Activation of human bitter taste receptors by polymethoxylated flavonoids

Tangeretin and nobiletin are polymethoxylated flavonoids in citrus peel. Both tangeretin and nobiletin are bitter; however, their bitterness has not been evaluated using human bitter taste receptors (hTAS2Rs). We screened 25 kinds of hTAS2Rs and found that hTAS2R14 and hTAS2R46 received both compounds.     

Sweet and bitter tastants specific detection by the taste cell-based sensor

Sweet and bitter tastants specific detection by cell-based sensor is investigated in this paper. Human enteroendocrine NCI-H716 cells, expressing G protein-coupled receptors and sweet receptors (type 1, member 2/type 1, member 3), and human enteroendocrine STC-1 cells, expressing G protein-coupled receptors and bitter receptors (type 2 members) are used as sensing devices. The HEK-293 cells, without taste receptor expression, are used as negative control. The electrochemical impedance spectrum data is recorded and processed by bistable stochastic resonance for signal-to-noise ratio calculation. NCI-H716 cell-based sensor selectively responds to sweeteners and sweet tastant mixtures. STC-1 cell-based sensor selectively responds to bitter tastants and bitter tastant mixtures. The tastants species and concentrations can be decided by signal-to-noise ratio parameters. HEK-293 cell-based sensor lacks the tastants discriminating ability. The taste cell-based sensor is easy to prepare and operate. This work offers a useful way in gustatory mechanism research.     

Molecular basis of bitter taste

The sense of taste responds to a large variety of stimuli through specific transduction mechanisms. The molecular events in the perception of bitter taste are believed to start with the binding of specific water-soluble molecules to G-protein-coupled receptors encoded by the type 2 family of taste receptor genes and expressed at the surface of taste receptor cells. Recent advances in the identification and cloning of the complete repertoire of genes of this family in humans and rodents provide an opportunity to address unresolved questions in bitter taste. The functional characterization of some of the receptors that these genes encode suggests that it will be possible to understand more precisely their specific functions.     

Three-dimensional mapping of the bitter taste receptor site

The essential geometrical features of the receptor site of bittermolecules were found through a detailed mapping procedure basedon the use of the shapes of conformationally rigid molecules.     

The sweet and the bitter of mammalian taste

The discovery of two families of mammalian taste receptors has provided important insights into taste recognition and taste perception. Recent studies have examined the receptors and signaling pathways that mediate sweet, bitter, and amino acid taste detection in mammals. These studies demonstrate that taste cells are selectively tuned to different taste modalities and clarify the logic of taste coding in the periphery.     

Postnatal development of bitter taste avoidance behavior in mice is associated with ACTIN-dependent localization of bitter taste receptors to the microvilli of taste cells

Bitter taste avoidance behavior (BAB) plays a fundamental role in the avoidance of toxic substances with a bitter taste. However, the molecular basis underlying the development of BAB is unknown. To study critical developmental events by which taste buds turn into functional organs with BAB, we investigated the early phase development of BAB in postnatal mice in response to bitter-tasting compounds, such as quinine and thiamine. Postnatal mice started to exhibit BAB for thiamine and quinine at postnatal day 5 (PD5) and PD7, respectively. Histological analyses of taste buds revealed the formation of microvilli in the taste pores starting at PD5 and the localization of type 2 taste receptor 119 (TAS2R119) at the microvilli at PD6. Treatment of the tongue epithelium with cytochalasin D (CytD), which disturbs ACTIN polymerization in the microvilli, resulted in the loss of TAS2R119 localization at the microvilli and the loss of BAB for quinine and thiamine. The release of ATP from the circumvallate papillae tissue due to taste stimuli was also declined following CytD treatment. These results suggest that the localization of TAS2R119 at the microvilli of taste pores is critical for the initiation of BAB.     

