Mg2+ and memantine block of rat recombinant NMDA receptors containing chimeric NR2A/2D subunits expressed in Xenopus laevis oocytes

N -methyl- d -aspartate receptors (NMDARs) display differences in their sensitivity to the channel blockers Mg²⁺ and memantine that are dependent on the identity of the NR2 subunit present in the receptor–channel complex. This study used two-electrode voltage-clamp recordings from Xenopus laevis oocytes expressing recombinant NMDARs to investigate the actions of Mg²⁺ and memantine at the two NMDARs displaying the largest differences in sensitivity to these blockers, namely NR1/NR2A and NR1/NR2D NMDARs. In addition, NR2A/2D chimeric subunits have been employed to examine the effects of pore-forming elements and ligand-binding domains (LBD) on the potency of the block produced by each of these inhibitors. Our results show that, as previously documented, NR2D-containing NMDARs are less sensitive to voltage-dependent Mg²⁺ block than their NR2A-containing counterparts. The reduced sensitivity is determined by the M1M2M3 membrane-associated regions, as replacing these regions in NR2A subunits with those found in NR2D subunits results in a ∼10-fold reduction in Mg²⁺ potency. Intriguingly, replacing the NR2A LBD with that from NR2D subunits results in a ∼2-fold increase in Mg²⁺ potency. Moreover, when responses mediated by NR1/NR2A NMDARs are evoked by the partial agonist homoquinolinate, rather than glutamate, Mg²⁺ also displays an increased potency. Memantine block of glutamate-evoked currents is most potent at NR1/NR2D NMDARs, but no differences are observed in its ability to inhibit NR2A-containing or NR2A/2D chimeric NMDARs. We suggest that the potency of block of NMDARs by Mg²⁺ is influenced not only by pore-forming regions but also the LBD and the resulting conformational changes that occur following agonist binding.     

Selectivity and interactions of Ba2+ and Cs+ with wild-type and mutant TASK1 K+ channels expressed in Xenopus oocytes

The acid-sensitive K⁺ channel, TASK1 is a member of the K⁺-selective tandem-pore domain (K2P) channel family. Like many of the K2P channels, TASK1 is relatively insensitive to conventional channel blockers such as Ba²⁺. In this paper we report the impact of mutating the pore-neighbouring histidine residues, which are involved in pH sensing, on the sensitivity to blockade by Ba²⁺ and Cs⁺; additionally we compare the selectivity of these channels to extracellular K⁺, Na⁺ and Rb⁺. H98D and H98N mutants showed reduced selectivity for K⁺ over both Na⁺ and Rb⁺, and significant permeation of Rb⁺. This enhanced permeability must reflect changes in the structure or flexibility of the selectivity filter. Blockade by Ba²⁺ and Cs⁺ was voltage-dependent, indicating that both ions block within the pore. In 100 m m K⁺, the K _D at 0 mV for Ba²⁺ was 36 ± 10 m m  ( n = 6)  , whilst for Cs⁺ it was 20 ± 6.0 m m  ( n = 5)  . H98D was more sensitive to Ba²⁺ than the wild-type (WT); in addition, the site at which Ba²⁺ appears to bind was altered (WT: δ, 0.64 ± 0.16, n = 6; H98D: δ, 0.16 ± 0.03, n = 5, statistically different from WT; H98N: δ, 0.58 ± 0.09, not statistically different from WT). Thus, the pore-neighbouring residue H98 contributes not only to the pH sensitivity of TASK1, but also to the structure of the conduction pathway.     

Mg2+ and memantine block of rat recombinant NMDA receptors containing chimeric NR2A/2D subunits expressed in Xenopus laevis oocytes.

