Sugar-regulated cation channel formed by an insect gustatory receptor

Insects sense the taste of foods and toxic compounds in their environment through the gustatory system. Genetic studies using fruit flies have suggested that putative seven-transmembrane gustatory receptors (Grs) expressed in gustatory sensory neurons are required for responses to specific tastants. We reconstituted sugar responses of Bombyx mori Gr-9 (BmGr-9), a silkworm Gr, in two heterologous expression systems. Xenopus oocytes or HEK293T cells expressing BmGr-9 selectively responded to D-fructose with an influx of extracellular Ca(2+) and a nonselective cation current conductance in a G protein-independent manner. Outside-out patch-clamp recording of BmGr-9-expressing cell membranes provides evidence supporting the hypothesis that BmGr-9 constitutes a ligand-gated ion channel. The fructose-activated current associated with BmGr-9 was suppressed by other hexoses, including glucose and sorbose. The activation and inhibition of insect Gr ion channels may be the molecular basis for the decoding system that discriminates subtle differences in sweet taste. Finally, Drosophila melanogaster Gr43a (DmGr43a), a BmGr-9 ortholog, also responded to D-fructose, suggesting that DmGr43a relatives appear to compose the family of fructose receptors.     

Detection of sweet tastants by a conserved group of insect gustatory receptors

Sweet taste cells play critical roles in food selection and feeding behaviors. Drosophila sweet neurons express eight gustatory receptors (Grs) belonging to a highly conserved clade in insects. Despite ongoing efforts, little is known about the fundamental principles that underlie how sweet tastants are detected by these receptors. Here, we provide a systematic functional analysis of Drosophila sweet receptors using the ab1C CO₂-sensing olfactory neuron as a unique in vivo decoder. We find that each of the eight receptors of this group confers sensitivity to one or more sweet tastants, indicating direct roles in ligand recognition for all sweet receptors. Receptor response profiles are validated by analysis of taste responses in corresponding Gr mutants. The response matrix shows extensive overlap in Gr–ligand interactions and loosely separates sweet receptors into two groups matching their relationships by sequence. We then show that expression of a bitter taste receptor confers sensitivity to selected aversive tastants that match the responses of the neuron that the Gr is derived from. Finally, we characterize an internal fructose-sensing receptor, Gr43a, and its ortholog in the malaria mosquito, AgGr25, in the ab1C expression system. We find that both receptors show robust responses to fructose along with a number of other sweet tastants. Our results provide a molecular basis for tastant detection by the entire repertoire of sweet taste receptors in the fly and lay the foundation for studying Grs in mosquitoes and other insects that transmit deadly diseases.The detection of high-calorie sweet compounds is a fundamental property of the taste system. In Drosophila, as in mammals, sweet tastants are detected by a distinct subpopulation of sensory cells that drives innate acceptance (1). An investigation of the mechanisms of tastant detection by sweet receptors is therefore necessary for understanding key principles of feeding behaviors.Insect gustatory receptors (Grs) belong to a novel arthropod superfamily unrelated to mammalian taste receptors (2). The Drosophila melanogaster Gr gene family encodes 68 receptors that are expressed in complex overlapping patterns in chemosensory neurons in both adult and larval stages (3–6). Expression analysis shows that individual Grs are exclusive to either sweet (attractive) or bitter (aversive) taste neurons, delineating separation of sweet and bitter taste receptors within Grs (3–5, 7). Eight Grs have been mapped to sweet taste neurons (5, 8–10), defining a distinct clade of receptors whose members are found across insects and arthropods (11). Of these, Gr5a and Gr64a are broadly required for responses to complementary subsets of sugars in labellar sweet taste neurons (9). Several lines of evidence suggest that one or more of the remaining six receptors are coexpressed with Gr5a in sweet neurons of the fly labellum (8–10, 12). Genetic analysis for some of these other Grs suggests that they are also necessary for responses to sweet tastants, although the breadth of sugar response defects can vary between different Gr mutants (12–14).Receptor expression in a heterologous context is crucial for deciphering its response properties. Our current understanding of how volatile chemicals are encoded by insect odorant receptor (Or) proteins was made possible by both cell-based and in vivo expression systems that allowed comprehensive functional analysis of Or gene repertoires in D. melanogaster (15, 16) and the malaria mosquito Anopheles gambiae (17, 18). The success of ectopic analysis of Ors is in stark contrast to similar studies for Grs, which have met with limited progress (19–22), despite over a decade of efforts. Although the antennal CO₂ receptors Gr21a and Gr63a were successfully expressed in an “empty” olfactory neuron lacking functional Ors (20, 21), attempts to express other Gr genes have been largely futile. Only few instances of functional Gr expression in tissue culture have been reported, which include Gr5a and Gr43a from Drosophila, BmGr8 and BmGr9 from the silkworm Bombyx mori, and PxutGr1 from the swallowtail butterfly Papilio xuthus (19, 22–24). In each case, expression of a single receptor was found to be sufficient to confer tastant responses. To date, however, these instances remain notable exceptions. Because Grs represent a highly divergent chemoreceptor family across insects (25), limitations in examining their functional properties embody a critical gap in the field.We recently expressed Gr64e in the Gr21a/Gr63a CO₂-sensing neuron in the olfactory system and showed that it confers sensitivity to glycerol (12). Here we investigate how tastants are detected by the entire repertoire of sweet taste receptors in Drosophila. We express each receptor individually in the ab1C neuron and examine its responses to a diagnostic panel of sweet compounds derived from the response profile of sweet taste neurons (9). We find that Gr5a and Gr64a confer complementary responses and that every other receptor is activated by one or more sweet tastants. Typically, ectopic responses of other receptors overlap with either Gr5a or Gr64a, but not with both. Ectopic responses are validated by tastant response defects in corresponding Gr mutants. We extend our study by testing a bitter receptor, Gr59c, and observe bitter responses that match previously associated ligands for Gr59c (5). We also test an internal fructose-sensing receptor, Gr43a, and its malaria mosquito ortholog, AgGr25. Both Gr43a and AgGr25 confer robust responses to fructose and some other sweet tastants. Importantly, our results show that AgGr25 can function independently, in the absence of other mosquito proteins. Together, our findings reveal tastant detection properties of Drosophila sweet taste receptors and describe and provide a tool for further analysis of insect taste receptors.     

