Differential expression of bitter taste receptors in non-cancerous breast epithelial and breast cancer cells

The human bitter taste receptors (T2Rs) are chemosensory receptors that belong to the G protein-coupled receptor superfamily. T2Rs are present on the surface of oral and many extra-oral cells. In humans 25 T2Rs are present, and these are activated by hundreds of chemical molecules of diverse structure. Previous studies have shown that many bitter compounds including chloroquine, quinidine, bitter melon extract and cucurbitacins B and E inhibit tumor growth and induce apoptosis in cancer cells. However, the existence of T2Rs in cancer cell is not yet elucidated. In this report using quantitative (q)-PCR and flow cytometry, we characterized the expression of T2R1, T2R4, T2R10, T2R38 and T2R49 in the highly metastatic breast cancer cell line MDA-MB-231, poorly metastatic cell line MCF-7, and non-cancerous mammary epithelial cell line MCF-10A. Among the 5 T2Rs analyzed by qPCR and flow cytometry, T2R4 is expressed at 40–70% in mammary epithelial cells in comparison to commonly used breast cancer marker proteins, estrogen receptor and E-cadherin. Interestingly, the expression of T2R4 was downregulated in breast cancer cells. An increase in intracellular calcium mobilization was observed after the application of bitter agonists, quinine, dextromethorphan, and phenylthiocarbamide that are specific for some of the 5 T2Rs. This suggests that the endogenous T2Rs expressed in these cells are functional. Taken together, our novel findings suggest that T2Rs are differentially expressed in mammary epithelial cells, with some T2Rs downregulated in breast cancer cells.     

Identification of ligands for two human bitter T2R receptors

Earlier, a family of G protein-coupled receptors, termed T2Rs, was identified in the rodent and human genomes through data mining. It was suggested that these receptors mediate bitter taste perception. Analysis of the human genome revealed that the hT2R family is composed of 25 members. However, bitter ligands have been identified for only three human receptors so far. Here we report identification of two novel ligand-receptor pairs. hT2R61 is activated by 6-nitrosaccharin, a bitter derivative of saccharin. hT2R44 is activated by denatonium and 6-nitrosaccharin. Activation profiles for these receptors correlate with psychophysical data determined for the bitter compounds in human studies. Functional analysis of hT2R chimeras allowed us to identify residues in extracellular loops critical for receptor activation by ligands. The discovery of two novel bitter ligand-receptor pairs provides additional support for the hypothesis that hT2Rs mediate a bitter taste response in humans.     

Smallest bitter taste receptor (T2Rs) gene repertoire in carnivores

Bitter taste reception is presumably associated with dietary selection, preventing animals from ingesting potentially harmful compounds. Accordingly, carnivores, who encounter these toxic substances less often, should have fewer genes associated with bitter taste reception compared with herbivores and omnivores. To investigate the genetic basis of bitter taste reception, we confirmed bitter taste receptor (T2R) genes previously found in the genome sequences of two herbivores (cow and horse), two omnivores (mouse and rat) and one carnivore (dog). We also identified, for the first time, the T2R repertoire from the genome of other four carnivore species (ferret, giant panda, polar bear and cat) and detected 17-20 bitter receptor genes from the five carnivore genomes, including 12-16 intact genes, 0-1 partial but putatively functional genes, and 3-8 pseudogenes. Both the intact T2R genes and the total T2R gene number among carnivores were the smallest among the tested species, supporting earlier speculations that carnivores have fewer T2R genes, herbivores an intermediate number, and omnivores the largest T2R gene repertoire. To further explain the genetic basis for this disparity, we constructed a phylogenetic tree, which showed most of the T2R genes from the five carnivores were one-to-one orthologs across the tree, suggesting that carnivore T2Rs were conserved among mammals. Similarly, the small carnivore T2R family size was likely due to rare duplication events. Collectively, these results strengthen arguments for the connection between T2R gene family size, diet and habit.     

Bitter peptides activate hTAS2Rs, the human bitter receptors

Fermented food contains numerous peptides derived from material proteins. Bitter peptides formed during the fermentation process are responsible for the bitter taste of fermented food. We investigated whether human bitter receptors (hTAS2Rs) recognize bitterness of peptides with a heterologous expression system. HEK293 cells expressing hTAS2R1, hTAS2R4, hTAS2R14, and hTAS2R16 responded to bitter casein digests. Among those cells, the hTAS2R1-expressing cell was most strongly activated by the synthesized bitter peptides Gly-Phe and Gly-Leu, and none of the cells was activated by the non-bitter dipeptide Gly-Gly. The results showed that these bitter peptides, as well as many other bitter compounds, activate hTAS2Rs, suggesting that humans utilize these hTAS2Rs to recognize and perceive the structure and bitterness of peptides.     

