Marco Beato

Single-Channel Behavior of Heteromeric α1β Glycine Receptors: An Attempt to Detect a Conformational Change before the Channel Opens

The α1β heteromeric receptors are likely to be the predominant synaptic form of glycine receptors in the adult. Their activation mechanism was investigated by fitting putative mechanisms to single-channel recordings obtained at four glycine concentrations (10-1000 μm) from rat α1β receptors, expressed in human embryonic kidney 293 cells. The adequacy of each mechanism, with its fitted rate constants, was assessed by comparing experimental dwell time distributions, open-shut correlations, and the concentration-open probability (Popen) curve with the predictions of the model. A good description was obtained only if the mechanism had three glycine binding sites, allowed both partially and fully liganded openings, and predicted the presence of open-shut correlations. A strong feature of the data was the appearance of an increase in binding affinity as more glycine molecules bind, before the channel opens. One interpretation of this positive binding cooperativity is that binding sites interact, each site sensing the state of ligation of the others. An alternative, and novel, explanation is that agonist binding stabilizes a higher affinity form of the receptor that is produced by a conformational change (“flip”) that is separate from, and precedes, channel opening. Both the “interaction” scheme and the flip scheme describe our data well, but the latter has fewer free parameters and above all it offers a mechanism for the affinity increase. Distinguishing between the two mechanisms will be important for our understanding of the structural dynamics of activation in the nicotinic superfamily and is important for our understanding of mutations in these receptors.

The Activation Mechanism of α1 Homomeric Glycine Receptors

The glycine receptor mediates fast synaptic inhibition in the spinal cord and brainstem. Its activation mechanism is not known, despite the physiological importance of this receptor and the fact that it can serve as a prototype for other homopentameric channels. We analyzed single-channel recordings from rat recombinant α1 glycine receptors by fitting different mechanisms simultaneously to sets of sequences of openings at four glycine concentrations (10–1000 μm). The adequacy of the mechanism and the rate constants thus fitted was judged by examining how well these described the observed dwell-time distributions, open–shut correlation, and single-channel Popen dose–response curve. We found that gating efficacy increased as more glycine molecules bind to the channel, but maximum efficacy was reached when only three (of five) potential binding sites are occupied. Successive binding steps are not identical, implying that binding sites can interact while the channel is shut. These interactions can be interpreted in the light of the topology of the binding sites within a homopentamer.

Openings of the Rat Recombinant α1 Homomeric Glycine Receptor as a Function of the Number of Agonist Molecules Bound

The functional properties of rat homomeric α1 glycine receptors were investigated using whole-cell and outside-out recording from human embryonic kidney cells transfected with rat α1 subunit cDNA. Whole-cell dose-response curves gave EC 50 estimates between 30 and 120 μM and a Hill slope of ∼3.3. Single channel recordings were obtained by steady-state application of glycine (0.3, 1, or 10 μM) to outside-out patches. Single channel conductances were mostly 60–90 pS, but smaller conductances of ∼40 pS were also seen (10% of the events) with a relative frequency that did not depend on agonist concentration. The time constants of the apparent open time distributions did not vary with agonist concentration, but short events were more frequent at low glycine concentrations. There was also evidence of a previously missed short-lived open state that was more common at lower glycine concentrations. The time constants for the different components of the burst length distributions were found to have similar values at different concentrations. Nevertheless, the mean burst length increased with increasing glycine. This was because the relative area of each burst-length component was concentration dependent and short bursts were favored at lower glycine concentrations. Durations of adjacent open and shut times were found to be strongly (negatively) correlated. Additionally, long bursts were made up of longer than average openings separated by short gaps, whereas short bursts usually consisted of single isolated short openings. The most plausible explanation for these findings is that long bursts are generated when a higher proportion of the five potential agonist binding sites on the receptor is occupied by glycine. On the basis of the concentration dependence and the intraburst structure we provide a preliminary kinetic scheme for the activation of the homomeric glycine receptor, in which any number of glycine molecules from one to five can open the channel, although not with equal efficiency.