Drosophila TRPA1 channel mediates chemical avoidance in gustatory receptor neurons

Mammalian sweet, bitter, and umami taste is mediated by a single transduction pathway that includes a phospholipase C (PLC)β and one cation channel, TRPM5. However, in insects such as the fruit fly, Drosophila melanogaster, it is unclear whether different tastants, such as bitter compounds, are sensed in gustatory receptor neurons (GRNs) through one or multiple ion channels, as the cation channels required in insect GRNs are unknown. Here, we set out to explore additional sensory roles for the Drosophila TRPA1 channel, which was known to function in thermosensation. We found that TRPA1 was expressed in GRNs that respond to aversive compounds. Elimination of TRPA1 had no impact on the responses to nearly all bitter compounds tested, including caffeine, quinine, and strychnine. Rather, we found that TRPA1 was required in a subset of avoidance GRNs for the behavioral and electrophysiological responses to aristolochic acid. TRPA1 did not appear to be activated or inhibited directly by aristolochic acid. We found that elimination of the same PLC that leads to activation of TRPA1 in thermosensory neurons was also required in the TRPA1-expressing GRNs for avoiding aristolochic acid. Given that mammalian TRPA1 is required for responding to noxious chemicals, many of which cause pain and injury, our analysis underscores the evolutionarily conserved role for TRPA1 channels in chemical avoidance.     

Drosophila Gr5a encodes a taste receptor tuned to trehalose

Recent studies have suggested that Drosophila taste receptors are encoded by a family of G protein-coupled receptor genes comprising at least 56 members. One of these genes, Gr5a, has been shown by genetic analysis to be required by the fly for behavioral and sensory responses to a sugar, trehalose. Here, we show that Gr5a is expressed in neurons of taste sensilla located on the labellum and legs. Expression is observed in most if not all labellar sensilla and suggests that many taste neurons express more than one receptor. We demonstrate by heterologous expression in a Drosophila S2 cell line that Gr5a encodes a receptor tuned to trehalose. This is the first functional expression of an invertebrate taste receptor.     

