Functional reconstitution of the glycine receptor

Functional reconstitution and characterization of recombinant human alpha 1-glycine receptors

By utilizing a baculoviral expression system described previously (Cascio, M., Schoppa, N. E., Grodzicki, R. L., Sigworth, F. J., and Fox, R. O. (1993) J. Biol. Chem. 268, 22135-22142), functional recombinant homomeric human alpha(1)-glycine receptors (GlyR) were overexpressed in insect cell culture, solubilized, purified, and reconstituted into lipid vesicles via gel filtration. Reconstituted GlyR channels were observed to retain native-like activity in single channel recordings of planar bilayers and in flux assays of small unilamellar vesicles, providing evidence that the recombinant homomeric receptor may be functionally reconstituted. This reconstitution is significant in that it indicates that the overexpressed homomeric receptor is an appropriate substrate for subsequent biophysical characterization aimed at the general elucidation of structure-function. Circular dichroism spectroscopy of reconstituted GlyR indicated a low alpha-helical content and a significant fraction of polyproline structure. The small fraction of observed alpha-helix is insufficient to accommodate the four helical transmembrane domains proposed in models for this receptor. By inference, other members of the homologous ligand-gated channel superfamily, which include the ionotropic gamma-aminobutyric acid, acetylcholine, and serotonin receptors, may also be erroneously modeled, and alternate models should be considered.

Hamster sperm glycine receptor: evidence for its presence and involvement in the acrosome reaction

Recent reports have provided evidence for the presence of amino acid neurotransmitter receptor/chloride channels in human and porcine spermatozoa and their involvement in the acrosome reaction (AR). In this work we investigated whether a glycine receptor (GlyR) was present in golden hamster sperm, and whether it had a role in the hamster AR. The neuronal GlyR agonist glycine, stimulated in a dose-dependent manner, the AR of hamster spermatozoa previously capacitated for at least 3 hr. This stimulation was completely inhibited by 50 microM (+)-bicuculline and by concentrations of strychnine as low as 10-50 nM; both agents are antagonists of neuronal GlyR when used at the concentrations reported in this study. beta-Alanine, another agonist of the neuronal GlyR, also stimulated the AR. The AR-stimulatory effect of this compound was completely abolished by 50 nM strychnine. The inhibitory effect of strychnine on the glycine-induced hamster sperm AR was completely overcome by subsequent treatment with the calcium ionophore ionomycin, demonstrating that the strychnine effect was specific for GlyR. Additional binding studies with (3)[H]-strychnine, the typical radioligand used to detect GlyR in several cells, demonstrated for the first time the presence of specific binding sites for strychnine in the hamster spermatozoa. Interestingly, binding increased during in vitro capacitation, particularly in those sperm suspensions showing high percentages of AR. Taken together these results strongly suggest the presence of a GlyR in the hamster spermatozoa, with a role in the AR when activated.

Biology of the postsynaptic glycine receptor

Glycine is one of the major inhibitory neurotransmitters, and upon binding to its receptor it activates chloride conductances. Receptors are accumulated immediately opposite release sites, at the postsynaptic differentiations, where they form functional microdomains. This review describes recent advances in our understanding of the structure-function relationships of the glycine receptor, a member of the ligand-gated ion channel superfamily. Following purification of the receptor complex and identification of its integral and peripheral membrane protein components, molecular cloning has revealed the existence of several subtypes of the ligand-binding subunit. This heterogeneity is responsible for the distinct pharmacological and functional properties displayed by the various receptor configurations that are differentially expressed and assembled during development. This review also focuses on the molecular aspects of glycinergic synaptogenesis, highlighting gephyrin, the peripheral component of the receptor. The role of this cytoplasmic protein in anchoring and maintaining the channel complex in postsynaptic clusters is discussed. The glycine receptor recently moved into the spotlight as a paradigm in the approach to cell biology of the formation of the postsynaptic membrane.

