Effects of gamma2S subunit incorporation on GABAA receptor macroscopic kinetics.

GABA(A) receptors, the major inhibitory neurotransmitter receptors in the mammalian central nervous system, are heteropentameric proteins. We are interested in understanding the contribution of the gamma subunit to the kinetic properties of GABA(A) receptors. Studies in Xenopus oocytes have suggested that co-expression of alpha1, beta2, and gamma 2S subunits results in the formation of both alpha beta and alpha betagamma receptors (Boileau et al. 2002a; Boileau et al., 1998). Here, we have used an excess of the gamma 2S subunit in transfections of HEK293 cells to bias expression toward alpha beta gamma-containing receptors. Using rapid application and whole cell patch clamp techniques, we found that incorporation of the gamma subunit eliminated the rapid phases of desensitization and accelerated deactivation, consistent with a proposed role of desensitization in slowing deactivation. In addition, alpha betagamma receptors had an increased GABA EC(50), reduced sensitivity to block by Zn(2+), and did not display outward rectification as compared to alpha beta receptors.

The relative amount of cRNA coding for gamma2 subunits affects stimulation by benzodiazepines in GABA(A) receptors expressed in Xenopus oocytes.

Benzodiazepine (BZD) potentiation of GABA-activated Cl(-)-current (I(GABA)) in recombinant GABA(A) receptors requires the presence of the gamma subunit. When alpha1, beta2 and gamma2S cRNA are expressed in a 1:1:1 ratio in Xenopus oocytes, BZD potentiation of I(GABA) is submaximal, variable and diminishes over time. Potentiation by BZDs is increased, more reproducible and is stabilized over time by increasing the relative amount of cRNA coding for the gamma2S subunit. In addition, GABA EC(50) values for alpha1beta2gamma2 (1:1:1) receptors are intermediate to values measured for alpha1beta2 (1:1) and alpha1beta2gamma2 (1:1:10) receptors. We conclude that co-expression of equal ratios of alpha1, beta2 and gamma2 subunits in Xenopus oocytes produces a mixed population of alpha1beta2 and alpha1beta2gamma2 receptors. Therefore, for accurate measurements of BZD potentiation it is necessary to inject a higher ratio of gamma2 subunit cRNA relative to alpha1 and beta2 cRNA. This results in a purer population of alpha1beta2gamma2 receptors.

Identification of benzodiazepine binding site residues in the gamma2 subunit of the gamma-aminobutyric acid(A) receptor.

gamma-Aminobutyric acid(A) receptor gamma-subunits are important for benzodiazepine (BZD) binding and modulation of the gamma-aminobutyric acid-mediated Cl(-) current. Previously, by using gamma2/alpha1 chimeric subunits, we identified two domains of the gamma2-subunit, Lys-41-Trp-82 and Arg-114-Asp-161, that are, in conjunction, necessary and sufficient for high-affinity BZD binding. In this study, we generated additional gamma2/alpha1 chimeric subunits and gamma2 point mutants to identify specific residues within the gamma2 Lys-41-Trp-82 region that contribute to BZD binding. Mutant gamma2 and gamma2/alpha1 chimeric subunits were expressed with wild-type alpha1 and beta2 subunits in HEK 293 cells, and the binding of several BZDs was measured. We present evidence that the gamma2 region Met-57-Ile-62 is important for flunitrazepam binding and that, in particular, gamma2 Met-57 and gamma2 Tyr-58 are essential determinants for conferring high-affinity binding. Furthermore, we identify an additional residue, gamma2 Ala-79, that not only is important for high-affinity binding by flunitrazepam (a strong positive modulator) but also plays a crucial role in the binding of the imidazobenzodiazepines Ro15-1788 (a zero modulator) and Ro15-4513 (a weak negative modulator) in the BZD binding pocket. Results from site-directed mutagenesis of gamma2 Ala-79 suggest that this residue may be part of a microdomain within the BZD binding site that is important for binding imidazobenzodiazepines. This separation of drug-specific microdomains for competitive BZD ligands lends insight into the structural determinants governing the divergent effects of these compounds.