Molecular evolution of the insect chemoreceptor gene superfamily in Drosophila melanogaster

The insect chemoreceptor superfamily in Drosophila melanogaster is predicted to consist of 62 odorant receptor (Or) and 68 gustatory receptor (Gr) proteins, encoded by families of 60 Or and 60 Gr genes through alternative splicing. We include two previously undescribed Or genes and two previously undescribed Gr genes; two previously predicted Or genes are shown to be alternative splice forms. Three polymorphic pseudogenes and one highly defective pseudogene are recognized. Phylogenetic analysis reveals deep branches connecting multiple highly divergent clades within the Gr family, and the Or family appears to be a single highly expanded lineage within the superfamily. The genes are spread throughout the Drosophila genome, with some relatively recently diverged genes still clustered in the genome. The Gr5a gene on the X chromosome, which encodes a receptor for the sugar trehalose, has transposed from one such tandem cluster of six genes at cytological location 64, as has Gr61a, and all eight of these receptors might bind sugars. Analysis of intron evolution suggests that the common ancestor consisted of a long N-terminal exon encoding transmembrane domains 1-5 followed by three exons encoding transmembrane domains 6-7. As many as 57 additional introns have been acquired idiosyncratically during the evolution of the superfamily, whereas the ancestral introns and some of the older idiosyncratic introns have been lost at least 48 times independently. Altogether, these patterns of molecular evolution suggest that this is an ancient superfamily of chemoreceptors, probably dating back at least to the origin of the arthropods.     

Taste-independent detection of the caloric content of sugar in Drosophila

Feeding behavior is influenced primarily by two factors: nutritional needs and food palatability. However, the role of food deprivation and metabolic needs in the selection of appropriate food is poorly understood. Here, we show that the fruit fly, Drosophila melanogaster, selects calorie-rich foods following prolonged food deprivation in the absence of taste-receptor signaling. Flies mutant for the sugar receptors Gr5a and Gr64a cannot detect the taste of sugar, but still consumed sugar over plain agar after 15 h of starvation. Similarly, pox-neuro mutants that are insensitive to the taste of sugar preferentially consumed sugar over plain agar upon starvation. Moreover, when given a choice between metabolizable sugar (sucrose or D-glucose) and nonmetabolizable (zero-calorie) sugar (sucralose or L-glucose), starved Gr5a; Gr64a double mutants preferred metabolizable sugars. These findings suggest the existence of a taste-independent metabolic sensor that functions in food selection. The preference for calorie-rich food correlates with a decrease in the two main hemolymph sugars, trehalose and glucose, and in glycogen stores, indicating that this sensor is triggered when the internal energy sources are depleted. Thus, the need to replenish depleted energy stores during periods of starvation may be met through the activity of a taste-independent metabolic sensing pathway.     

Transient receptor potential family members PKD1L3 and PKD2L1 form a candidate sour taste receptor

Animals use their gustatory systems to evaluate the nutritious value, toxicity, sodium content, and acidity of food. Although characterization of molecular identities that receive taste chemicals is essential, molecular receptors underlying sour taste sensation remain unclear. Here, we show that two transient receptor potential (TRP) channel members, PKD1L3 and PKD2L1, are coexpressed in a subset of taste receptor cells in specific taste areas. Cells expressing these molecules are distinct from taste cells having receptors for bitter, sweet, or umami tastants. The PKD2L1 proteins are accumulated at the taste pore region, where taste chemicals are detected. PKD1L3 and PKD2L1 proteins can interact with each other, and coexpression of the PKD1L3 and PKD2L1 is necessary for their functional cell surface expression. Finally, PKD1L3 and PKD2L1 are activated by various acids when coexpressed in heterologous cells but not by other classes of tastants. These results suggest that PKD1L3 and PKD2L1 heteromers may function as sour taste receptors.     