Fluorescence-based optimization of human bitter taste receptor expression in Saccharomyces cerevisiae

Human TAS2 receptors (hTAS2Rs) perceive bitter tastants, but few studies have explored the structure-function relationships of these receptors. In this paper, we report our trials on the large-scale preparations of hTAS2Rs for structural analysis. Twenty-five hTAS2Rs were expressed using a GFP-fusion yeast system in which the constructs and the culture conditions (e.g., the signal sequence, incubation time and temperature after induction) were optimized by measuring GFP fluorescence. After optimization, five hTAS2Rs (hTAS2R7, hTAS2R8, hTAS2R16, hTAS2R41, and hTAS2R48) were expressed at levels greater than 1 mg protein/L of culture, which is a preferable level for purification and crystallization. Among these five bitter taste receptors, hTAS2R41 exhibited the highest detergent solubilization efficiency of 87.1% in n-dodecyl-β-d-maltopyranoside (DDM)/cholesteryl hemisuccinate (CHS). Fluorescence size-exclusion chromatography showed that hTAS2R41 exhibited monodispersity in DDM/CHS without aggregates, suggesting that hTAS2R41 is a good target for future crystallization trials.     

Bitter taste receptors: Novel insights into the biochemistry and pharmacology

Bitter taste receptors (T2Rs) belong to the super family of G protein-coupled receptors (GPCRs). There are 25 T2Rs expressed in humans, and these interact with a large and diverse group of bitter ligands. T2Rs are expressed in many extra-oral tissues and can perform diverse physiological roles. Structure-function studies led to the identification of similarities and dissimilarities between T2Rs and Class A GPCRs including amino acid conservation and novel motifs. However, the efficacy of most of the T2R ligands is not yet elucidated and the biochemical pharmacology of T2Rs is poorly understood. Recent studies on T2Rs characterized novel ligands including blockers for these receptors that include inverse agonist and antagonists. In this review we discuss the techniques used for elucidating bitter blockers, concept of ligand bias, generic amino acid numbering, the role of cholesterol, and conserved water molecules in the biochemistry and pharmacology of T2Rs.     

The human taste receptor hTAS2R14 responds to a variety of different bitter compounds

The recent advances in the functional expression of TAS2Rs in heterologous systems resulted in the identification of bitter tastants that specifically activate receptors of this family. All bitter taste receptors reported to date exhibit a pronounced selectivity for single substances or structurally related bitter compounds. In the present study we demonstrate the expression of the hTAS2R14 gene by RT-PCR analyses and in situ hybridisation in human circumvallate papillae. By functional expression in HEK-293T cells we show that hTAS2R14 displays a, so far, unique broad tuning towards a variety of structurally diverse bitter compounds, including the potent neurotoxins, (-)-alpha-thujone, the pharmacologically active component of absinthe, and picrotoxinin, a poisonous substance of fishberries. The observed activation of heterologously expressed hTAS2R14 by low concentrations of (-)-alpha-thujone and picrotoxinin suggests that the receptor is sufficiently sensitive to caution us against the ingestion of toxic amounts of these substances.     

Identification of novel genes for bitter taste receptors in sheep (Ovis aries)

Genetic studies on taste sensitivity, and bitter taste receptors (T2R) in particular, are an essential tool to understand ingestive behavior and its relation to variations of nutritional status occurring in ruminants. In the present study, we conducted a data-mining search to identify T2R candidates in sheep by comparison with the described T2R in cattle and using recently available ovine genome. In sheep, we identified eight orthologs of cattle genes: T2R16, T2R10B, T2R12, T2R3, T2R4, T2R67, T2R13 and T2R5. The in silico predicted genes were then confirmed by PCR and DNA sequencing. The sequencing results showed a 99% to 100% similarity with the in silico predicted sequence. Moreover, we address the chromosomal distribution and compare, in homology and phylogenetic terms, the obtained genes with the known T2R in human, mouse, dog, cattle, horse and pig. The eight novel genes identified map either to ovine chromosome 3 or 4. The phylogenetic data suggest a clustering by receptor type rather than by species for some of the receptors. From the species analyzed, we observed a clear proximity between the two ruminant species, sheep and cattle, in contrast with lower similarities obtained for the comparison of sheep with other mammals. Although further studies are needed to identify the complete T2R repertoire in domestic sheep, our data represent a first step for genetic studies on this field.     

