Jakob Heid

GABAB-receptor subtypes assemble into functional heteromeric complexes

B-type receptors for the neurotransmitter GABA (γ-aminobutyric acid) inhibit neuronal activity through G-protein-coupled second-messenger systems, which regulate the release of neurotransmitters and the activity of ion channels and adenylyl cyclase. Physiological and biochemical studies show that there are differences in drug efficiencies at different GABAB receptors, so it is expected that GABAB-receptor (GABABR) subtypes exist. Two GABAB-receptor splice variants have been cloned (GABABR1a and GABABR1b), but native GABAB receptors and recombinant receptors showed unexplained differences in agonist-binding potencies. Moreover, the activation of presumed effector ion channels in heterologous cells expressing the recombinant receptors proved difficult,. Here we describe a new GABAB receptor subtype, GABABR2, which does not bind available GABAB antagonists with measurable potency. GABABR1a, GABABR1b and GABABR2 alone do not activate Kir3-type potassium channels efficiently, but co-expression of these receptors yields a robust coupling to activation of Kir3 channels. We provide evidence for the assembly of heteromeric GABAB receptors in vivo and show that GABABR2 and GABABR1a/b proteins immunoprecipitate and localize together at dendritic spines. The heteromeric receptor complexes exhibit a significant increase in agonist- and partial-agonist-binding potencies as compared with individual receptors and probably represent the predominant native GABAB receptor. Heteromeric assembly among G-protein-coupled receptors has not, to our knowledge, been described before.

Epilepsy, Hyperalgesia, Impaired Memory, and Loss of Pre- and Postsynaptic GABA B Responses in Mice Lacking GABA B(1)

GABA(B) (gamma-aminobutyric acid type B) receptors are important for keeping neuronal excitability under control. Cloned GABA(B) receptors do not show the expected pharmacological diversity of native receptors and it is unknown whether they contribute to pre- as well as postsynaptic functions. Here, we demonstrate that Balb/c mice lacking the GABA(B(1)) subunit are viable, exhibit spontaneous seizures, hyperalgesia, hyperlocomotor activity, and memory impairment. Upon GABA(B) agonist application, null mutant mice show neither the typical muscle relaxation, hypothermia, or delta EEG waves. These behavioral findings are paralleled by a loss of all biochemical and electrophysiological GABA(B) responses in null mutant mice. This demonstrates that GABA(B(1)) is an essential component of pre- and postsynaptic GABA(B) receptors and casts doubt on the existence of proposed receptor subtypes.

Redistribution of GABAB(1) Protein and Atypical GABAB Responses in GABAB(2)-Deficient Mice

GABAB receptors mediate slow synaptic inhibition in the nervous system. In transfected cells, functional GABAB receptors are usually only observed after coexpression of GABAB(1) and GABAB(2) subunits, which established the concept of heteromerization for G-protein-coupled receptors. In the heteromeric receptor, GABAB(1) is responsible for binding of GABA, whereas GABAB(2) is necessary for surface trafficking and G-protein coupling. Consistent with these in vitro observations, the GABAB(1) subunit is also essential for all GABAB signaling in vivo. Mice lacking the GABAB(1) subunit do not exhibit detectable electrophysiological, biochemical, or behavioral responses to GABAB agonists. However, GABAB(1) exhibits a broader cellular expression pattern than GABAB(2), suggesting that GABAB(1) could be functional in the absence of GABAB(2). We now generated GABAB(2)-deficient mice to analyze whether GABAB(1) has the potential to signal without GABAB(2) in neurons. We show that GABAB(2)-/- mice suffer from spontaneous seizures, hyperalgesia, hyperlocomotor activity, and severe memory impairment, analogous to GABAB(1)-/- mice. This clearly demonstrates that the lack of heteromeric GABAB(1,2) receptors underlies these phenotypes. To our surprise and in contrast to GABAB(1)-/- mice, we still detect atypical electrophysiological GABAB responses in hippocampal slices of GABAB(2)-/- mice. Furthermore, in the absence of GABAB(2), the GABAB(1) protein relocates from distal neuronal sites to the soma and proximal dendrites. Our data suggest that association of GABAB(2) with GABAB(1) is essential for receptor localization in distal processes but is not absolutely necessary for signaling. It is therefore possible that functional GABAB receptors exist in neurons that naturally lack GABAB(2) subunits.

