Balance of activity between LN(v)s and glutamatergic dorsal clock neurons promotes robust circadian rhythms in Drosophila.

Circadian rhythms offer an excellent opportunity to dissect the neural circuits underlying innate behavior because the genes and neurons involved are relatively well understood. We first sought to understand how Drosophila clock neurons interact in the simple circuit that generates circadian rhythms in larval light avoidance. We used genetics to manipulate two groups of clock neurons, increasing or reducing excitability, stopping their molecular clocks, and blocking neurotransmitter release and reception. Our results revealed that lateral neurons (LN(v)s) promote and dorsal clock neurons (DN(1)s) inhibit light avoidance, these neurons probably signal at different times of day, and both signals are required for rhythmic behavior. We found that similar principles apply in the more complex adult circadian circuit that generates locomotor rhythms. Thus, the changing balance in activity between clock neurons with opposing behavioral effects generates robust circadian behavior and probably helps organisms transition between discrete behavioral states, such as sleep and wakefulness.

5-HT3 receptor ion size selectivity is a property of the transmembrane channel, not the cytoplasmic vestibule portals.

5-HT3A receptors select among permeant ions based on size and charge. The membrane-associated (MA) helix lines the portals into the channel's cytoplasmic vestibule in the 4-Å resolution structure of the homologous acetylcholine receptor. 5-HT3A MA helix residues are important determinants of single-channel conductance. It is unknown whether the portals into the cytoplasmic vestibule also determine the size selectivity of permeant ions. We sought to determine whether the portals form the size selectivity filter. Recently, we showed that channels functioned when the entire 5-HT3A M3-M4 loop was replaced by the heptapeptide M3-M4 loop sequence from GLIC, a bacterial Cys-loop neurotransmitter gated ion channel homologue from Gloebacter violaceus. We used homomeric 5-HT3A receptors with either a wild-type (WT) M3-M4 loop or the chimeric heptapeptide (5-HT3A-glvM3M4) loop, i.e., with or without portals. In Na(+)-containing buffer, the WT receptor current-voltage relationship was inwardly rectifying. In contrast, the 5-HT3A-glvM3M4 construct had a negative slope conductance region at voltages less than -80 mV. Glutamine substitution for the heptapeptide M3-M4 loop arginine eliminated the negative slope conductance region. We measured the relative permeabilities and conductances of a series of inorganic and organic cations ranging from 0.9 to 4.5 Å in radius (Li(+), Na(+), ammonium, methylammonium, ethanolammonium, 2-methylethanolammonium, dimethylammonium, diethanolammonium, tetramethylammonium, choline, tris [hydroxymethyl] aminomethane, and N-methyl-d-glucamine). Both constructs had measurable conductances with Li(+), ammonium, and methylammonium (size range of 0.9-1.8-Å radius). Many of the organic cations >2.4 Å acted as competitive antagonists complicating measurement of conductance ratios. Analysis of the permeability ratios by excluded volume theory indicates that the minimal pore radius for 5-HT3A and 5-HT3-glvM3M4 receptors was similar, ∼ 5 Å. We infer that the 5-HT3A size selectivity filter is located in the transmembrane channel and not in the portals into the cytoplasmic vestibule. Thus, the determinants of size selectivity and conductance are located in physically distinct regions of the channel protein.

Drosophila pacemaker neurons require g protein signaling and GABAergic inputs to generate twenty-four hour behavioral rhythms.

Intercellular signaling is important for accurate circadian rhythms. In Drosophila, the small ventral lateral neurons (s-LN(v)s) are the dominant pacemaker neurons and set the pace of most other clock neurons in constant darkness. Here we show that two distinct G protein signaling pathways are required in LN(v)s for 24 hr rhythms. Reducing signaling in LN(v)s via the G alpha subunit Gs, which signals via cAMP, or via the G alpha subunit Go, which we show signals via Phospholipase 21c, lengthens the period of behavioral rhythms. In contrast, constitutive Gs or Go signaling makes most flies arrhythmic. Using dissociated LN(v)s in culture, we found that Go and the metabotropic GABA(B)-R3 receptor are required for the inhibitory effects of GABA on LN(v)s and that reduced GABA(B)-R3 expression in vivo lengthens period. Although no clock neurons produce GABA, hyperexciting GABAergic neurons disrupts behavioral rhythms and s-LN(v) molecular clocks. Therefore, s-LN(v)s require GABAergic inputs for 24 hr rhythms.

Chloroquine-resistant isoforms of the Plasmodium falciparum chloroquine resistance transporter acidify lysosomal pH in HEK293 cells more than chloroquine-sensitive isoforms.