Incorporation of the β3 Subunit Has a Dominant-Negative Effect on the Function of Recombinant Central-Type Neuronal Nicotinic Receptors

The β3 neuronal nicotinic subunit is localized in dopaminergic areas of the central nervous system, in which many other neuronal nicotinic subunits are expressed. So far, β3 has only been shown to form functional receptors when expressed together with the α3 and β4 subunits. We have systematically tested in Xenopus laevis oocytes the effects of coexpressing human β3 with every pairwise functional combination of neuronal nicotinic subunits likely to be relevant to the central nervous system. Expression of α7 homomers or α/β pairs (α2, α3, α4, or α6 together with β2 or β4) produced robust nicotinic currents for all combinations, save α6β2 and α6β4. Coexpression of wild-type β3 led to a nearly complete loss of function (measured as maximum current response to acetylcholine) for α7 and for all functional α/β pairs except for α3β4. This effect was also seen in hippocampal neurons in culture, which lost their robust α7-like responses when transfected with β3. The level of surface expression of nicotinic binding sites (α3β4, α4β2, and α7) in tsA201 cells was only marginally affected by β3 expression. Furthermore, the dominant-negative effect of β3 was abolished by a valine-serine mutation in the 9′ position of the second transmembrane domain of β3, a mutation believed to facilitate channel gating. Our results show that incorporation of β3 into neuronal nicotinic receptors other than α3β4 has a powerful dominant-negative effect, probably due to impairment in gating. This raises the possibility of a novel regulatory role for the β3 subunit on neuronal nicotinic signaling in the central nervous system.

Intracellular chloride ions regulate the time course of GABA-mediated inhibitory synaptic transmission.

The time-dependent integration of excitatory and inhibitory synaptic currents is an important process for shaping the input–output profiles of individual excitable cells, and therefore the activity of neuronal networks. Here, we show that the decay time course of GABAergic inhibitory synaptic currents is considerably faster when recorded with physiological internal Cl− concentrations than with symmetrical Cl− solutions. This effect of intracellular Cl− is due to a direct modulation of the GABAA receptor that is independent of the net direction of current flow through the ion channel. As a consequence, the time window during which GABAergic inhibition can counteract coincident excitatory inputs is much shorter, under physiological conditions, than that previously measured using high internal Cl−. This is expected to have implications for neuronal network excitability and neurodevelopment, and for our understanding of pathological conditions, such as epilepsy and chronic pain, where intracellular Cl− concentrations can be altered.

The Time Course of Transmitter at Glycinergic Synapses onto Motoneurons

The concentration of transmitter in the synaptic cleft and its clearance time are one of the main determinants of synaptic strength. We estimated the time course of glycine at rat lumbar motoneurons synapses in spinal cord slices by recording synaptic currents in the presence of a low-affinity competitive antagonist at glycine receptors [2-(3-carboxypropyl)-3-amino-6-(4-methoxyphenyl)pyridazinium (SR-95531)]. Data were analyzed by using the established activation mechanism for glycine receptors and our measurements of SR-95531 binding rates. We show that this technique alone is not sufficient to determine simultaneously the peak concentration of transmitter and its clearance time. However, we found that block of the glial glycine transporter prolongs the glycine transient. This observation puts additional constraints on the range of possible values of the time course of glycine, indicating that glycine reaches a peak concentration of 2.2–3.5 mm and is cleared from the cleft with a time constant of 0.6–0.9 ms.

Human α3β4 Neuronal Nicotinic Receptors Show Different Stoichiometry if They Are Expressed in Xenopus Oocytes or Mammalian HEK293 Cells

Background The neuronal nicotinic receptors that mediate excitatory transmission in autonomic ganglia are thought to be formed mainly by the α3 and β4 subunits. Expressing this composition in oocytes fails to reproduce the properties of ganglionic receptors, which may also incorporate the α5 and/or β2 subunits. We compared the properties of human α3β4 neuronal nicotinic receptors expressed in Human embryonic kidney cells (HEK293) and in Xenopus oocytes, to examine the effect of the expression system and α∶β subunit ratio. Methodology/Principal Findings Two distinct channel forms were observed: these are likely to correspond to different stoichiometries of the receptor, with two or three copies of the α subunit, as reported for α4β2 channels. This interpretation is supported by the pattern of change in acetylcholine (ACh) sensitivity observed when a hydrophilic Leu to Thr mutation was inserted in position 9′ of the second transmembrane domain, as the effect of mutating the more abundant subunit is greater. Unlike α4β2 channels, for α3β4 receptors the putative two-α form is the predominant one in oocytes (at 1∶1 α∶β cRNA ratio). This two-α form has a slightly higher ACh sensitivity (about 3-fold in oocytes), and displays potentiation by zinc. The putative three-α form is the predominant one in HEK cells transfected with a 1∶1 α∶β DNA ratio or in oocytes at 9∶1 α∶β RNA ratio, and is more sensitive to dimethylphenylpiperazinium (DMPP) than to ACh. In outside-out single-channel recordings, the putative two-α form opened to distinctive long bursts (100 ms or more) with low conductance (26 pS), whereas the three-α form gave rise to short bursts (14 ms) of high conductance (39 pS). Conclusions/Significance Like other neuronal nicotinic receptors, the α3β4 receptor can exist in two different stoichiometries, depending on whether it is expressed in oocytes or in mammalian cell lines and on the ratio of subunits transfected.