The molecular basis of CO2 reception in Drosophila

CO(2) elicits a response from many insects, including mosquito vectors of diseases such as malaria and yellow fever, but the molecular basis of CO(2) detection is unknown in insects or other higher eukaryotes. Here we show that Gr21a and Gr63a, members of a large family of Drosophila seven-transmembrane-domain chemoreceptor genes, are coexpressed in chemosensory neurons of both the larva and the adult. The two genes confer CO(2) response when coexpressed in an in vivo expression system, the "empty neuron system." The response is highly specific for CO(2) and dependent on CO(2) concentration. The response shows an equivalent dependence on the dose of Gr21a and Gr63a. None of 39 other chemosensory receptors confers a comparable response to CO(2). The identification of these receptors may now allow the identification of agents that block or activate them. Such agents could affect the responses of insect pests to the humans they seek.     

Blocking taste receptor activation of gustducin inhibits gustatory responses to bitter compounds

Gustducin, a transducin-like guanine nucleotide-binding regulatory protein (G protein), and transducin are expressed in taste receptor cells where they are thought to mediate taste transduction. Gustducin and transducin are activated in the presence of bovine taste membranes by several compounds that humans perceive to be bitter. We have monitored this activation with an in vitro assay to identify compounds that inhibited taste receptor activation of transducin by bitter tastants: AMP and chemically related compounds inhibited in vitro responses to several bitter compounds (e.g., denatonium, quinine, strychnine, and atropine). AMP also inhibited behavioral and electrophysiological responses of mice to bitter tastants, but not to NaCl, HCl, or sucrose. GMP, although chemically similar to AMP, inhibited neither the bitter-responsive taste receptor activation of transducin nor the gustatory responses of mice to bitter compounds. AMP and certain related compounds may bind to bitter-responsive taste receptors or interfere with receptor-G protein coupling to serve as naturally occurring taste modifiers.     

AN ELECTROPHYSIOLOGICAL ANALYSIS OF THE ACTION OF CARBOHYDRATES ON THE SUGAR RECEPTOR OF THE BLOWFLY

Measurements of the taste thresholds of blowflies for a wide variety of carbohydrates, presented individually and in combination, showed that the stimulating effects of the compounds are not always additive. Both synergism and inhibition were observed. In order to gain some insight into the nature of the molecular events occurring in the receptor, it was deemed necessary to investigate synergism and inhibition in single receptors by electrophysiological methods.This investigation revealed that mannose enhances the responses of the sugar receptor of the blowfly to aldose and aldose-derived sugars and reduces responses to the ketose sugars. Responses to fructose are enhanced by the presence of glucose and reduced by the addition of sorbose. Curves describing responses to the aldose and aldose-derived sugars over a wide range of concentrations have steep slopes and intersect the x axis at high concentration values. Curves relating to the ketoses have shallow slopes and lower intercepts. Two or more modes of action of carbohydrates on the sugar receptor are suggested by these data.     

Cardiac catheterization: haemostatic changes in pediatric versus adult patients

Thrombophilic or haemorrhagic complications are possible adverse events following cardiac catheterization particularly in pediatric patients. It was therefore the aim of our study to compare the cardiac catheterization-related haemostatic changes in children with that in adults. The total of 50 patients was subdivided into Gr I (1–6 years), Gr II (7–18 years), and Gr III (19–58 years). Parameters of coagulation activation, plasma levels of various clotting factors and heparinase-modified thrombelastometry parameters were determined prior and immediately after cardiac catheterization. The haemostatic system of pediatric patients was markedly more affected by the procedure than that of adults. Levels of thrombin/antithrombin complex and prothrombin fragment 1+2 in the post-catheter plasma samples were significantly increased in Grs I and II, not in Gr III. The catheter-related decrease in fibrinogen and F II levels was higher in Gr I than in Grs II and III. F VII levels were significantly decreased in Grs I and II, not in Gr III. The catheter-related prolongation of Coagulation times was highest in Gr I, followed by Gr II and finally Gr III. A significant catheter-related decrease of maximum clot firmness was observed solely in Gr I. Our results show that cardiac catheterisation perturbs the haemostatic system of adults, and, even more pronounced, that of pediatric patients. Thus, our results indicate that children might be at a higher risk for either thrombotic complications or post-operative bleeding events than adults.     