Solubilization, partial purification and functional reconstitution of a sheep brain endoplasmic reticulum anion channel

1. An intracellular anion channel, known to be co-localized in brain endoplasmic reticulum membranes with ryanodine-sensitive calcium-release channels, was incorporated into voltage-clamped planar lipid bilayers from sheep brain microsomal membrane vesicles. 2. Single channels, which displayed a main open-state conductance of 80-100 pS in symmetric 450 mM choline Cl, reduced to approximately 20 pS in symmetric 225 mM (choline)2SO4 (the solutions also contained 10 mM Tris-HCl, pH 7.4), discriminated poorly between Cl- and choline+ (relative permeability ratio, PCl-/Pcholine+, 2.5). 3. Sheep brain microsomal membrane proteins were solubilized in the zwitterionic detergent CHAPS, and subjected to sequential anion-exchange and size-exclusion chromatography; the solubilizate, and partially-purified protein fractions, were then incorporated into large unilamellar liposomes by freeze-thaw sonication. 4. Reconstituted passive anion (Cl-)-transport, which was reduced by approximately 60% in the presence of SO4(2-), was assayed by measuring the efflux of entrapped 36Cl- (compared to the efflux of [3H]inulin), and also by monitoring the fluorescence quenching of entrapped SPQ by Cl(-)-influx. 5. Cl(-)-transporting activity was enriched up to 200-fold after two stages of purification, and the partially-purified channel protein was incorporated from reconstituted proteoliposomes into planar lipid bilayers, where its permeation behaviour remained very similar to that observed for the native channel.

Molecular physiology of anion channels

Anion channels have diverse functions, ranging from regulation of cell volume to transepithelial transport and control of excitability. Three well established structural classes of plasma membrane chloride channels now exist: the ligand-gated chloride channels, the cAMP-stimulated cystic fibrosis transmembrane conductance regulator channel, and the voltage-gated (or swelling-activated) members of the CLC chloride channel family. Genetic defects leading to inherited disease are known for each of these classes. A combination of mutagenesis and biophysical analysis has been used to correlate their structure with function. Recently, the role of several molecules has been questioned; rather than being chloride channels themselves, they may be activators of endogenous channels in the cells used for expression.

Structure and function of inhibitory glycine receptors

Ion transport by peptide channels has been the major theme in the work of the late P. Läuger. His theoretical and experimental approaches provided the basis for a deeper understanding of pore-mediated ion permeation through biological membranes. This review on a ligand–gated ion channel protein from the mammalian brain is dedicated to the memory of this outstanding scientist.

Glycinergic ligands modulate the rate of phosphorylation of the glycine receptor by protein kinase C

The alpha subunit of the glycine receptor purified from rat spinal cord is rapidly and specifically phosphorylated by protein kinase C (Ruiz-Gómez et al., (1991) J. Biol. Chem. 266, 559-566). We report here that the rate of phosphorylation of the glycine receptor by this kinase is higher in the presence of agonists (glycine, beta-alanine) than in the presence of antagonists (strychnine, RU-5135). These results suggest that activated glycine receptors would be a preferential target for functional regulation through phosphorylation mechanisms.

Intestinal absorption of beta-lactam antibiotics and oligopeptides. Functional and stereospecific reconstitution of the oligopeptide transport system from rabbit small intestine

The H(+)-dependent uptake system responsible for the enteral absorption of oligopeptides and orally active beta-lactam antibiotics was functionally reconstituted into liposomes. Membrane proteins from rabbit small intestinal brush border membrane vesicles were solubilized with n-octyl glucoside and incorporated into liposomes using a gel filtration method. At protein/lipid ratios of 1:10 and 1:40, the uptake of the orally active alpha-amino-cephalosporin, D-cephalexin into proteoliposomes was stimulated by an inwardly directed H+ gradient and was protein-dependent. In these proteoliposomes the binding protein for oligopeptides and beta-lactam antibiotics of Mr 127,000 could be labeled by direct photoaffinity labeling with [3H]benzylpenicillin revealing an identical binding specificity as in the original brush border membrane vesicles. The uptake system for beta-lactam antibiotics and oligopeptides showed a remarkable stereospecificity; only D-cephalexin was taken up by intact brush border membrane vesicles, whereas the L-enantiomer was not taken up to a significant extent. This stereospecificity for uptake was also seen after reconstitution of solubilized brush border membrane proteins into liposomes demonstrating a functional reconstitution of the peptide transporter. Both enantiomers however, bound to the 127-kDa binding protein as was shown by a decrease in the extent of photoaffinity labeling of the 127-kDa protein in the presence of both enantiomers. After reconstitution of subfractions of brush border membrane proteins obtained by wheat germ lectin affinity chromatography into proteoliposomes, only liposomes containing the 127-kDa binding protein showed a significant uptake of D-cephalexin whereas the L-enantiomer was not transported. The uptake rates for D-cephalexin into proteoliposomes correlated with the content of 127-kDa binding protein in these liposomes as was determined by specific photoaffinity labeling with [3H]benzylpenicillin. The purified 127-kDa binding protein was also reconstituted into liposomes and its ability for specific binding of substrates as well as stereospecific uptake of cephalexin could be restored. These results indicate that the binding protein for oligopeptides and beta-lactam antibiotics of Mr 127,000 mediates the stereospecific and H(+)-dependent transport of orally active beta-lactam antibiotics across the enterocyte brush border membrane. We therefore suggest that this 127-kDa binding protein is the intestinal peptide transport system (or a component thereof).

