Evidence of inter- and intra-subunit alcohol and anesthetic binding cavities in the glycine receptor

McCracken, Mandy Leigh

06 November 2014

Alcohol is abundantly consumed by society and general anesthetics are used everyday in operating suites throughout the world, yet the sites and mechanisms of action for these drugs are not completely understood. Glycine receptors (GlyRs) are pentameric ion channels expressed throughout the brain and spinal cord and have become increasingly popular targets in the study of alcohol action. Each GlyR subunit is composed of four alpha helical transmembrane segments (TM1-4), and although amino acids involved with alcohol action have been previously identified in TM1-4, the orientation of each of these residues with respect to a putative alcohol/anesthetic binding cavity remains controversial. In order to better characterize this binding cavity within the GlyR, we conducted a series of experiments using cysteine mutagenesis and biochemical cross-linking. In Aim 1, the participation of TM1 with TM3 in a common alcohol/anesthetic binding cavity was further investigated. We used two-electrode voltage clamp electrophysiology in Xenopus oocytes to demonstrate the ability of A288 in TM3 to form cross-links with I229 in TM1, which reduced the ability of both alcohol and anesthetics to modulate GlyR function. Aim 2 investigated whether TM3 could also participate in a binding cavity with TM4. We have shown that residues in TM4 are able to form cross-links with A288 in TM3, and found that cross-linking between TM3 and those residues in TM4 also reduced the ability of alcohol and anesthetics to enhance GlyR function. Aim 3 determined whether these cross-links are formed between residues within the same subunit (intra-subunit) or between subunits (inter-subunit), and ultimately whether these residues participate in a common alcohol/anesthetic binding cavity within or between GlyR subunits. GlyR protein, which measures about 50 kDa, was extracted from oocytes injected with the cysteine mutants, and immunoblotting was used with a GlyR-specific antibody to subsequently help quantify band ratios between cross-linked and uncross-linked conditions. We found an increase in the 100:50 kDa band ratio for the TM1-3 mutant only, but not TM3-4 mutant or the wild-type, which suggests TM1-3 may participate in an alcohol binding cavity between GlyR subunits while TM3-4 may contribute to a binding cavity within a subunit. / text

Glycine receptor

Alcohol

Anesthetics

Identification of novel allosteric modulators of the glycine receptor using phage display technology

Tipps, Megan Elizabeth

31 October 2011

The glycine receptor (GlyR) is a ligand-gated ion channel and a member of the cys-loop receptor family. Like other members of this family, the GlyR is a target for many drugs of abuse, including alcohol. While the effects of alcohol on these receptors have been well-characterized, the contribution of each receptor subtype to the overall physiological and behavioral effects of alcohol use are unclear. This is partially due to the limited pharmacology of the GlyR, which limits the ability to isolate GlyR function within a complex system. One method for identifying compounds that bind to and modulate a given target is phage display. This approach uses bacteriophage to screen a large number of peptide sequences for affinity at a given target. We developed a phage selection protocol to identify peptides that bind to the GlyR. These peptides were then tested for functional effects at the GlyR using two-electrode voltage clamp physiology. We identified several peptides that were able to modulate GlyR function. Peptide D12-116 showed specificity for the GlyR over two closely related γ-aminobutyric acid (GABA) channels. In addition, this method is easily adapted for the selection of peptides that bind to any cell-expressed target, increasing the utility of phage display in the neurobiology field. Another shortcoming in GlyR pharmacology is the lack of modulators with specificity for a single GlyR subtype. We next adjusted our selection protocol to search for peptides that can distinguish between the different Gly R α subtypes. We identified several promising lead peptides that show subtype preference. Finally, we found that trifluoroacetic acid (TFA), a common peptide contaminant, also modulates GlyR function. This finding has important implications for both previously reported peptide modulators and the pharmacology of several volatile anesthetics, for which TFA is the major metabolite / text