Identification of transduction elements for benzodiazepine modulation of the GABA(A) receptor: three residues are required for allosteric coupling.

Modulation of GABA(A) receptors by benzodiazepines (BZDs) is believed to involve two distinct steps: a recognition step in which BZDs bind and a conformational transition step in which the affinity of the receptor for GABA changes. Previously, using gamma(2)/alpha(1) chimeric subunits (chi), we demonstrated that although the N-terminal 167 gamma(2) amino acid residues confer high-affinity BZD binding, other gamma(2) domains couple BZD binding to potentiation of the GABA-mediated Cl(-) current (I(GABA)). To determine which gamma(2) regions couple binding to potentiation, we generated chis with longer N-terminal gamma(2) segments for voltage-clamp experiments in Xenopus oocytes. Chimeras containing greater than the N-terminal 167 gamma(2) residues showed incremental gains in maximal potentiation for diazepam enhancement of I(GABA). Residues in gamma(2)199-236, gamma(2)224-236 (pre-M1), and particularly gamma(2)257-297 (M2 and surrounding loops) are important for BZD potentiation. For several positive BZD modulators tested, the same regions restored potentiation of I(GABA). In contrast, beta-carboline inverse-agonism was unaltered in chimeric receptors, suggesting that structural determinants for positive and negative BZD allosteric modulation are different. Dissection of the gamma(2)257-297 domain revealed that three residues in concert, gamma(2)T281, gamma(2)I282 (M2 channel vestibule), and gamma(2)S291 (M2-M3 loop) are necessary to impart full BZD potentiation to chimeric receptors. Thus, these residues participate in coupling distant BZD-binding events to conformational changes in the GABA(A) receptor. The location of these novel residues provides insight into the mechanisms underlying allosteric coupling for other members of the ligand-gated ion channel superfamily.

Mapping the agonist binding site of the GABAA receptor: evidence for a beta-strand.

GABAA receptors, along with the receptors for acetylcholine, glycine, and serotonin, are members of a ligand-gated ion channel superfamily (Ortells and Lunt, 1995). Because of the paucity of crystallographic information for these ligand-gated channels, little is known about the structure of their binding sites or how agonist binding is transduced into channel gating. We used the substituted cysteine accessibility method to obtain secondary structural information about the GABA binding site and to systematically identify residues that line its surface. Each residue from alpha1 Y59 to K70 was mutated to cysteine and expressed with wild-type beta2 subunits in Xenopus oocytes or HEK 293 cells. The sulfhydryl-specific reagent N-biotinylaminoethyl methanethiosulfonate (MTSEA-Biotin) was used to covalently modify the cysteine-substituted residues. Receptors with cysteines substituted at positions alpha1 T60, D62, F64, R66, and S68 reacted with MTSEA-Biotin, and alpha1 F64C, R66C, and S68C were protected from reaction by agonist. We conclude that alpha1 F64, R66, and S68 line part of the GABA binding site. The alternating pattern of accessibility of consecutive engineered cysteines to reaction with MTSEA-Biotin indicates that the region from alpha1 Y59 to S68 is a beta-strand.

Transformation of Paramecium tetraurelia by electroporation or particle bombardment.

Methods for mass transformation of Paramecium tetraurelia were established using plasmids bearing neomycin-resistance or calmodulin gene fragments. Phenotypic and molecular analyses showed that, although variable, up to 5% transformation can be achieved by electroporation. Concentrations of divalent cations Ca2+ and Mg2+ in the electroporation medium were crucial for efficient transformation. Strong neomycin-resistance transformation using bioballistic particle bombardment with gold particles was observed. For both methods, hybridization to transformant DNA revealed plasmid signals consistent with macronuclear transformation and correlated with transformed phenotypes. Complementation of a known calmodulin gene mutation was also achieved by mass transformation. Possible sources of variation and the general utility of these methods are discussed.