Functional characterization of human bitter taste receptors

The T2Rs belong to a multi-gene family of G-protein-coupled receptors responsible for the detection of ingested bitter-tasting compounds. The T2Rs are conserved among mammals with the human and mouse gene families consisting of about 25 members. In the present study we address the signalling properties of human and mouse T2Rs using an in vitro reconstitution system in which both the ligands and G-proteins being assayed can be manipulated independently and quantitatively assessed. We confirm that the mT2R5, hT2R43 and hT2R47 receptors respond selectively to micromolar concentrations of cycloheximide, aristolochic acid and denatonium respectively. We also demonstrate that hT2R14 is a receptor for aristolochic acid and report the first characterization of the ligand specificities of hT2R7, which is a broadly tuned receptor responding to strychnine, quinacrine, chloroquine and papaverine. Using these defined ligand-receptor interactions, we assayed the ability of the ligand-activated T2Rs to catalyse GTP binding on divergent members of the G(alpha) family including three members of the G(alphai) subfamily (transducin, G(alphai1) and G(alphao)) as well as G(alphas) and G(alphaq). The T2Rs coupled with each of the three G(alphai) members tested. However, none of the T2Rs coupled to either G(alphas) or G(alphaq), suggesting the T2Rs signal primarily through G(alphai)-mediated signal transduction pathways. Furthermore, we observed different G-protein selectivities among the T2Rs with respect to both G(alphai) subunits and G(betagamma) dimers, suggesting that bitter taste is transduced by multiple G-proteins that may differ among the T2Rs.     

Peripheral coding of bitter taste in Drosophila

Taste receptors play a crucial role in detecting the presence of bitter compounds such as alkaloids, and help to prevent the ingestion of toxic food. In Drosophila, we show for the first time that several taste sensilla on the prothoracic legs detect bitter compounds both through the activation of specific taste neurons but also through inhibition of taste neurons activated by sugars and water. Each sensillum usually houses a cluster of four taste neurons classified according to their best stimulus (S for sugar, W for Water, L1 and L2 for salts). Using a new statistical approach based on the analysis of interspike intervals, we show that bitter compounds activate the L2 cell. Bitter-activated L2 cells were excited with a latency of at least 50 ms. Their sensitivity to bitter compounds was different between sensilla, suggesting that specific receptors to bitter compounds are differentially expressed among L2 cells. When presented in mixtures, bitter compounds inhibited the responses of S and W, but not the L1 cell. The inhibition was effective even in sensilla where bitter compounds did not activate the L2 cell, indicating that bitter compounds directly interact with the S and W cells. Interestingly, this inhibition occurred with latencies similar to the excitation of bitter-activated L2 cells. It suggests that the inhibition in the W and S cells shares similar transduction pathways with the excitation in the L2 cells. Combined with molecular approaches, the results presented here should provide a physiological basis to understand how bitter compounds are detected and discriminated.     

Angiotensin-(1-7) prevents diabetes-induced cardiovascular dysfunction

The aim of this study was to test the hypothesis that treatment with angiotensin-(1-7) [ANG-(1-7)] or ANG-(1-7) nonpeptide analog AVE-0991 can produce protection against diabetes-induced cardiovascular dysfunction. We examined the influence of chronic treatment (4 wk) with ANG-(1-7) (576 microg.kg(-1).day(-1) ip) or AVE-0991 (576 microg.kg(-1).day(-1) ip) on proteinuria, vascular responsiveness of isolated carotid and renal artery ring segments and mesenteric bed to vasoactive agonists, and cardiac recovery from ischemia-reperfusion in streptozotocin-treated rats (diabetes). Animals were killed 4 wk after induction of diabetes and/or treatment with ANG-(1-7) or AVE-0991. There was a significant increase in urine protein (231 +/- 2 mg/24 h) in diabetic animals compared with controls (88 +/- 6 mg/24 h). Treatment of diabetic animals with ANG-(1-7) or AVE-0991 resulted in a significant reduction in urine protein compared with vehicle-treated diabetic animals (183 +/- 16 and 149 +/- 15 mg/24 h, respectively). Treatment with ANG-(1-7) or AVE-0991 also prevented the diabetes-induced abnormal vascular responsiveness to norepinephrine, endothelin-1, angiotensin II, carbachol, and histamine in the perfused mesenteric bed and isolated carotid and renal arteries. In isolated perfused hearts, recovery of left ventricular function from 40 min of global ischemia was significantly better in ANG-(1-7)- or AVE-0991-treated animals. These results suggest that activation of ANG-(1-7)-mediated signal transduction could be an important therapeutic strategy to reduce cardiovascular events in diabetic patients.     