Determining the Neurotransmitter Concentration Profile at Active Synapses

Establishing the temporal and concentration profiles of neurotransmitters during synaptic release is an essential step towards understanding the basic properties of inter-neuronal communication in the central nervous system. A variety of ingenious attempts has been made to gain insights into this process, but the general inaccessibility of central synapses, intrinsic limitations of the techniques used, and natural variety of different synaptic environments have hindered a comprehensive description of this fundamental phenomenon. Here, we describe a number of experimental and theoretical findings that has been instrumental for advancing our knowledge of various features of neurotransmitter release, as well as newly developed tools that could overcome some limits of traditional pharmacological approaches and bring new impetus to the description of the complex mechanisms of synaptic transmission.

Molecular determinants of glycine receptor αβ subunit sensitivities to Zn2+‐mediated inhibition

Glycine receptors exhibit a biphasic sensitivity profile in response to Zn2+‐mediated modulation, with low Zn2+ concentrations potentiating (< 10 μm), and higher Zn2+ concentrations inhibiting submaximal responses to glycine. Here, a substantial 30‐fold increase in sensitivity to Zn2+‐mediated inhibition was apparent for the homomeric glycine receptor (GlyR) α1 subunit compared to either GlyR α2 or α3 subtypes. Swapping the divergent histidine (H107) residue in GlyR α1, which together with the conserved H109 forms part of an intersubunit Zn2+‐binding site, for the equivalent asparagine residue present in GlyR α2 and α3, reversed this phenotype. Co‐expression of heteromeric GlyR α1 or α2 with the ancillary β subunit yielded receptors that maintained their distinctive sensitivities to Zn2+ inhibition. However, GlyR α2β heteromers were consistently 2‐fold more sensitive to inhibition compared to the GlyR α2 homomer. Comparative studies to elucidate the specific residue in the β subunit responsible for this differential sensitivity revealed instead threonine 133 in the α1 subunit as a new vital component for Zn2+‐mediated inhibition. Further studies on heteromeric receptors demonstrated that a mutated β subunit could indeed affect Zn2+‐mediated inhibition but only from one side of the intersubunit Zn2+‐binding site, equivalent to the GlyR α1 H107 face. This strongly suggests that the α subunit is responsible for Zn2+‐mediated inhibition and that this is effectively transduced, asymmetrically, from the side of the Zn2+‐binding site where H109 and T133 are located.

High Intracellular Chloride Slows the Decay of Glycinergic Currents

The time course of currents mediated by native and recombinant glycine receptors was examined with a combination of rapid agonist applications to outside-out patches and single-channel recording. The deactivation time constant of currents evoked by brief, saturating pulses of glycine is profoundly affected by the chloride concentration on the intracellular side of the cell membrane. Deactivation was threefold slower when intracellular chloride was increased from a low level (10 mm), similar to that observed in living mature neurons, to 131 mm (“symmetrical” chloride, often used in pipette internal solutions). Single-channel analysis revealed that high chloride has its greatest effect on the channel closing rate, slowing it by a factor of 2 compared with the value we estimated in the cell-attached mode (in which the channels are at physiological intracellular chloride concentrations). The same effect of chloride was observed when glycinergic evoked synaptic currents were recorded from juvenile rat spinal motoneurons in vitro, because the decay time constant was reduced from ∼7 ms to ∼3 ms when cells were dialyzed with 10 mm chloride intracellular recording solution. Our results indicate that the time course of glycinergic synaptic inhibition in intact neurons is much faster than is estimated by measurements in symmetrical chloride and can be modulated by changes in intracellular chloride concentration in the range that can occur in physiological or pathological conditions.