Cytokine signaling through the JAK/STAT pathway is required for long-term memory in Drosophila

Cytokine signaling through the JAK/STAT pathway regulates multiple cellular responses, including cell survival, differentiation, and motility. Although significant attention has been focused on the role of cytokines during inflammation and immunity, it has become clear that they are also implicated in normal brain function. However, because of the large number of different genes encoding cytokines and their receptors in mammals, the precise role of cytokines in brain physiology has been difficult to decipher. Here, we took advantage of Drosophila's being a genetically simpler model system to address the function of cytokines in memory formation. Expression analysis showed that the cytokine Upd is enriched in the Drosophila memory center, the mushroom bodies. Using tissue- and adult-specific expression of RNAi and dominant-negative proteins, we show that not only is Upd specifically required in the mushroom bodies for olfactory aversive long-term memory but the Upd receptor Dome, as well as the Drosophila JAK and STAT homologs Hop and Stat92E, are also required, while being dispensable for less stable memory forms.     

Enhancement of D1 dopamine receptor-mediated locomotor stimulation in M(4) muscarinic acetylcholine receptor knockout mice

Muscarinic acetylcholine receptors (M(1)-M(5)) regulate many key functions of the central and peripheral nervous system. Primarily because of the lack of receptor subtype-selective ligands, the precise physiological roles of the individual muscarinic receptor subtypes remain to be elucidated. Interestingly, the M(4) receptor subtype is expressed abundantly in the striatum and various other forebrain regions. To study its potential role in the regulation of locomotor activity and other central functions, we used gene-targeting technology to create mice that lack functional M(4) receptors. Pharmacologic analysis of M(4) receptor-deficient mice indicated that M(4) receptors are not required for muscarinic receptor-mediated analgesia, tremor, hypothermia, and salivation. Strikingly, M(4) receptor-deficient mice showed an increase in basal locomotor activity and greatly enhanced locomotor responses (as compared with their wild-type littermates) after activation of D1 dopamine receptors. These results indicate that M(4) receptors exert inhibitory control on D1 receptor-mediated locomotor stimulation, probably at the level of striatal projection neurons where the two receptors are coexpressed at high levels. Our findings offer new perspectives for the treatment of Parkinson's disease and other movement disorders that are characterized by an imbalance between muscarinic cholinergic and dopaminergic neurotransmission.     

Rapid evolution of smell and taste receptor genes during host specialization in Drosophila sechellia

Our understanding of the genetic basis of host specialization in insects is limited to basic information on the number and location of genetic factors underlying changes in conspicuous phenotypes. We know nothing about general patterns of molecular evolution that may accompany host specialization but are not traceable to a single prominent phenotypic change. Here, I describe changes in the entire repertoire of 136 olfactory receptor (Or) and gustatory receptor (Gr) genes of the recently specialized vinegar fly Drosophila sechellia. I find that D. sechellia is losing Or and Gr genes nearly 10 times faster than its generalist sibling Drosophila simulans. Moreover, those D. sechellia receptors that remain intact have fixed amino acid replacement mutations at a higher rate relative to silent mutations than have their D. simulans orthologs. Comparison of these patterns with those observed in a random sample of genes indicates that the changes at Or and Gr loci are likely to reflect positive selection and/or relaxed constraint associated with the altered ecological niche of this fly.     

CRH-stimulation of cyclic adenosine 5'-monophosphate pathway is partially inhibited by the coexpression of CRH-R1 and CRH-R2alpha

Corticotropin-releasing hormone (CRH) is one of the major proteins responsible for brain stress regulation. Two well-known receptors have been described: type 1 and type 2α, both members of the receptor superfamily of G protein-coupled receptors (GPCR). We investigated receptor regulation when both CRH receptor subtypes are coexpressed in the same mammalian cell line. When both types of receptors are coexpressed, cAMP second messenger production is partially inhibited compared to when receptors are expressed separately. However, neither binding kinetics nor internalization rates are modified by coexpression of these receptors. To our knowledge this is the first demonstration of receptor interaction that results in the modification of CRH-mediated signal transduction pathway. Because CRH-R1 and CRH-R2α have overlapping mRNA expression patterns in the brain, these receptors may be coexpressed in neurons, suggesting that receptor interaction may play an important role in the effect evoked by CRH, contributing to the complexity of differential coupling of the CRH receptors in different endocrine and stress behavior responses.     