The emergence of chloroquine-resistant Plasmodium falciparum malaria imperils the lives of millions of people in Africa, Southeast Asia and South America. Chloroquine resistance is associated with mutations in the P. falciparum chloroquine resistance transporter (PfCRT). We expressed chloroquine-sensitive (HB3) and resistant (Dd2) pfcrt alleles in HEK293 human embryonic kidney cells. PfCRT localized to the lysosomal limiting membrane and was not detected in the plasma membrane. We observed significant acidification of lysosomes containing PfCRT HB3 and Dd2, with Dd2 acidifying significantly more than HB3. A mutant HB3 allele expressing the K76T mutation (earlier found to be key for chloroquine resistance) acidified to the same extent as Dd2, whereas the acidification by a Dd2 allele expressing the T76K "back mutation" was significantly less than Dd2. Thus, the amino acid at position 76 is both an important determinant of chloroquine resistance in parasites and of lysosomal acidification following heterologous expression. PfCRT may be capable of modulating the pH of the parasite digestive vacuole, and thus chloroquine availability. Chloroquine accumulation and glycyl-phenylalanine-2-naphthylamide-induced release of lysosomal Ca(2+) stores were unaffected by PfCRT expression. Cytoplasmic domain mutations did not alter PfCRT sorting to the lysosomal membrane. This heterologous expression system will be useful to characterize PfCRT protein structure and function, and elucidate its molecular role in chloroquine resistance.

Detection of human and rodent 5-HT3B receptor subunits by anti-peptide polyclonal antibodies.

BACKGROUND: The 5-HT3 receptor is a member of a neurotransmitter-gated ion channel family which includes nicotinic acetylcholine, GABAA, and glycine receptors. While antibodies specific for the 5-HT3A receptor subunit are plentiful, and have revealed a wealth of structural and functional information, few antisera exist for the detection of 5-HT3B receptor subunits. Here we describe the generation and characterisation of a rabbit polyclonal antiserum that specifically recognises 5-HT3B receptor subunits RESULTS: Immunization of a rabbit with a 20-mer peptide, corresponding to the N-terminus of the human 5-HT3B receptor subunit, generated serum with polyclonal antibodies from which an IgG fraction was purified, yielding pAb77. The antibodies were shown to label 5-HT3B receptor subunits in transfected human embryonic kidney cells and rodent tissues using Western blots. Immunocytochemistry using pAb77 on these cells showed that 5-HT3B receptor subunits do not reach the plasma membrane in the absence of 5-HT3A receptor subunits. Immunohistochemical analysis of rat brain sections showed pAb77 immunoreactivity in distinct populations of cells in the hippocampus. CONCLUSION: We have demonstrated that pAb77 antibodies specifically label native and recombinant 5-HT3B receptor subunits with high affinity and specificity. The antibody was shown to be useful for the determination of both receptor trafficking and also mapping 5-HT3B receptor subunit expression in the CNS.

A role for the beta 1-beta 2 loop in the gating of 5-HT3 receptors.

Based on the Torpedo acetylcholine receptor structure, Unwin and colleagues (Miyazawa et al., 2003; Unwin, 2005) hypothesized that the transduction of agonist binding to channel gate opening involves a "pin-into-socket" interaction between alphaV46 at the tip of the extracellular beta1-beta2 loop and the transmembrane M2 segment and M2-M3 loop. We mutated to cysteine the aligned positions in the 5-HT3A and 5-HT3B subunit beta1-beta2 loops K81 and Q70, respectively. The maximal 5-HT-activated currents in receptors containing 5-HT3A/K81C or 5-HT3B/Q70C were markedly reduced compared with wild type. Desensitization of wild-type currents involved fast and slow components. Mutant currents desensitized with only the fast time constant. Reaction with several methanethiosulfonate reagents potentiated currents to wild-type levels, but reaction with other more rigid thiol-reactive reagents caused inhibition. Single-channel conductances of wild type, K81C, and K81C after modification were similar. We tested the proximity of K81C to the M2-M3 loop by mutating M2-M3 loop residues to cysteine in the K81C background. Disulfide bonds formed in 5-HT3A/K81C/A304C and 5-HT3A/K81C/I305C when coexpressed with 5-HT3B. We conclude that in the resting state, K81 is not in a hydrophobic pocket as suggested by the pin-into-socket hypothesis. K81 interacts with the extracellular end of M2 and plays a critical role in channel opening and in the return from fast desensitization. We suggest that during channel activation, beta1-beta2 loop movement moves M2 and the M2-M3 loop so that the M2 segments rotate/translate away from the channel axis, thereby opening the lumen. Recovery from fast desensitization requires the interaction between K81 and the extracellular end of M2.

Locating an antagonist in the 5-HT3 receptor binding site using modeling and radioligand binding.