Reengineering the ligand sensitivity of the broadly tuned human bitter taste receptor TAS2R14

Background

In humans, bitterness perception is mediated by ~25 bitter taste receptors present in the oral cavity. Among these receptors three, TAS2R10, TAS2R14 and TAS2R46, exhibit extraordinary wide agonist profiles and hence contribute disproportionally high to the perception of bitterness. Perhaps the most broadly tuned receptor is the TAS2R14, which may represent, because of its prominent expression in extraoral tissues, a receptor of particular importance for the physiological actions of bitter compounds beyond taste.

Evaluation of the bitterness of green tea catechins by a cell-based assay with the human bitter taste receptor hTAS2R39

Catechins have a broad range of physiological functions and act as the main taste ingredient of green tea. Although catechins show a strong bitterness, the bitter taste receptor for catechins has not been fully understood. The objective of this study was to identify the receptor for the major green tea catechins such as (−)-epicatechin (EC), (−)-epicatechin gallate (ECg), (−)-epigallocatechin (EGC), and (−)-epigallocatechin gallate (EGCg). By the cell-based assay using cultured cells expressing human bitter taste receptor, a clear response of hTAS2R39-expressing cells was observed to 300 μM of either ECg or EGCg, which elicit a strong bitterness in humans. The response of hTAS2R39-expressing cells to ECg was the strongest among the tested catechins, followed by EGCg. Because the cellular response to EC and EGC is much weaker than those of ECg and EGCg, galloyl groups was strongly supposed to be involved in the bitter intensity. This finding is similar to the observations of taste intensity obtained from a human sensory study. Our results suggest the participation of hTAS2R39 in the detection of catechins in humans, indicating the possibility that bitterness of tea catechins can be evaluated by using cells expressing hTAS2R39.     

Functions of human bitter taste receptors depend on N-glycosylation

Human bitter taste receptors of the TAS2R gene family play a crucial role as warning sensors against the ingestion of toxic food compounds. Moreover, the genetically highly polymorphic hTAS2Rs recognize an enormous number of structurally diverse toxic and non-toxic bitter substances, and hence, may substantially influence our individual eating habits. Heterologous expression in mammalian cells is a useful tool to investigate interactions between these receptors and their agonists. However, many bitter taste receptors are poorly expressed at the cell surface of heterologous cells requiring the addition of plasma membrane export promoting epitopes to the native receptor proteins. Currently, nothing is known about amino acid motifs or other receptor-intrinsic features of TAS2Rs affecting plasma membrane association. In the present study, we analyzed the Asn-linked glycosylation of hTAS2Rs at a consensus sequence in the second extracellular loop, which is conserved among all 25 hTAS2Rs. Non-glycosylated receptors exhibit substantially lower cell surface localization and reduced association with the cellular chaperone calnexin. As the auxiliary factors receptor transporting proteins 3 and 4 are able to restore the function of non-glycosylated hTAS2R16 partially, we conclude that glycosylation is important for receptor maturation but not for its function per se .     

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.     

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.     

猪獾苦味受体T2R2基因的分子克隆与进化分析

苦味的感知是机体有效的自我保护机制之一。文章采用PCR和克隆测序方法首次从猪獾基因组中获得一全长为1 169 bp的苦味受体T2R2基因DNA序列(GenBank登录号: FJ812727)。该序列含有完整的1个外显子(无内含子), 大小为915 bp, 编码304个氨基酸残基。其蛋白质等电点为9.76, 分子量为34.74 kDa。拓扑结构预测显示猪獾T2R2蛋白上含有N-糖基化位点、N-肉豆蔻酰化位点各1个, 蛋白激酶C磷酸化位点2个。整个蛋白质多肽链含有7个跨膜螺旋区, 4个细胞外区和4个细胞内区。亲水性/疏水性分析表明, 猪獾T2R2蛋白质为一疏水性蛋白, 其亲水性区段所占比例较小。种间相似性比较显示, 猪獾T2R2基因与犬、猫、牛、马、黑猩猩和小鼠的T2R2基因cDNA序列相似性分别为91.4%、90.6%、84.4%、85.4%、83.8%、72.1%, 氨基酸序列相似性分别为85.5%、85.8%、74.0%、77.6%、75.3%、61.5%。核苷酸替换计算和选择性检验结果表明, 猪獾T2R2基因与犬、猫、牛、马、黑猩猩和小鼠间存在着强烈的纯净化选择(Purifying selection), 即强烈的功能束缚(Functional constraint), 进一步分析发现该选择作用实际上主要存在于跨膜区。猪獾、犬、猫、牛、马、黑猩猩和小鼠的T2R2基因外显子核苷酸序列构建的基因树与其物种树的拓扑结构是相一致的, 表明T2R2基因适合于构建不同物种间的系统进化树。     