Sensitive procedures for measuring chloride fluxes mediated by the purified glycine receptor incorporated into phospholipid vesicles

Two novel methods have been developed to directly measure chloride influx into purified glycine receptor-containing phospholipid vesicles. Using a method based on the fluorescence quenching of a chloride-sensitive probe entrapped into the vesicles, a chloride influx was detected which could be enhanced by glycine and completely abolished by the antagonist strychnine. In addition, by tracing the 36Cl- influx into the proteoliposomes, a stimulatory effect of both glycine and beta-alanine could be seen, which can be inhibited by strychnine and other glycine antagonists. These data, together with a previous report demonstrating ligand-mediated iodide fluxes in the same preparation (Biochemistry, 28 (1989) 6405-6409), clearly demonstrate the utility of the reconstituted receptor preparation to investigate some ion channel and pharmacological properties of the glycine receptor.

Cell-permeable fluorescent indicator for cytosolic chloride

A major limitation of quinolinium-based fluorescent indicators for cytosolic Cl- has been the necessity of invasive cell loading because the positively charged ring nitrogen confers high polarity and membrane impermeability. A novel approach to mask the positive nitrogen was developed and evaluated for rapid, noninvasive indicator loading into living cells and effective intracellular trapping. The nonpolar and lipophilic compound 6-methoxy-N-ethyl-1,2-dihydroquinoline (diH-MEQ) was Cl- insensitive but was readily oxidized to the membrane-impermeable and Cl(-)-sensitive fluorescent indicator 6-methoxy-N-ethylquinolium chloride (MEQ), MEQ had 344-nm absorbance and 440-nm emission maxima, 0.70 quantum yield, and 4100 M-1 cm-1 molar extinction coefficient. In aqueous buffers, the fluorescence of MEQ was quenched by Cl- by a collisional mechanism with a Stern-Volmer constant (KCl) of 145 M-1. MEQ fluorescence was quenched by other anions (KBr = 275 M-1, KI = 360 M-1, KSCN = 300 M-1) but not by NO3-, SO4(2-), cations, and pH. Swiss 3T3 fibroblasts and colonic T84 cells were loaded with MEQ by incubation at 37 degrees C with 25-50 microM diH-MEQ for 5-10 min followed by diH-MEQ-free buffer for 15 min. MEQ stained cells brightly and uniformly and was nontoxic in studies of cell growth, cAMP and Ca2+ signaling, and electrophysiological properties. MEQ leaked out of cells by less than 10% in 60 min and was sensitive to cytosolic Cl- with KCl = 19 M-1.(ABSTRACT TRUNCATED AT 250 WORDS)

Sulfhydryl groups modulate the allosteric interaction between glycine binding sites at the inhibitory glycine receptor