Glycine receptor

Phage display

Peptide

Trifluoroacetic acid

Zinc interactions with allosteric modulators at the glycine receptor

Cornelison, Garrett Lee

11 September 2014

The glycine receptor (GlyR) is a ligand-gated ion channel member of the Cys-loop receptor superfamily, responsible for inhibitory neurotransmission in the brain and spinal cord. Zinc is a potent allosteric modulator of GlyR function, enhancing GlyR activity at low nM to 10[mu]M concentrations while inhibiting GlyR activity at higher concentrations. We investigated sources of contaminating zinc, identifying low nM levels of zinc in ultrapure H₂O, powdered reagents used in the preparation of common electrophysiological buffers, and in polystyrene pipets. These low levels of zinc were capable of enhancing GlyR function. These findings suggest that without checking for this effect using a zinc-chelator such as tricine, one cannot assume that responses elicited by glycine applied alone are not necessarily also partially due to some level of allosteric modulation by zinc. Taurine-activated GlyR may have a role in the rewarding effects of drugs of abuse. Zinc is found at GlyR-potentiating concentrations throughout the nervous system, so we examined the combinatorial effects of zinc with drugs of abuse on taurine-activated GlyR to mimic in vivo conditions. Whole cell recordings revealed that zinc potentiation of saturating taurine-generated currents decreased further potentiation by drugs of abuse, indicating no synergistic effects on efficacy when receptors are saturated with taurine as may be seen during synaptic events in vivo. Finally, we utilized phage display to identify novel peptide modulators of the GlyR. We tested 26 peptides against [alpha1beta] GlyRs, identifying peptides with various levels of activity on GlyR function. We demonstrated that these modulators were zinc-dependent, as their effects on GlyR activity were abolished in the presence of the zinc-chelating agent tricine. Together, these data indicate the importance of accounting for the effects of zinc when studying the function of the GlyR, as even low levels of zinc that can be found as contaminants in labware and buffers can affect GlyR function and responses to various allosteric modulators, including drugs of abuse. / text

Glycine receptor

Ligand-gated ion channel

Zinc

Cys-loop receptor

A Novel Synthesis and Subsequent Decyclization of Iminothiozolidinones: Expansion of Thiourea Chemistry for Biological Applications

Franklin, Constance D

01 January 2017

Small molecule synthesis has become a valuable tool in the study of biological systems. Biologically active compounds can be designed based on well-characterized endogenous systems or they can be found through the screening of large libraries of small molecules. This work involves the development of a small library of cyclic thiourea-based small molecules by use of an unreported synthetic pathway. Briefly, parent thioureas were cyclized by reaction with bromoacetyl bromide, and one or two isomeric heterocycles were found to form. Further studies indicated that the reaction could be easily manipulated by temperature or solvent to effectively control the product distribution. These iminothiozolidinones were characterized by single crystal x-ray analysis. The new reaction was explored in an effort to uncover the factors influencing the control of the isomer formation. Furthermore, these iminothiozolidinones underwent a novel decyclization reaction that resulted in the loss of the parent thiourea connectivity and incorporation of an external nucleophile to yield an aminooxoethylcarbamothionate. The reaction proceeds through a termolecular mechanism. These reactions can be combined to a one-pot reaction series. These compounds share similarities with a class of compounds reported to be known HIV-1 reverse transcriptase inhibitors94. In addition to these new synthetic reactions, work was conducted with a previously developed cyclen thiourea receptor for the anionic dye HPTS and its derivatives50-52. This system was used to develop a cell labeling assay that led to the amplification of fluorescent labeling of target cells through the use of liposomes. Briefly, a dye-ligand conjugate for the glycine receptor was synthesized. Liposomes functionalized with the cyclen receptor were prepared encapsulating Rhodamine B. Confocal microscopy studies demonstrated the binding of the HPTS-ligand to the cell membranes. Addition of the liposomes resulted in quenching of the green fluorescence, indicating binding of the cyclen to HPTS. Subsequent excitation of Rhodamine B showed red fluorescence associated with the cells. The intensity of the red signal was demonstrably higher than for the signal resulting from the binding of the ligand-dye to the receptor. Together, these projects increase the synthetic usefulness of thiourea based small molecules and demonstrate the potential biological applications of related compounds.