N-methyl-d-aspartate receptors (NMDARs) display differences in their sensitivity to the channel blockers Mg(2+) and memantine that are dependent on the identity of the NR2 subunit present in the receptor-channel complex. This study used two-electrode voltage-clamp recordings from Xenopus laevis oocytes expressing recombinant NMDARs to investigate the actions of Mg(2+) and memantine at the two NMDARs displaying the largest differences in sensitivity to these blockers, namely NR1/NR2A and NR1/NR2D NMDARs. In addition, NR2A/2D chimeric subunits have been employed to examine the effects of pore-forming elements and ligand-binding domains (LBD) on the potency of the block produced by each of these inhibitors. Our results show that, as previously documented, NR2D-containing NMDARs are less sensitive to voltage-dependent Mg(2+) block than their NR2A-containing counterparts. The reduced sensitivity is determined by the M1M2M3 membrane-associated regions, as replacing these regions in NR2A subunits with those found in NR2D subunits results in a approximately 10-fold reduction in Mg(2+) potency. Intriguingly, replacing the NR2A LBD with that from NR2D subunits results in a approximately 2-fold increase in Mg(2+) potency. Moreover, when responses mediated by NR1/NR2A NMDARs are evoked by the partial agonist homoquinolinate, rather than glutamate, Mg(2+) also displays an increased potency. Memantine block of glutamate-evoked currents is most potent at NR1/NR2D NMDARs, but no differences are observed in its ability to inhibit NR2A-containing or NR2A/2D chimeric NMDARs. We suggest that the potency of block of NMDARs by Mg(2+) is influenced not only by pore-forming regions but also the LBD and the resulting conformational changes that occur following agonist binding.     

Spatiotemporal patterning of IP3-mediated Ca2+ signals in Xenopus oocytes by Ca2+-binding proteins

Ca²⁺-binding proteins (CaBPs) are expressed in a highly specific manner across many different cell types, yet the physiological basis underlying their selective distribution patterns remains unclear. We used confocal line-scan microscopy together with photo-release of IP₃ in Xenopus oocytes to investigate the actions of mobile cytosolic CaBPs on the spatiotemporal properties of IP₃-evoked Ca²⁺ signals. Parvalbumin (PV), a CaBP with slow Ca²⁺-binding kinetics, shortened the duration of IP₃-evoked Ca²⁺ signals and 'balkanized' global responses into discrete localized events (puffs). In contrast, calretinin (CR), a presumed fast buffer, prolonged Ca²⁺ responses and promoted 'globalization' of spatially uniform Ca²⁺ signals at high [IP₃]. Oocytes loaded with CR or PV showed Ca²⁺ puffs following photolysis flashes that were subthreshold in controls, and the spatiotemporal properties of these localized events were differentially modulated by PV and CR. In comparison to results we previously obtained with exogenous Ca²⁺ buffers, PV closely mimicked the actions of the slow buffer EGTA, whereas CR showed important differences from the fast buffer BAPTA. Most notably, puffs were never observed after loading BAPTA, and this exogenous buffer did not show the marked sensitization of IP₃ action evident with CR. The ability of Ca²⁺ buffers and CaBPs with differing kinetics to fine-tune both global and local intracellular Ca²⁺ signals is likely to have significant physiological implications.     

Kinetics of Mg2+ unblock of NMDA receptors: implications for spike-timing dependent synaptic plasticity

The time course of Mg²⁺ block and unblock of NMDA receptors (NMDARs) determines the extent they are activated by depolarization. Here, we directly measure the rate of NMDAR channel opening in response to depolarizations at different times after brief (1 ms) and sustained (4.6 s) applications of glutamate to nucleated patches from neocortical pyramidal neurons. The kinetics of Mg²⁺ unblock were found to be non-instantaneous and complex, consisting of a prominent fast component (time constant ∼100 μs) and slower components (time constants 4 and ∼300 ms), the relative amplitudes of which depended on the timing of the depolarizing pulse. Fitting a kinetic model to these data indicated that Mg²⁺ not only blocks the NMDAR channel, but reduces both the open probability and affinity for glutamate, while enhancing desensitization. These effects slow the rate of NMDAR channel opening in response to depolarization in a time-dependent manner such that the slower components of Mg²⁺ unblock are enhanced during depolarizations at later times after glutamate application. One physiological consequence of this is that brief depolarizations occurring earlier in time after glutamate application are better able to open NMDAR channels. This finding has important implications for spike-timing-dependent synaptic plasticity (STDP), where the precise (millisecond) timing of action potentials relative to synaptic inputs determines the magnitude and sign of changes in synaptic strength. Indeed, we find that STDP timing curves of NMDAR channel activation elicited by realistic dendritic action potential waveforms are narrower than expected assuming instantaneous Mg²⁺ unblock, indicating that slow Mg²⁺ unblock of NMDAR channels makes the STDP timing window more precise.