A conditioned aversion study of sucrose and SC45647 taste in TRPM5 knockout mice

Previously, published studies have reported mixed results regarding the role of the TRPM5 cation channel in signaling sweet taste by taste sensory cells. Some studies have reported a complete loss of sweet taste preference in TRPM5 knockout (KO) mice, whereas others have reported only a partial loss of sweet taste preference. This study reports the results of conditioned aversion studies designed to motivate wild-type (WT) and KO mice to respond to sweet substances. In conditioned taste aversion experiments, WT mice showed nearly complete LiCl-induced response suppression to sucrose and SC45647. In contrast, TRPM5 KO mice showed a much smaller conditioned aversion to either sweet substance, suggesting a compromised, but not absent, ability to detect sweet taste. A subsequent conditioned flavor aversion experiment was conducted to determine if TRPM5 KO mice were impaired in their ability to learn a conditioned aversion. In this experiment, KO and WT mice were conditioned to a mixture of SC45647 and amyl acetate (an odor cue). Although WT mice avoided both components of the stimulus mixture, they avoided SC45647 more than the odor cue. The KO mice also avoided both stimuli, but they avoided the odor component more than SC45647, suggesting that while the KO mice are capable of learning an aversion, to them the odor cue was more salient than the taste cue. Collectively, these findings suggest the TRPM5 KO mice have some residual ability to detect SC45647 and sucrose, and, like bitter, there may be a TRPM5-independent transduction pathway for detecting these substances.     

Iontophoretic application of bitter taste stimuli in hamsters

Recent electrophysiological studies on the iontophoretic applicationof taste stimuli by weak electric currents using rodents andfrogs have produced stimuli which appear to mimic the actionof salty, sour and sweet solutions. However, there has beenno report of an ionic stimulus which might serve as a bitteriontophoretic probe. Many common bitter stimuli are either uncharged(e.g. quinine, urea) or have mixed quality sensations (e.g.the bitter salts KCl, MgCl₂) and therefore are unsuitable. Thisreport investigates the use of four organic anions, all of whichare bitter to humans, which may serve as potential bitter stimulifor iontophoretic application to the tongue of the hamster whilerecording electrophysiologically from its chorda tympani nerve.These anions are m-nitrobenzene sulfonate (NBSA), picrate, cholateand m-nitrobenzoate (NBA). The electrophysiological responsesto cathodal polarization via these four anions plus saccharin,an effective cathodal stimulus in the hamster, form the sameefficacy series as chemical (i.e. normal sapid) presentationsof sodium salts of these anions, i.e. saccharin > NBSA >picrate > NBA > cholate. Behavioral evidence suggeststhat NBSA is sweet to hamsters while the latter three anions,picrate, NBA and cholate, are bitter. Electrophyiological observations,based on magnitude of response, appear to support these behavioralfindings. It was concluded that picrate, NBA and cholate mayserve as useful bitter stimulus probes for ionto-phoretic applicationin the hamster.     

灵长类苦味受体基因研究进展

在鲜味、甜味、苦味、咸味和酸味5种味觉形式中,苦味能避免动物摄入有毒有害物质,在动物的生存中发挥着特别重要的作用。苦味味觉的产生依赖于苦味物质与苦味受体的相互作用。苦味受体由苦味受体基因Tas2rs编码,此类基因在不同物种中数量变化较大以适应不同的需求。目前的研究在灵长类中鉴别出了若干苦味受体的配体,并发现有的苦味受体基因所经受的选择压在类群之间、基因之间甚至同一基因不同功能区之间都存在着变化。本文从苦味受体作用的多样性特点,受体与配体的对应关系、受体基因进化模式与食性之间的关系、苦味受体基因的适应性进化方面对灵长类苦味受体基因进行了综述,以期为苦味受体基因在灵长类中的深入研究提供参考。     

酶催化糖基转移反应在改善罗汉果苦味皂苷口味中的应用

罗汉果皂苷Ⅱ是罗汉果嫩果的主要皂苷成分,味道极苦,在罗汉果生产季节的末期大量滞长果(苦果)因为天气原因而产生,这些滞长果因体内的苦味皂苷尚未转化为甜味皂苷而被丢弃;另外,在罗汉果甜苷提取行业中,脱苦工艺同样会产生大量的苦味罗汉果皂苷Ⅱ。但在化学结构上,罗汉果苦味皂苷与甜味皂苷拥有完全相同的苷元部分,仅存在葡萄糖残基数目和位置的差别。该研究通过酶催化糖基转移反应将新的葡萄糖基团引入苦味的罗汉果皂苷Ⅱ中,可以延长其糖链,从而达到改善其口味的目的。该研究从原料选择、糖源选择以及反应温度等多方面考察了反应条件,最终确定的反应最佳条件为纯度在50%以上的罗汉果皂苷Ⅱ、2倍于皂苷重量的淀粉、60 U·g-1罗汉果苦味皂苷的酶、60~65℃反应24 h。经实际罗汉果苦果样品验证了方法的可行性,所获得的产品可以完全消除苦味,并且带有淡淡的甜味,经HPLC-MS确定了所获得的微甜产物为3~6个糖的皂苷混合物。该方法对于目前罗汉果生产中大量出现并被遗弃的嫩果、苦果以及脱苦工艺中产生的罗汉果皂苷Ⅱ而言,是一种潜在的实现废物利用的方法。     