A GABAA receptor alpha1 subunit tagged with green fluorescent protein requires a beta subunit for functional surface expression.

gamma-Aminobutyric acid, type A (GABAA) receptors, the major inhibitory neurotransmitter receptors in the central nervous system, are heteropentameric proteins assembled from distinct subunit classes with multiple subtypes, alpha(1-6), beta(1-4), gamma(1-3), delta(1), and epsilon(1). To examine the process of receptor assembly and targeting, we tagged the carboxyl terminus of the GABAA receptor alpha1 subunit with red-shifted enhanced green fluorescent protein (EGFP). Xenopus oocytes were injected with cRNA of this fusion protein, alpha1-EGFP, alone or in combination with cRNA of GABAA receptor beta2, gamma2, or beta2+gamma2 subunits. Within 72 h after injection, EGFP fluorescence was visible in all fusion protein-injected cells. The fluorescence was associated with the plasmalemma only when the beta2 subunit was co-injected with alpha1-EGFP. Texas Red-conjugated immunolabeling of EGFP on nonpermeabilized cells demonstrated that EGFP was localized extracellularly. Hence, the COOH terminus of the alpha1 subunit is extracellular. Two-electrode voltage clamp of alpha1-EGFPbeta2- and alpha1-EGFPbeta2 gamma2-injected oocytes demonstrates that these cells express functional receptors, with EC50 values for GABA and diazepam similar to wild-type receptors. Thus, a COOH-terminal tag of the alpha1 subunit appears to be functionally silent, providing a useful marker for studies of GABAA receptor expression, assembly, transport, targeting, and clustering. Moreover, the beta2 subunit is required for receptor assembly and surface expression.

Molecular dissection of benzodiazepine binding and allosteric coupling using chimeric gamma-aminobutyric acidA receptor subunits.

Although gamma-aminobutyric acid (GABA)A receptor alpha subunits are important for benzodiazepine (BZD) binding and GABA-current potentiation by BZDs, the presence of a gamma subunit is required for high affinity BZD effects. To determine which regions unique to the gamma2S subunit confer BZD binding and potentiation, we generated chimeric protein combinations of rat gamma2S and alpha1 subunits using a modified protocol to target crossover events to the amino-terminal extracellular region of the subunits. Several chimeras with full open reading frames were constructed and placed into vectors for either voltage-clamp experiments in Xenopus laevis oocytes or radioligand binding experiments in human embryonic kidney 293 cells. Chimeras (chi) containing at least the amino-terminal 161 amino acids of gamma2S bound BZDs with wild-type affinity when coexpressed with alpha1 and beta2 subunits. Further analysis of the gamma2S binding site region uncovered two areas, gamma2S K41-W82 and gamma2S R114-D161, that together are necessary and sufficient for high affinity BZD binding. Surprisingly, although the 161-amino acid residue amino terminus of the gamma2S subunit is sufficient for high affinity BZD binding, it is not sufficient for efficient allosteric coupling of the GABA and BZD binding sites, as demonstrated by reduced diazepam potentiation of the GABA-gated current and GABA potentiation of [3H]flunitrazepam binding. Thus, by using gamma/alpha chimeras, we identified two gamma2 subunit regions required for BZD binding that are distinct from domain or domains responsible for allosteric coupling of the BZD and GABA binding sites.

Osmotaxis in Escherichia coli.

The escape of motile organisms from high concentrations of chemicals was studied in Escherichia coli. We have found all chemicals tested to be osmorepellents. It was shown in both a spatial assay and a temporal assay that the known sensory receptors for chemotaxis are not used for osmotaxis, so a different sensory mechanism appears to be employed. According to the temporal assay, the mechanism between sensory receptors and flagella is also not used for tumbling response (at least in solutions above 0.4 osmolar).