thiourea

organic synthesis

cyclen

glycine receptor

iminothiozolidinone

liposomes

Organic Chemistry

Activation and allosteric modulation of the [alpha]1 glycine receptor

Welsh, Brian Thomas

24 January 2011

The glycine receptor (GlyR) is a ligand-gated ion channel and member of the nicotinic acetylcholine receptor superfamily. Glycine and the partial agonist taurine are both believed to be the endogenous ligands of the receptor. Partial agonists have lower efficacies than full agonists, eliciting submaximal responses even at saturating concentrations. Recent evidence suggests that efficacy at these receptors is determined by conformational changes that occur early in the process of receptor activation. We previously identified a mutation of the aspartate-97 residue to arginine (D97R), which produces a spontaneously active mutant with behavior that mimics the effects of saturating glycine concentrations on wildtype (WT) GlyR. This D97 residue is hypothesized to form an electrostatic interaction with arginine-119 on an adjacent subunit to stabilize a closed channel closed state. We found that the disruption of this bond converts taurine into a full agonist and greatly increases the efficacies of other [beta]-amino acid partial agonists. Our findings suggest that the determination of efficacy in the GlyR involves the disruption of an inter-subunit electrostatic interaction soon after binding. We next investigated whether the taurine efficacy could be enhanced by ethanol, a well-studied positive allosteric modulator of receptor function. Whole-cell recordings of WT GlyRs demonstrated that alcohol could potentiate the effect of low concentrations of taurine, but did not increase the efficacy of a saturating concentration. Therefore we sought to understand the mechanism by which alcohol enhances the GlyR, because ethanol's actions at inhibitory receptors in the brain are thought to produce many of the physiological effects associated with its use. We examined the effects of 3 [mu]M glycine ± 50 or 200 mM ethanol on outside-out patches expressing WT [alpha]1 GlyR, to determine the effects of alcohol at the single-channel level. Alcohol enhanced GlyR function in a very specific manner. It had minimal effects on open and closed dwell times. Instead, ethanol potentiated GlyR function almost exclusively by increasing burst durations and increasing the number of channel openings per burst, without affecting the percentage of open time within bursts. Kinetic modeling suggests that ethanol increases burst durations by decreasing the rate of glycine unbinding. / text

Glycine receptor

Ethanol

Single channel

Partial agonism

Taurine

Novel Insights Into the Activation of Glycine Receptors

Stephan Alexander Pless

Unknown Date

No description available.

PLASTIC CHANGES IN THE INHIBITORY GLYCINE SYSTEM OF THE DORSAL COCHLEAR NUCLEUS (DCN) IN A RAT MODEL OF TINNITUS

Wang, Hongning

01 January 2008

FFifteen to thirty-five percent of the population in the United States experience tinnitus, a subjective "ringing in the ears". Up to 10% of tinnitus patients report their symptoms are severe and disabling. Tinnitus was induced in FBN rats using 116 dB (SPL) unilateral octave-band sound exposures centered at 16 kHz for one hour in an anesthetized preparation. Rats were assessed behaviorally by an operant conditioning paradigm as well as a gap detection method to verify the development of tinnitus. Both young (7 mos.) and aged (30 mos.) sound exposed rats showed significant elevated auditory brainstem-evoked response (ABR) thresholds for clix and all tested frequencies immediately after the sound exposure. Eighty days post-exposure, ABR thresholds for the young exposed rats were significantly close to the initial young control values while aged exposed rats showed residual thresholds shifts relative to aged controls. Sixteen weeks following sound exposure, young exposed rats showed significantly reduced gap detection at 24 and 32 kHz, suggestive of high frequency tinnitus. Aged exposed animals showed significant tinnitus-related behavioral changes near 10 kHz by both behavior methods. Message and protein levels of &alpha1-3 glycine receptor subunits (GlyRs), gephyrin, BDNF and its receptor TrkB were assessed in dorsal cochlear nucleus (DCN) fusiform cells 4 months post exposure utilizing quantitative in situ hybridization and immunocytochemistry. Young exposed rats showed significant decreases of GlyR &alpha1 protein at middle and high frequency regions in DCN unlike the contrasting increase of their message levels. Aged exposed rats showed higher &alpha1 subunit protein levels in the same high and middle DCN frequency regions. The GlyR anchoring protein, gephyrin, was significantly increased in both young and aged exposed rats, suggesting an intracellular receptor trafficking change following acoustic trauma. BDNF and TrkB were also increased over fusiform cells in both young and aged exposed rats. [3H] strychnine binding was used to evaluate DCN GlyR pharmacology and function following sound exposure. The age-related decrease in GlyR α1 protein was reflected in the significant age-related down-regulation of GlyR (Bmax). Tinnitus-related changes in GlyR &alpha1 protein level was reflected in the decline of the GlyR (Bmax) in young exposed rats and up-regulated GlyRs in aged exposed animals. The GlyRs in DCN of young exposed animals also demonstrated an increase in affinity, further suggesting a post-exposure receptor composition change. These findings suggest that both aging and/or sound exposure/tinnitus are associated with GlyR changes capable of altering alter the output of the DCN. Detailed characterization of these GlyR modifications could advance the development of novel selective drugs for tinnitus and age-related hearing loss.