Ionic basis of salt-induced receptor potential in frog taste cells

1. The ionic basis of the receptor potential elicited by salt stimuli in a frog taste cell was studied with intracellular microelectrodes and lingual artery perfusion. 2. The amplitudes of the receptor potentials induced by salts were decreased by 32-60% when interstitial Na+ and Ca2+ were replaced with choline+, tetramethylammonium+ and tetraethyl-ammonium+. 3. After removal of Na+ and Ca2+ from both interstitial and superficial fluids, the reversal potentials of NaCl induced receptor potentials changed depending upon the stimulus concentrations. 4. These results indicate that the direct influx of Na+ across the receptor membrane, as well as the influx of interstitial Na+ across the basolateral membrane, occurs during NaCl stimulation.     

Genetic tracing of the neural pathway for bitter taste in t2r5-WGA transgenic mice

To visualize the neural pathways originating from bitter taste receptor cells (TRCs), we generated transgenic mice expressing the transneuronal tracer wheat germ agglutinin (WGA) under the control of the mouse T2R5 gene promoter/enhancer (t2r5-WGA mice). WGA mRNA was specifically expressed in bitter TRCs. The WGA protein was detected in bitter TRCs and nerve processes in taste buds, but not in sweet, umami, or sour TRCs. The WGA protein was transferred to a subset of sensory neurons in the geniculate and nodose/petrosal ganglia. These results suggest that bitter TRCs, which are devoid of synaptic structures, are innervated by gustatory neurons and that bitter sensory information is directly transmitted to specific gustatory neurons. The t2r5-WGA mice provide a useful tool for identifying gustatory relay neurons in the peripheral sensory ganglia responsible for aversive sensations.     

Salivary protein profiles and sensitivity to the bitter taste of caffeine

The interindividual variation in the sensitivity to bitterness is attributed in part to genetic polymorphism at the taste receptor level, but other factors, such as saliva composition, might be involved. In order to investigate this, 2 groups of subjects (hyposensitive, hypersensitive) were selected from 29 healthy male volunteers based on their detection thresholds for caffeine, and their salivary proteome composition was compared. Abundance of 26 of the 255 spots detected on saliva electrophoretic patterns was significantly different between hypo- and hypersensitive subjects. Saliva of hypersensitive subjects contained higher levels of amylase fragments, immunoglobulins, and serum albumin and/or serum albumin fragments. It also contained lower levels of cystatin SN, an inhibitor of protease. The results suggest that proteolysis occurring within the oral cavity is an important perireceptor factor associated to the sensitivity to the bitter taste of caffeine.     

Computational studies of ligand-receptor interactions in bitter taste receptors

Phenylthiocarbamide tastes intensely bitter to some individuals, but others find it completely tasteless. Recently, it was suggested that phenylthiocarbamide elicits bitter taste by interacting with a human G protein-coupled receptor (hTAS2R38) encoded by the PTC gene. The phenylthiocarbamide nontaster trait was linked to three single nucleotide polymorphisms occurring in the PTC gene. Using the crystal structure of bovine rhodopsin as template, we generated the 3D structure of hTAS2R38 bitter taste receptor. We were able to map on the receptor structure the amino acids affected by the genetic polymorphisms and to propose molecular functions for two of them that explained the emergence of the nontaster trait. We used molecular docking simulations to find that phenylthiocarbamide exhibited a higher affinity for the target receptor than the structurally similar molecule 6-n-propylthiouracil, in line with recent experimental studies. A 3D model was constructed for the hTAS2R16 bitter taste receptor as well, by applying the same protocol. We found that the recently published experimental ligand binding affinity data for this receptor correlated well with the binding scores obtained from our molecular docking calculations.