Heterologously expressed serotonin 1A receptors couple to muscarinic K+ channels in heart.

In cardiac atrial cells, muscarinic acetylcholine receptors activate a K+ current directly via a guanine nucleotide-binding protein (G protein). Serotonin type 1A receptors may activate a similar pathway in hippocampal neurons. To develop a system in which receptor/G protein/K+ channel coupling can be experimentally manipulated, we have used a highly efficient recombinant vaccinia virus vector system to express human serotonin 1A receptors in primary cultures of rat atrial myocytes. The expressed 1A receptors activated the inwardly rectifying K+ conductance that is normally activated by the endogenous muscarinic acetylcholine receptors. Maximal responses to either agonist occluded further activation by the other agonist. The average activation time constants for serotonin were about 5 times slower than for acetylcholine. The data support suggestions that the intracellular signaling pathway from seven-helix receptors to G proteins and directly to ion channels is widespread in excitable cells. After a fraction of the G proteins are activated irreversibly by guanosine 5'-[gamma-thio]triphosphate, subsequent transduction proceeds more efficiently. One possible interpretation is that multiple G-protein molecules are required to activate each channel. Vaccinia virus expression vectors are thus useful for expressing seven-helix receptors in primary cultures of postmitotic cells and have provided a heterologous expression system for the signaling pathway from seven-helix receptors to G proteins and directly to ion channels.     

Chemokine receptor CXCR3 agonist prevents human T-cell migration in a humanized model of arthritic inflammation

The recruitment of T lymphocytes during diseases such as rheumatoid arthritis is regulated by stimulation of the chemokine receptors expressed by these cells. This study was designed to assess the potential of a CXCR3-specific small-molecule agonist to inhibit the migration of activated human T cells toward multiple chemokines. Further experiments defined the molecular mechanism for this anti-inflammatory activity. Analysis in vitro demonstrated agonist induced internalization of both CXCR3 and other chemokine receptors coexpressed by CXCR3(+) T cells. Unlike chemokine receptor-specific antagonists, the CXCR3 agonist inhibited migration of activated T cells toward the chemokine mixture in synovial fluid from patients with active rheumatoid arthritis. A humanized mouse air-pouch model showed that intravenous treatment with the CXCR3 agonist prevented inflammatory migration of activated human T cells toward this synovial fluid. A potential mechanism for this action was defined by demonstration that the CXCR3 agonist induces receptor cross-phosphorylation within CXCR3-CCR5 heterodimers on the surface of activated T cells. This study shows that generalized chemokine receptor desensitization can be induced by specific stimulation of a single chemokine receptor on the surface of activated human T cells. A humanized mouse model was used to demonstrate that this receptor desensitization inhibits the inflammatory response that is normally produced by the chemokines present in synovial fluid from patients with active rheumatoid arthritis.     

Estimation of the bronchodilatory effect of deep inhalation after a free run in children.

The bronchomotor effects of a deep inhalation (DI) may provide relevant information about the mechanisms of exercise-induced airway obstruction in children and may be assessed by respiratory conductance (Grs) measured using the forced oscillation technique. The aims of the present study were to assess the effect of DI on Grs after exercise in relationship to the lung function response to exercise. Grs at 12 Hz using a head generator and spirometric data were measured in 62 children suspected of asthma before and 5 min after a 6-min free run. After exercise, Grs was significantly increased by DI in 38 subjects, who also showed larger Grs and forced expiratory volume in one second (FEV1)/forced vital capacity (FVC) responses to exercise than the 24 nonresponders. Stepwise regression indicated significant correlation between the response of Grs to DI and both Grs and FEV1/FVC responses to exercise. The data are consistent with exercise-induced bronchoconstriction being reversed by deep inhalation.