Aging

BDNF

Dorsal Cochlear Nucleus (DCN)

Gephyrin

Glycine receptor

Tinnitus

Single channel analysis of thiol binding to a putative site of alcohol action on the glycine receptor

Goldstein, Beth Erlichman

23 October 2009

An alcohol and anesthetic binding pocket is hypothesized to exist among transmembrane domains of the α1 glycine receptor (GlyR). Prior work has shown that amino acid residue serine-267 plays a significant role in the enhancing effects of alcohol and anesthetics and is theorized to form part of an alcohol and anesthetic binding cavity among subunit transmembrane domains. Propyl methanethiosulfonate (PMTS), an alcohol-like thiol, was previously shown to bind to a cysteine residue introduced at position 267 (S267C) and this resulted in permanent enhancement of GlyR function. If ethanol is binding to residue 267 in wildtype GlyR to potentiate receptor function then we hypothesized that covalent thiol labeling would produce receptor enhancement by the same mechanisms as ethanol. Using outside-out patch single channel electrophysiology we determined the open and closed dwell-times and burst properties of S267C GlyR in the absence and presence of PMTS. The primary consequence of PMTS binding to S267C GlyR was an increase in the lengths of burst durations, paralleling the main effect of ethanol on wildtype GlyR. Our findings thus provide a new line of evidence suggesting that ethanol is exerting its enhancing effects on the GlyR through its interactions with amino acid residue 267 in the second transmembrane domain. / text

Alcohol

Anesthetic

Glycine receptor

Thiol binding

Amino acid

Transmembrane domains

Propyl methanethiosulfonate

Amino acid residue 267

Critical elements contributing to the control of glycine receptor activation and allosteric modulation

Todorovic, Jelena, 1981-

02 February 2011

Glycine receptors (GlyRs) are ligand-gated ion channels (LGICs) that, along with other members of the cys-loop superfamily of receptors, mediate a considerable portion of fast neurotransmission in the central nervous system (CNS). GlyRs are pentameric channels, organized quasi-symmetrically around an ion-conducting pore. Opening of the integral ion pore depends on ligand binding and transduction of this binding signal to the channel gate. Research presented in this dissertation describes a number of critical electrostatic interactions that play a role in conserving the closed-state stability of the receptor in the absence of ligand, ensuring that receptor activation occurs only upon neurotransmitter binding. These amino acids, aspartic acid at position 97 (D97), lysine 116 (K116), arginine 119 (R119) and arginine R131 (R131) are charged residues that interact with one another through electrostatic attraction. When D97 is replaced with any other amino acid this destabilizes the closed state of the channel and causes spontaneous GlyR channel opening. I show that restoration of this electrostatic interaction in GlyR bearing double mutations in which the charges are swapped (D97R/R119E and D97R/R131D) markedly decreases this spontaneous current. In addition, I investigate how these residues that interact at the interfaces between receptor subunits affect the efficacies of GlyR partial agonists. My work shows that the partial agonist taurine is converted into a full agonist at both D97R and R131D receptors. Furthermore, I analyzed the structure of the more extracellular part of the transmembrane (TM) 2 segment that lines the ion channel pore, showing that it is unlikely that this fragment (stretching from T13’ to S18’) is constrained in a true alpha helical conformation. From this work, using disulfide trapping and whole cell electrophysiology, I conclude that a significant level of flexibility characterizes this part of the TM2 domain. This segment includes residue S267, previously shown to be significant for alcohol and anesthetic actions, as well as residue Q266 that, when mutated, produces a hyperekplexia-like phenotype. The range of movement of residues in this region may therefore play an important role not only in channel gating but also in how modulators of GlyR function exert their actions. / text