We have used a homology model of the extracellular domain of the 5-HT(3) receptor to dock granisetron, a 5-HT(3) receptor antagonist, into the binding site using AUTODOCK. This yielded 13 alternative energetically favorable models. The models fell into 3 groups. In model type A the aromatic rings of granisetron were between Trp-90 and Phe-226 and its azabicyclic ring was between Trp-183 and Tyr-234, in model type B this orientation was reversed, and in model type C the aromatic rings were between Asp-229 and Ser-200 and the azabicyclic ring was between Phe-226 and Asn-128. Residues located no more than 5 A from the docked granisetron were identified for each model; of 26 residues identified, 8 were found to be common to all models, with 18 others being represented in only a subset of the models. To identify which of the docking models best represents the ligand-receptor complex, we substituted each of these 26 residues with alanine and a residue with similar chemical properties. The mutant receptors were expressed in human embryonic kidney (HEK)293 cells and the affinity of granisetron determined using radioligand binding. Mutation of 2 residues (Trp-183 and Glu-129) ablated binding, whereas mutation of 14 other residues caused changes in the [(3)H]granisetron binding affinity in one or both mutant receptors. The data showed that residues both in and close to the binding pocket can affect antagonist binding and overall were found to best support model B.

Loose protein packing around the extracellular half of the GABA(A) receptor beta1 subunit M2 channel-lining segment.

GABA(A) receptors are ligand-gated ion channels formed by the pseudosymmetrical assembly of five homologous subunits around the central channel axis. The five M2 membrane-spanning segments largely line the channel. In the present work we probed the water surface accessibility of the beta(1) subunit M2 segment using the substituted cysteine accessibility method. We assayed the reaction of the negatively charged sulfhydryl-specific reagent, p-chloromercuribenzenesulfonate (pCMBS(-)), by its effect on subsequent currents elicited by EC(50) and saturating GABA concentrations. pCMBS(-), applied with GABA, reacted with 14 of the 19 residues tested. At the M2 cytoplasmic end from 2' to 6' only beta(1)A252C (2') and beta(1)T256C (6') were pCMBS(-)-reactive in the presence of GABA. We infer that the M2 segments are tightly packed in this region. Toward the extracellular half of M2 all residues from beta(1)T262C (12') through beta(1)E270C (20') reacted with pCMBS(-) applied with GABA. We infer that this region is highly mobile and loosely packed against the rest of the protein. Based on differences in pCMBS(-) reaction rates two domains can be distinguished on the putative channel-lining side of M2. A faster reacting domain includes the 2', 9', 12', 13', and 16' residues. The slower reacting face contains the 6', 10', and 14' residues. We hypothesize that these may represent the channel-lining faces in the closed and open states and that gating involves an 80-100 degrees rotation of the M2 segments. These results are consistent with the loose packing of the M2 segments inferred from the structure of the homologous Torpedo nicotinic acetylcholine receptor.

Prediction of 5-HT3 receptor agonist-binding residues using homology modeling.

5-HT(3) receptors demonstrate significant structural and functional homology to other members of the Cys-loop ligand-gated ion channel superfamily. The extracellular domains of these receptors share similar sequence homology (approximately 20%) with Limnaea acetylcholine binding protein, for which an x-ray crystal structure is available. We used this structure as a template for computer-based homology modeling of the 5-HT(3) receptor extracellular domain. AutoDock software was used to dock 5-HT into the putative 5-HT(3) receptor ligand-binding site, resulting in seven alternative energetically favorable models. Residues located no more than 5 A from the docked 5-HT were identified for each model; of these, 12 were found to be common to all seven models with five others present in only certain models. Some docking models reflected the cation-pi interaction previously demonstrated for W183, and data from these and other studies were used to define our preferred models.

The molecular basis of the structure and function of the 5-HT3 receptor: a model ligand-gated ion channel (review).

The ligand-gated ion channel superfamily of neurotransmitter receptors are proteins responsible for rapid transmission of nerve impulses at the synapse and have, therefore, been the subject of intensive research for many years. The cys-loop family, of which the 5-HT3 receptor is a member, includes the nicotinic acetylcholine receptor, the GABAA receptor and the glycine receptor. A diverse range of endogenous and artificial ligands activate these receptors, but, nevertheless, the family shares many similarities of structure and function. Several important questions, however, still remain to be determined, including the mechanism of agonist recognition at the binding site, the nature of the connection between the agonist binding and channel domains, the structure of the transmembrane regions and the mechanism of ion permeation and selectivity. This article reviews recent advances in the characterization of the molecular properties of the 5-HT3 receptor and their role in its function, and assesses its suitability as a model system for the study of the above questions.