γ-Hydroxybutyrate is a weak agonist at recombinant GABAB receptors

Gamma-hydroxybutyrate (GHB) is a neuromodulator with high affinity binding sites in the mammalian brain. However, the receptor for GHB has not yet been identified. There are indications that GHB and gamma-aminobutyric acid (GABA) mediate their effects via the same receptor. We tested this hypothesis using GABA(B)R1/R2 receptors co-expressed with Kir3 channels in Xenopus oocytes. GHB activated these receptors with an EC50 of approximately 5 mM and a maximal stimulation of 69% when compared to the GABA(B) receptor agonist L-baclofen. GHB and L-baclofen did not amplify each others effect nor did they stimulate the GABA(B) receptor in a linearly additive manner. CGP54626A, 2-OH saclofen and CGP35348, three competitive GABA(B) receptor antagonists, inhibited the GHB induced response completely. A concentration of 30 mM GHB displaced [125I]CGP64213 binding at GABA(B)R1 expressed in COS cells by 21%. These results indicate that GHB is a weak partial agonist at the GABA binding site of GABA(B)R1/R2.

Developmental changes of agonist affinity at GABABR1 receptor variants in rat brain

Recently, two N-terminal splice variants of the metabotropic receptor for GABA (gamma-amino-butyric acid) were cloned. Here, we describe an antiserum that recognizes the two receptor variants. We demonstrate that these proteins are identical with GABAB receptors that are photoaffinity labeled with [125I]CGP71872 in rat brain. The C-terminal epitopes recognized by the antiserum are conserved in several vertebrate species but not in chicken. No hints for the existence of additional closely related receptor subtypes or variants are found in double-labeling experiments with antibody and photoaffinity ligand. Western blot analysis reveals widespread expression of the GABABR1 receptor proteins in rat brain with the highest level of expression at early postnatal stages. The binding affinity of the GABAB receptor agonist L-baclofen at native R1a and R1b variants is similar. In early postnatal development the affinity at R1a and R1b is 10-fold lower than in adult brain and gradually increases with aging.

Ligands for expression cloning and isolation of GABAB receptors

Outlined is the rationale behind the syntheses of radioligands [125I]CGP64213 and [125I]CGP71872, which led to the identification of cloned GABA(B) receptors 1a and 1b 17 years after the first pharmacological characterisation of native GABA(B) receptors by Bowery et al. [Nature 283 (1980) 92-94]. More recently it was shown that the N-terminal extracellular domains of GABA(B) receptors 1a and 1b contain the binding sites for agonists and antagonists [B. Malitschek et al., Mol. Pharmacol. 56 (1999) 448-454]. In order to isolate the extracellular domain(s) of GABA(B) receptors 1a (or 1b) and to purify and crystallise these proteins a third ligand [125I]CGP84963 was designed, which combines, in one molecule, a GABA(B) receptor binding part, an azidosalicylic acid as photoaffinity moiety and 2-iminobiotin, which binds to avidin in a reversible, pH-dependent fashion [W. Froestl et al., Neuropharmacology 38 (1999) 1641-1646].

Ligands for the isolation of GABAB receptors : W. Froestl would like to dedicate this work to the first GABAB chemist, Cr Heinrich Keberle, on the occasion of his 77th birthday

Since the discovery that the most abundant inhibitory neurotransmitter in the mammalian brain, GABA (gamma-aminobutyric acid), interacts not only with ionotropic GABA(A) receptors, but also with metabotropic GABA(B) receptors (Bowery et al., 1980) much work has been devoted to the elucidation of the structure of GABA(B) receptors by either affinity chromatography purification or by expression cloning. In 1997 Kaupmann et al. succeeded in cloning two splice variants designated GABA(B) R1a (960 amino acids) and GABA(B) R1b (844 amino acids). Although the amino acid sequences are now known, precise information on the three-dimensional environment of the GABA(B) R1 binding site is still lacking. Recent experiments demonstrated that the amino acids of the seven transmembrane helices are not essential for ligand binding as a soluble GABA(B) receptor fragment is still able to bind antagonists (Malitschek et al., 1999). For the isolation and purification of the soluble N-terminal extracellular domain (NTED) of GABA(B) receptors potent ligands for affinity chromatography were synthesised with the aim of obtaining a crystalline receptor fragment-ligand complex for X-ray structure determination. The most promising ligand [125I]CGP84963 (K(D) = 2 nM) combines, in one molecule, a GABA(B) receptor binding part, an azidosalicylic acid as a photoaffinity moiety separated by a spacer consisting of three GABA molecules from 2-iminobiotin, which binds to avidin in a reversible, pH-dependent fashion.

Erratum to “Ligands for the isolation of GABAB receptors”: [Neuropharmacology 38 (1999), 1641–1646]

Erratum Erratum to ‘‘Ligands for the isolation of GABAB receptors’’ [Neuropharmacology 38 (1999), 1641–1646] Wolfgang Froestl *, Bernhard Bettler, Helmut Bittiger, Jakob Heid, Klemens Kaupmann, Stuart J. Mickel, Dietrich Strub No6artis Pharma AG, Therapeutic Area Ner6ous System, WKL-136.5.25, CH-4002 Basel, Switzerland Dedicated to: W. Froestl would like to dedicate this work to the first GABAB chemist, Dr Heinrich Keberle, on the occasion of his 77th birthday. www.elsevier.com/locate/neuropharm