We have investigated the effect of chemical reagents that modify sulfhydryl groups on the ligand binding properties of the glycine receptor (GlyR). The Hill coefficient (nH) for the displacement of [3H]strychnine binding by glycine was increased from approximately 0.8 to values significantly above 1 (approximately 1.2-1.4) in membranes pretreated with the disulfide-reducing agent dithiothreitol or glutathione. However, the affinity of strychnine or glycine for the GlyR was not affected by these treatments. This indicates that several glycine binding sites interact cooperatively for displacing bound strychnine under such experimental circumstances. A similar increase in the nH for glycine has been observed when the temperature of the binding assay was increased to 37 degrees C. Combination of dithiothreitol pretreatment and increased binding temperature led to nH variations similar to those observed with either of these treatments alone, a finding suggesting that their mechanisms of action are not independent. Conversely, modification of rat spinal cord membranes or of purified and reconstituted GlyR preparations with the sulfhydryl-alkylating agent N-ethylmaleimide or fluorescein-maleimide decreased nH values to approximately 0.5, without affecting glycine or strychnine affinities. This effect may be caused by an increased heterogeneity of GlyR populations. It is interesting that occupancy of the receptor by glycine or beta-alanine (but not by antagonists) specifically protects from the effects of the different sulfhydryl reagents. Moreover, the presence of some of the Eccles' anions, i.e., anions that permeate through the channels associated with GlyRs and gamma-aminobutyric acidA receptors, seems to be required for the action of both dithiothreitol and N-ethylmaleimide.(ABSTRACT TRUNCATED AT 250 WORDS)

Agonist binding to purified glycine receptor reconstituted into giant liposomes elicits two types of chloride currents

Using 'inside-out' membrane patches obtained from reconstituted giant liposomes containing purified glycine receptor from rat spinal cord, we have detected chloride currents elicited in response to the presence of the agonists glycine or beta-alanine. Regardless of the agonist employed, two different patterns of single channel currents could be detected, which differ in their main conductance, complexity of substates and opening frequency. In agreement with the expectations of glycine receptor heterogeneity suggested recently at the mRNA and cDNA level, our results indicate the existence of functionally different glycine receptors in the adult rat spinal cord.

The inhibitory glycine receptor: a ligand-gated chloride channel of the central nervous system

The postsynaptic glycine receptor (GlyR) is a major inhibitory chloride channel protein in the central nervous system. The affinity-purified receptor contains polypeptides of 48 kDa, 58 kDa, and 93 kDa. The 48-kDa (alpha) and 58 kDa (beta) subunits span the postsynaptic membrane in a pentameric arrangement to form the anion channel of the receptor. The 93-kDa polypeptide is cytoplasmically localized and may have an anchoring function. Molecular cloning revealed that different structural characteristics are shared by the membrane-spanning subunits of the GlyR and those of other ligand-gated ion channel proteins. Developmental regulation of the GlyR is characterized by alterations in antagonist binding, heterogeneity of alpha subunits, and increased levels of the 93-kDa polypeptide. Glycine receptor function can be reconstituted by expression of cloned alpha subunits in heterologous cell systems. Positive charges found at the presumed mouths of the GlyR channel appear to be important determinants of ion selectivity. These data establish the anion-conducting GlyR as a homolog of other ligand-gated ion channel proteins and suggest that the diversity of these channels originates from divergent evolution of a primordial channel protein early in phylogeny.

Development and biological applications of chloride-sensitive fluorescent indicators

Chloride movement across cell plasma and internal membranes, is of central importance for regulation of cell volume and pH, vectorial salt movement in epithelia, and, probably, intracellular traffic. Quinolinium-based chloride-sensitive fluorescent indicators provide a new approach to study chloride transport mechanisms and regulation that is complementary to 36Cl tracer methods, intracellular microelectrodes, and patch clamp. Indicator fluorescence is quenched by chloride by a collisional mechanism with Stern-Volmer constants of up to 220 M-1. Fluorescence is quenched selectively by chloride in physiological systems and responds to changes in chloride concentration in under 1 ms. The indicators are nontoxic and can be loaded into living cells for continuous measurement of intracellular chloride concentration by single-cell fluorescence microscopy. In this review, the structure-activity relationships for chloride-sensitive fluorescent indicators are described. Methodology for measurement of chloride transport in isolated vesicle and liposome systems and in intact cells is evaluated critically by use of examples from epithelial cell physiology. Future directions for synthesis of tailored chloride-sensitive indicators and new applications of indicators for studies of transport regulation and intracellular ion gradients are proposed.