The anatomy of mammalian sweet taste receptors

All sweet‐tasting compounds are detected by a single G‐protein coupled receptor (GPCR), the heterodimer T1R2‐T1R3, for which no experimental structure is available. The sweet taste receptor is a class C GPCR, and the recently published crystallographic structures of metabotropic glutamate receptor (mGluR) 1 and 5 provide a significant step forward for understanding structure‐function relationships within this family. In this article, we recapitulate more than 600 single point site‐directed mutations and available structural data to obtain a critical alignment of the sweet taste receptor sequences with respect to other class C GPCRs. Using this alignment, a homology 3D‐model of the human sweet taste receptor is built and analyzed to dissect out the role of key residues involved in ligand binding and those responsible for receptor activation. Proteins 2017; 85:332–341. © 2016 Wiley Periodicals, Inc.     

Evolutionary insights into umami,sweet, and bitter taste receptors in amphibians

Umami and sweet sensations provide animals with important dietary information for detecting and consuming nutrients, whereas bitter sensation helps animals avoid potentially toxic or harmful substances. Enormous progress has been made toward animal sweet/umami taste receptor (Tas1r) and bitter taste receptor (Tas2r). However, information about amphibians is mainly scarce. This study attempted to delineate the repertoire of Tas1r/Tas2r genes by searching for currently available genome sequences in 14 amphibian species. This study identified 16 Tas1r1, 9 Tas1r2, and 9 Tas1r3 genes to be intact and another 17 Tas1r genes to be pseudogenes or absent in the 14 amphibians. According to the functional prediction of Tas1r genes, two species have lost sweet sensation and seven species have lost both umami and sweet sensations. Anurans possessed a large number of intact Tas2rs, ranging from 39 to 178. In contrast, caecilians possessed a contractive bitter taste repertoire, ranging from 4 to 19. Phylogenetic and reconciling analysis revealed that the repertoire of amphibian Tas1rs and Tas2rs was shaped by massive gene duplications and losses. No correlation was found between feeding preferences and the evolution of Tas1rs in amphibians. However, the expansion of Tas2rs may help amphibians adapt to both aquatic and terrestrial habitats. Bitter detection may have played an important role in the evolutionary adaptation of vertebrates in the transition from water to land.     

The human bitter taste receptor hTAS2R39 is the primary receptor for the bitterness of theaflavins

We purified several hundred mgs of four major theaflavins (theaflavin, theaflavin-3-O-gallate, theaflavin-3′-O-gallate, and theaflavin-3,3′-O-digallate). Among the 25 hTAS2Rs expressed in HEK293T cells, hTAS2R39 and hTAS2R14 were activated by theaflavins. Both hTAS2R39 and hTAS2R14 responded to theaflavin-3′-O-gallate. In addition, hTAS2R39 was activated by theaflavin and theaflavin-3,3′-O-gallate, but not by theaflavin-3-O-gallate. In contrast, hTAS2R14 responded to theaflavin-3-O-gallate.     

Diversification and adaptive evolution of putative sweet taste receptors in threespine stickleback

The threespine stickleback Gasterosteus aculeatus is known to include several morphologically and ecologically divergent forms. Its phenotypic traits related to feeding vary among forms, and are considered to be a result of adaptations to various environments to find foods effectively. To examine whether the diversification of feeding modes in the stickleback involves genetic changes of the sense of taste, taste receptor family 1 (T1R) genes in stickleback were analyzed and compared with those in other model fishes. Ten T1R genes and 2 pseudogenes were identified from the stickleback genomic sequences. In particular, putative sweet taste receptors (T1R2s) highly increased in number in stickleback (8 genes and 2 pseudogenes) compared to other fishes (2-3 genes). Maximum likelihood estimations of nonsynonymous-synonymous nucleotide substitution rate have indicated that stickleback T1R2 are under positive selection. Expression analysis by RT-PCR revealed that most stickleback T1R genes were expressed in the taste organs; however, at least two T1R2 genes were not expressed in the taste organs, suggesting that the expression levels of these T1R2 genes may be fluctuated through the life history. In addition, sequencing analysis showed that several T1R2 genes in an anadromous form stickleback individual collected from the western Pacific (Japan) were substantially different from those in genomic data derived from a freshwater form individual collected in North America. This suggested that intra-specific variations of stickleback T1R2 genes were considerably large. Our results imply that, in stickleback, T1R2s have diversified through adaptation to various environments, probably to perceive substances important for its survival and reproduction.