes during glutamate excitotoxicity.

Glutamate is the predominant excitatory neurotransmitter in the mammalian central nervous system (CNS) and is normally stored intracellularly. However, in instances of CNS injury or disease, increased concentrations of extracellular glutamate can result in the over-activation of ionotropic glutamate receptors and trigger neuronal cell death (termed excitotoxicity). Two early hallmarks of such neuronal toxicity are mitochondrial dysfunction (depolarisation, decreased ATP synthesis, structural collapse and potential opening of the permeability transition pore) and the formation of focal swellings (also termed varicosities/beads) along the length of the dendrites. In this review, we summarise current knowledge of the mechanisms that underlie these early excitotoxic events as well as the mechanisms that facilitate dendritic recovery following termination of the excitotoxic insult.

Mitochondrial dysfunction and dendritic beading during neuronal toxicity

Mitochondrial dysfunction (depolarization and structural collapse), cytosolic ATP depletion, and neuritic beading are early hallmarks of neuronal toxicity induced in a variety of pathological conditions. We show that, following global exposure to glutamate, mitochondrial changes are spatially and temporally coincident with dendritic bead formation. During oxygen-glucose deprivation, mitochondrial depolarization precedes mitochondrial collapse, which in turn is followed by dendritic beading. These events travel as a wave of activity from distal dendrites toward the neuronal cell body. Despite the spatiotemporal relationship between dysfunctional mitochondria and dendritic beads, mitochondrial depolarization and cytoplasmic ATP depletion do not trigger these events. However, mitochondrial dysfunction increases neuronal vulnerability to these morphological changes during normal physiological activity. Our findings support a mechanism whereby, during glutamate excitotoxicity, Ca2+ influx leads to mitochondrial depolarization, whereas Na+ influx leads to an unsustainable increase in ATP demand (Na+,K+-ATPase activity). This leads to a drop in ATP levels, an accumulation of intracellular Na+ ions, and the subsequent influx of water, leading to microtubule depolymerization, mitochondrial collapse, and dendritic beading. Following the removal of a glutamate challenge, dendritic recovery is dependent upon the integrity of the mitochondrial membrane potential, but not on a resumption of ATP synthesis or Na+,K+-ATPase activity. Thus, dendritic recovery is not a passive reversal of the events that induce dendritic beading. These findings suggest that the degree of calcium influx and mitochondrial depolarization inflicted by a neurotoxic challenge, determines the ability of the neuron to recover its normal morphology.

Modulation of neuronal and recombinant GABAA receptors by redox reagents

1 The functional role played by the postulated disulphide bridge in γ‐aminobutyric acid type A (GABAA) receptors and its susceptibility to oxidation and reduction were studied using recombinant (murine receptor subunits expressed in human embryonic kidney cells) and rat neuronal GABAA receptors in conjunction with whole‐cell and single channel patch‐clamp techniques. 2 The reducing agent dithiothreitol (DTT) reversibly potentiated GABA‐activated responses (IGABA) of α1β1 or α1β2 receptors while the oxidizing reagent 5,5′‐dithio‐bis‐(2‐nitrobenzoic acid) (DTNB) caused inhibition. Redox modulation of IGABA was independent of GABA concentration, membrane potential and the receptor agonist and did not affect the GABA EC50 or Hill coefficient. The endogenous antioxidant reduced glutathione (GSH) also potentiated IGABA in α1β2 receptors, while both the oxidized form of DTT and glutathione (GSSG) caused small inhibitory effects. 3 Recombinant receptors composed of α1β1γ2S or α1β2γ2S were considerably less sensitive to DTT and DTNB. 4 For neuronal GABAA receptors, IGABA was enhanced by flurazepam and relatively unaffected by redox reagents. However, in cultured sympathetic neurones, nicotinic acetylcholine‐activated responses were inhibited by DTT whilst in cerebellar granule neurones, NMDA‐activated currents were potentiated by DTT and inhibited by DTNB. 5 Single GABA‐activated ion channel currents exhibited a conductance of 16 pS for α1β1 constructs. DTT did not affect the conductance or individual open time constants determined from dwell time histograms, but increased the mean open time by affecting the channel open probability without increasing the number of cell surface receptors. 6 A kinetic model of the effects of DTT and DTNB suggested that the receptor existed in equilibrium between oxidized and reduced forms. DTT increased the rate of entry into reduced receptor forms and also into desensitized states. DTNB reversed these kinetic effects. 7 Our results indicate that GABAA receptors formed by α and β subunits are susceptible to regulation by redox agents. Inclusion of the γ2 subunit in the receptor, or recording from some neuronal GABAA receptors, resulted in reduced sensitivity to DTT and DTNB. Given the suggested existence of αβ subunit complexes in some areas of the central nervous system together with the generation and release of endogenous redox compounds, native GABAA receptors may be subject to regulation by redox mechanisms.

Leptin regulates AMPA receptor trafficking via PTEN inhibition

The hormone leptin can cross the blood–brain barrier and influences numerous brain functions (Harvey, 2007). Indeed, recent studies have demonstrated that leptin regulates activity-dependent synaptic plasticity in the CA1 region of the hippocampus (Shanley et al., 2001; Li et al., 2002; Durakoglugil et al., 2005; Moult et al., 2009). It is well documented that trafficking of AMPA receptors is pivotal for hippocampal synaptic plasticity (Collingridge et al., 2004), but there is limited knowledge of how hormonal systems like leptin influence this process. In this study we have examined how leptin influences AMPA receptor trafficking and in turn how this impacts on excitatory synaptic function. Here we show that leptin preferentially increases the cell surface expression of GluR1 and the synaptic density of GluR2-lacking AMPA receptors in adult hippocampal slices. The leptin-induced increase in surface GluR1 required NMDA receptor activation and was associated with an increase in cytoplasmic PtdIns(3,4,5)P3 levels. In addition, leptin enhanced phosphorylation of the lipid phosphatase PTEN which inhibits PTEN function and elevates PtdIns(3,4,5)P3 levels. Moreover, inhibition of PTEN mimicked and occluded the effects of leptin on GluR1 trafficking and excitatory synaptic strength. These data indicate that leptin, via a novel pathway involving PTEN inhibition, promotes GluR1 trafficking to hippocampal synapses. This process has important implications for the role of leptin in hippocampal synaptic function in health and disease.