Glycine receptor

Ion channel

Single channel

Neurotransmission

LGIC

Cys-loop channel activation

Investigation into the Molecular Pharmacology of α1 and α3 Glycine Receptors

Xuebin Chen

Unknown Date

The glycine receptor (GlyR) mediates fast inhibitory neurotransmission in the central nervous system (CNS). Although GlyR α1 subunits are widely distributed, α3 subunits are found only on spinal cord pain sensory neurons where they mediate central inflammatory pain sensitization. Thus, the α3 subunit is a potential therapeutic target for anti-inflammatory analgesia. It is yet to be understood why α3 subunits are represented in these synapses. Thus, α3 subunit-specific modulators are required both as therapeutic leads and as pharmacological probes for basic research. The Thesis, which consists of three independent studies, investigated the molecular pharmacology of three classes of compounds at GlyRs, especially those containing the α3 subunit. The dihydropyridines (DHPs), nifedipine and nicardipine, modulate native GlyRs at micromolar concentrations. Nicardipine has a biphasic potentiating and inhibitory effect, whereas nifedipine causes inhibition only. The first study investigated the molecular mechanism by which these compounds inhibit recombinant GlyRs. The rate of onset of inhibition in the open state was accelerated by pre-application of DHP in the closed state, with the degree of acceleration proportional to the concentration of pre-applied DHP. This implies a non-inhibitory binding site close to the DHP inhibitory site. DHP inhibition was use-dependent and independent of glycine concentration, consistent with a pore-blocking mode of action. DHP sensitivity was abolished by the G2’A mutation, providing a strong case for DHP binding site in the pore. Nifedipine exhibited an approximately 10-fold higher inhibitory potency at α1-containing relative to α3-containing receptors, whereas nicardipine was only weakly selective for α1-containing GlyRs. The differential sensitivities of nifedipine and nicardipine for different GlyR isoforms suggest that DHPs may be a useful resource to screen as pharmacological tools for selectively inhibiting different synaptic GlyR isoforms. To date there are few compounds known to pharmacologically discriminate between α1 and α3 subunit-containing GlyRs. The second study stemmed from an observation that β-alanine and taurine act as weak partial agonists of α3 GlyRs but as strong partial agonists at α1 GlyRs. Using chimeras of α1 and α3 subunits, we identified the relatively structurally divergent M4 transmembrane domain and C-terminal tail as a specific determinant of the efficacy difference. As mutation of individual non-conserved M4 residues had little influence on agonist efficacies, the reduced efficacy of α3 GlyRs is most likely a distributed effect of all non-conserved M4 residues. Given the lack of contact between M4 and other transmembrane domains, the efficacy differences are probably mediated by differential interactions between the respective M4 domains and the surrounding lipid environment. The strong influence of M4 primary structure on partial agonist efficacy suggests that the relatively poorly conserved α3 GlyR M4 domain may be a promising domain to target in the search for α3 GlyR-specific modulators. β-carbolines have recently been shown to inhibit glycine receptors in a subunit-specific manner. The third study screened four structurally similar β-carbolines, harmane (HM), tryptoline (TP), norharmane (NHM) and 6-methoxyharmalan (MH) at recombinantly expressed α1, α1β, α2 and α3 glycine receptors. The four compounds exhibited only weak subunit-specificity, rendering them unsuitable as pharmacological probes. Because they displayed competitive antagonist activity, we investigated the roles of known glycine binding residues in coordinating the four compounds. The structural similarity of the compounds, coupled with the differential effects of C-loop mutations (T204A, F207Y) on compound potency, implied direct interactions between variable β-carboline groups and mutated residues. Mutant cycle analysis employing HM and NHM revealed a strong pairwise interaction between the HM methyl group and the C-loop in the region T204 and F207. These results, which define the orientation of the bound β-carbolines, were supported by molecular docking simulations. The information may also be relevant to understanding the mechanism of β-carboline binding to GABAAR where they are potent pharmacological probes. The identification of compounds that specifically abolish α3 GlyR-mediated currents should provide a useful means to investigate the physiological roles of this subunit. Drugs that potently and selectively enhance α3-subtype GlyR function may potentially serve as lead compounds since α3-subtype GlyRs have emerged as a potential therapeutic target for pain treatment. Results from studies forming the Thesis have identified several structural elements that might be useful for developing novel α3 subunit-specific drugs in the future.

Ligand-gated Ion Channel

Glycine Receptor

Pharmacology

Dihydropyridine

Beta-carboline

agonist